/* ** ################################################################### ** Processor: LPC834M101FHI33 ** Compilers: GNU C Compiler ** IAR ANSI C/C++ Compiler for ARM ** Keil ARM C/C++ Compiler ** MCUXpresso Compiler ** ** Reference manual: LPC83x User manual Rev.1.1 5 October 2016 ** Version: rev. 1.1, 2018-02-25 ** Build: b200509 ** ** Abstract: ** CMSIS Peripheral Access Layer for LPC834 ** ** Copyright 1997-2016 Freescale Semiconductor, Inc. ** Copyright 2016-2020 NXP ** All rights reserved. ** ** SPDX-License-Identifier: BSD-3-Clause ** ** http: www.nxp.com ** mail: support@nxp.com ** ** Revisions: ** - rev. 1.0 (2018-02-09) ** Initial version. ** - rev. 1.1 (2018-02-25) ** Update some registers according to UM rev 1.2 ** ** ################################################################### */ /*! * @file LPC834.h * @version 1.1 * @date 2018-02-25 * @brief CMSIS Peripheral Access Layer for LPC834 * * CMSIS Peripheral Access Layer for LPC834 */ #ifndef _LPC834_H_ #define _LPC834_H_ /**< Symbol preventing repeated inclusion */ /** Memory map major version (memory maps with equal major version number are * compatible) */ #define MCU_MEM_MAP_VERSION 0x0100U /** Memory map minor version */ #define MCU_MEM_MAP_VERSION_MINOR 0x0001U /* ---------------------------------------------------------------------------- -- Interrupt vector numbers ---------------------------------------------------------------------------- */ /*! * @addtogroup Interrupt_vector_numbers Interrupt vector numbers * @{ */ /** Interrupt Number Definitions */ #define NUMBER_OF_INT_VECTORS 48 /**< Number of interrupts in the Vector table */ typedef enum IRQn { /* Auxiliary constants */ NotAvail_IRQn = -128, /**< Not available device specific interrupt */ /* Core interrupts */ NonMaskableInt_IRQn = -14, /**< Non Maskable Interrupt */ HardFault_IRQn = -13, /**< Cortex-M0 SV Hard Fault Interrupt */ SVCall_IRQn = -5, /**< Cortex-M0 SV Call Interrupt */ PendSV_IRQn = -2, /**< Cortex-M0 Pend SV Interrupt */ SysTick_IRQn = -1, /**< Cortex-M0 System Tick Interrupt */ /* Device specific interrupts */ SPI0_IRQn = 0, /**< SPI0 interrupt */ SPI1_IRQn = 1, /**< SPI1 interrupt */ Reserved18_IRQn = 2, /**< Reserved interrupt */ USART0_IRQn = 3, /**< USART0 interrupt */ Reserved20_IRQn = 4, /**< Reserved interrupt */ Reserved21_IRQn = 5, /**< Reserved interrupt */ Reserved22_IRQn = 6, /**< Reserved interrupt */ Reserved23_IRQn = 7, /**< Reserved interrupt */ I2C0_IRQn = 8, /**< I2C0 interrupt */ SCT0_IRQn = 9, /**< State configurable timer interrupt */ MRT0_IRQn = 10, /**< Multi-rate timer interrupt */ Reserved27_IRQn = 11, /**< Reserved interrupt */ WDT_IRQn = 12, /**< Windowed watchdog timer interrupt */ BOD_IRQn = 13, /**< BOD interrupts */ FLASH_IRQn = 14, /**< flash interrupt */ WKT_IRQn = 15, /**< Self-wake-up timer interrupt */ ADC0_SEQA_IRQn = 16, /**< ADC0 sequence A completion. */ ADC0_SEQB_IRQn = 17, /**< ADC0 sequence B completion. */ ADC0_THCMP_IRQn = 18, /**< ADC0 threshold compare and error. */ ADC0_OVR_IRQn = 19, /**< ADC0 overrun */ DMA0_IRQn = 20, /**< DMA0 interrupt */ Reserved37_IRQn = 21, /**< Reserved interrupt */ Reserved38_IRQn = 22, /**< Reserved interrupt */ Reserved39_IRQn = 23, /**< Reserved interrupt */ PIN_INT0_IRQn = 24, /**< Pin interrupt 0 or pattern match engine slice 0 interrupt */ PIN_INT1_IRQn = 25, /**< Pin interrupt 1 or pattern match engine slice 1 interrupt */ PIN_INT2_IRQn = 26, /**< Pin interrupt 2 or pattern match engine slice 2 interrupt */ PIN_INT3_IRQn = 27, /**< Pin interrupt 3 or pattern match engine slice 3 interrupt */ PIN_INT4_IRQn = 28, /**< Pin interrupt 4 or pattern match engine slice 4 interrupt */ PIN_INT5_IRQn = 29, /**< Pin interrupt 5 or pattern match engine slice 5 interrupt */ PIN_INT6_IRQn = 30, /**< Pin interrupt 6 or pattern match engine slice 6 interrupt */ PIN_INT7_IRQn = 31 /**< Pin interrupt 7 or pattern match engine slice 7 interrupt */ } IRQn_Type; /*! * @} */ /* end of group Interrupt_vector_numbers */ /* ---------------------------------------------------------------------------- -- Cortex M0 Core Configuration ---------------------------------------------------------------------------- */ /*! * @addtogroup Cortex_Core_Configuration Cortex M0 Core Configuration * @{ */ #define __CM0PLUS_REV 0x0000 /**< Core revision r0p1 */ #define __MPU_PRESENT 0 /**< Defines if an MPU is present or not */ #define __VTOR_PRESENT 1 /**< Defines if VTOR is present or not */ #define __NVIC_PRIO_BITS 2 /**< Number of priority bits implemented in the NVIC */ #define __Vendor_SysTickConfig 0 /**< Vendor specific implementation of SysTickConfig is defined */ #include "core_cm0plus.h" /* Core Peripheral Access Layer */ #include "system_LPC834.h" /* Device specific configuration file */ /*! * @} */ /* end of group Cortex_Core_Configuration */ /* ---------------------------------------------------------------------------- -- Mapping Information ---------------------------------------------------------------------------- */ /*! * @addtogroup Mapping_Information Mapping Information * @{ */ /** Mapping Information */ /*! * @addtogroup dma_request * @{ */ /******************************************************************************* * Definitions ******************************************************************************/ /*! * @brief Structure for the DMA hardware request * * Defines the structure for the DMA hardware request collections. The user can configure the * hardware request to trigger the DMA transfer accordingly. The index * of the hardware request varies according to the to SoC. */ typedef enum _dma_request_source { kDmaRequestUSART0_RX_DMA = 0U, /**< USART0 RX DMA */ kDmaRequestUSART0_TX_DMA = 1U, /**< USART0 TX DMA */ kDmaRequestUSART1_RX_DMA = 2U, /**< USART1 RX DMA */ kDmaRequestUSART1_TX_DMA = 3U, /**< USART1 TX DMA */ kDmaRequestUSART2_RX_DMA = 4U, /**< USART2 RX DMA */ kDmaRequestUSART2_TX_DMA = 5U, /**< USART2 TX DMA */ kDmaRequestSPI0_RX_DMA = 6U, /**< SPI0 RX DMA */ kDmaRequestSPI0_TX_DMA = 7U, /**< SPI0 TX DMA */ kDmaRequestSPI1_RX_DMA = 8U, /**< SPI1 RX DMA */ kDmaRequestSPI1_TX_DMA = 9U, /**< SPI1 TX DMA */ kDmaRequestI2C0_SLV_DMA = 10U, /**< I2C0 SLAVE DMA */ kDmaRequestI2C0_MST_DMA = 11U, /**< I2C0 MASTER DMA */ kDmaRequestI2C1_SLV_DMA = 12U, /**< I2C1 SLAVE DMA */ kDmaRequestI2C1_MST_DMA = 13U, /**< I2C1 MASTER DMA */ kDmaRequestI2C2_SLV_DMA = 14U, /**< I2C2 SLAVE DMA */ kDmaRequestI2C2_MST_DMA = 15U, /**< I2C2 MASTER DMA */ kDmaRequestI2C3_SLV_DMA = 16U, /**< I2C3 SLAVE DMA */ kDmaRequestI2C3_MST_DMA = 17U, /**< I2C3 MASTER DMA */ } dma_request_source_t; /* @} */ /*! * @} */ /* end of group Mapping_Information */ /* ---------------------------------------------------------------------------- -- Device Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup Peripheral_access_layer Device Peripheral Access Layer * @{ */ /* ** Start of section using anonymous unions */ #if defined(__ARMCC_VERSION) #if (__ARMCC_VERSION >= 6010050) #pragma clang diagnostic push #else #pragma push #pragma anon_unions #endif #elif defined(__GNUC__) /* anonymous unions are enabled by default */ #elif defined(__IAR_SYSTEMS_ICC__) #pragma language=extended #else #error Not supported compiler type #endif /* ---------------------------------------------------------------------------- -- ADC Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup ADC_Peripheral_Access_Layer ADC Peripheral Access Layer * @{ */ /** ADC - Register Layout Typedef */ typedef struct { __IO uint32_t CTRL; /**< ADC Control register. Contains the clock divide value, resolution selection, sampling time selection, and mode controls., offset: 0x0 */ uint8_t RESERVED_0[4]; __IO uint32_t SEQ_CTRL[2]; /**< ADC Conversion Sequence-n control register: Controls triggering and channel selection for conversion sequence-n. Also specifies interrupt mode for sequence-n., array offset: 0x8, array step: 0x4 */ __IO uint32_t SEQ_GDAT[2]; /**< ADC Sequence-n Global Data register. This register contains the result of the most recent ADC conversion performed under sequence-n., array offset: 0x10, array step: 0x4 */ uint8_t RESERVED_1[8]; __I uint32_t DAT[12]; /**< ADC Channel N Data register. This register contains the result of the most recent conversion completed on channel N., array offset: 0x20, array step: 0x4 */ __IO uint32_t THR0_LOW; /**< ADC Low Compare Threshold register 0: Contains the lower threshold level for automatic threshold comparison for any channels linked to threshold pair 0., offset: 0x50 */ __IO uint32_t THR1_LOW; /**< ADC Low Compare Threshold register 1: Contains the lower threshold level for automatic threshold comparison for any channels linked to threshold pair 1., offset: 0x54 */ __IO uint32_t THR0_HIGH; /**< ADC High Compare Threshold register 0: Contains the upper threshold level for automatic threshold comparison for any channels linked to threshold pair 0., offset: 0x58 */ __IO uint32_t THR1_HIGH; /**< ADC High Compare Threshold register 1: Contains the upper threshold level for automatic threshold comparison for any channels linked to threshold pair 1., offset: 0x5C */ __IO uint32_t CHAN_THRSEL; /**< ADC Channel-Threshold Select register. Specifies which set of threshold compare registers are to be used for each channel, offset: 0x60 */ __IO uint32_t INTEN; /**< ADC Interrupt Enable register. This register contains enable bits that enable the sequence-A, sequence-B, threshold compare and data overrun interrupts to be generated., offset: 0x64 */ __IO uint32_t FLAGS; /**< ADC Flags register. Contains the four interrupt/DMA trigger flags and the individual component overrun and threshold-compare flags. (The overrun bits replicate information stored in the result registers)., offset: 0x68 */ __IO uint32_t TRM; /**< ADC Startup register., offset: 0x6C */ } ADC_Type; /* ---------------------------------------------------------------------------- -- ADC Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup ADC_Register_Masks ADC Register Masks * @{ */ /*! @name CTRL - ADC Control register. Contains the clock divide value, resolution selection, sampling time selection, and mode controls. */ /*! @{ */ #define ADC_CTRL_CLKDIV_MASK (0xFFU) #define ADC_CTRL_CLKDIV_SHIFT (0U) /*! CLKDIV - In synchronous mode only, the system clock is divided by this value plus one to produce * the clock for the ADC converter, which should be less than or equal to 72 MHz. Typically, * software should program the smallest value in this field that yields this maximum clock rate or * slightly less, but in certain cases (such as a high-impedance analog source) a slower clock may * be desirable. This field is ignored in the asynchronous operating mode. */ #define ADC_CTRL_CLKDIV(x) (((uint32_t)(((uint32_t)(x)) << ADC_CTRL_CLKDIV_SHIFT)) & ADC_CTRL_CLKDIV_MASK) #define ADC_CTRL_LPWRMODE_MASK (0x400U) #define ADC_CTRL_LPWRMODE_SHIFT (10U) /*! LPWRMODE - The low-power ADC mode * 0b0..The low-power ADC mode is disabled. The analog circuitry remains activated even when no conversions are requested. * 0b1..The low-power ADC mode is enabled. The analog circuitry is automatically powered-down when no conversions * are taking place. When any (hardware or software) triggering event is detected, the analog circuitry is * enabled. After the required start-up time, the requested conversion will be launched. Once the conversion * completes, the analog-circuitry will again be powered-down provided no further conversions are pending. * Using this mode can save an appreciable amount of current (approximately 2.5 mA) when conversions are * required relatively infrequently. The penalty for using this mode is an approximately FIFTEEN ADC CLOCK delay (30 * clocks in 10-bit mode), based on the frequency specified in the CLKDIV field, from the time the trigger * event occurs until sampling of the A/D input commences. Note: This mode will NOT power-up the A/D if the * ADC_ENA bit is low. */ #define ADC_CTRL_LPWRMODE(x) (((uint32_t)(((uint32_t)(x)) << ADC_CTRL_LPWRMODE_SHIFT)) & ADC_CTRL_LPWRMODE_MASK) #define ADC_CTRL_CALMODE_MASK (0x40000000U) #define ADC_CTRL_CALMODE_SHIFT (30U) /*! CALMODE - Writing a '1' to this bit will initiate a sef-calibration cycle. This bit will be * automatically cleared by hardware after the calibration cycle is complete. Note: Other bits of * this register may be written to concurrently with setting this bit, however once this bit has * been set no further writes to this register are permitted unitl the full calibration cycle has * ended. */ #define ADC_CTRL_CALMODE(x) (((uint32_t)(((uint32_t)(x)) << ADC_CTRL_CALMODE_SHIFT)) & ADC_CTRL_CALMODE_MASK) /*! @} */ /*! @name SEQ_CTRL - ADC Conversion Sequence-n control register: Controls triggering and channel selection for conversion sequence-n. Also specifies interrupt mode for sequence-n. */ /*! @{ */ #define ADC_SEQ_CTRL_CHANNELS_MASK (0xFFFU) #define ADC_SEQ_CTRL_CHANNELS_SHIFT (0U) /*! CHANNELS - Selects which one or more of the ADC channels will be sampled and converted when this * sequence is launched. A 1 in any bit of this field will cause the corresponding channel to be * included in the conversion sequence, where bit 0 corresponds to channel 0, bit 1 to channel 1 * and so forth. When this conversion sequence is triggered, either by a hardware trigger or via * software command, ADC conversions will be performed on each enabled channel, in sequence, * beginning with the lowest-ordered channel. This field can ONLY be changed while SEQA_ENA (bit 31) * is LOW. It is allowed to change this field and set bit 31 in the same write. */ #define ADC_SEQ_CTRL_CHANNELS(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_CHANNELS_SHIFT)) & ADC_SEQ_CTRL_CHANNELS_MASK) #define ADC_SEQ_CTRL_TRIGGER_MASK (0x7000U) #define ADC_SEQ_CTRL_TRIGGER_SHIFT (12U) /*! TRIGGER - Selects which of the available hardware trigger sources will cause this conversion * sequence to be initiated. Program the trigger input number in this field. See Table 476. In order * to avoid generating a spurious trigger, it is recommended writing to this field only when * SEQA_ENA (bit 31) is low. It is safe to change this field and set bit 31 in the same write. */ #define ADC_SEQ_CTRL_TRIGGER(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_TRIGGER_SHIFT)) & ADC_SEQ_CTRL_TRIGGER_MASK) #define ADC_SEQ_CTRL_TRIGPOL_MASK (0x40000U) #define ADC_SEQ_CTRL_TRIGPOL_SHIFT (18U) /*! TRIGPOL - Select the polarity of the selected input trigger for this conversion sequence. In * order to avoid generating a spurious trigger, it is recommended writing to this field only when * SEQA_ENA (bit 31) is low. It is safe to change this field and set bit 31 in the same write. * 0b0..Negative edge. A negative edge launches the conversion sequence on the selected trigger input. * 0b1..Positive edge. A positive edge launches the conversion sequence on the selected trigger input. */ #define ADC_SEQ_CTRL_TRIGPOL(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_TRIGPOL_SHIFT)) & ADC_SEQ_CTRL_TRIGPOL_MASK) #define ADC_SEQ_CTRL_SYNCBYPASS_MASK (0x80000U) #define ADC_SEQ_CTRL_SYNCBYPASS_SHIFT (19U) /*! SYNCBYPASS - Setting this bit allows the hardware trigger input to bypass synchronization * flip-flop stages and therefore shorten the time between the trigger input signal and the start of a * conversion. There are slightly different criteria for whether or not this bit can be set * depending on the clock operating mode: Synchronous mode (the ASYNMODE in the CTRL register = 0): * Synchronization may be bypassed (this bit may be set) if the selected trigger source is already * synchronous with the main system clock (eg. coming from an on-chip, system-clock-based timer). * Whether this bit is set or not, a trigger pulse must be maintained for at least one system * clock period. Asynchronous mode (the ASYNMODE in the CTRL register = 1): Synchronization may be * bypassed (this bit may be set) if it is certain that the duration of a trigger input pulse * will be at least one cycle of the ADC clock (regardless of whether the trigger comes from and * on-chip or off-chip source). If this bit is NOT set, the trigger pulse must at least be * maintained for one system clock period. * 0b0..Enable trigger synchronization. The hardware trigger bypass is not enabled. * 0b1..Bypass trigger synchronization. The hardware trigger bypass is enabled. */ #define ADC_SEQ_CTRL_SYNCBYPASS(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_SYNCBYPASS_SHIFT)) & ADC_SEQ_CTRL_SYNCBYPASS_MASK) #define ADC_SEQ_CTRL_START_MASK (0x4000000U) #define ADC_SEQ_CTRL_START_SHIFT (26U) /*! START - Writing a 1 to this field will launch one pass through this conversion sequence. The * behavior will be identical to a sequence triggered by a hardware trigger. Do not write 1 to this * bit if the BURST bit is set. This bit is only set to a 1 momentarily when written to launch a * conversion sequence. It will consequently always read back as a zero. */ #define ADC_SEQ_CTRL_START(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_START_SHIFT)) & ADC_SEQ_CTRL_START_MASK) #define ADC_SEQ_CTRL_BURST_MASK (0x8000000U) #define ADC_SEQ_CTRL_BURST_SHIFT (27U) /*! BURST - Writing a 1 to this bit will cause this conversion sequence to be continuously cycled * through. Other sequence A triggers will be ignored while this bit is set. Repeated conversions * can be halted by clearing this bit. The sequence currently in progress will be completed before * conversions are terminated. Note that a new sequence could begin just before BURST is cleared. */ #define ADC_SEQ_CTRL_BURST(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_BURST_SHIFT)) & ADC_SEQ_CTRL_BURST_MASK) #define ADC_SEQ_CTRL_SINGLESTEP_MASK (0x10000000U) #define ADC_SEQ_CTRL_SINGLESTEP_SHIFT (28U) /*! SINGLESTEP - When this bit is set, a hardware trigger or a write to the START bit will launch a * single conversion on the next channel in the sequence instead of the default response of * launching an entire sequence of conversions. Once all of the channels comprising a sequence have * been converted, a subsequent trigger will repeat the sequence beginning with the first enabled * channel. Interrupt generation will still occur either after each individual conversion or at * the end of the entire sequence, depending on the state of the MODE bit. */ #define ADC_SEQ_CTRL_SINGLESTEP(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_SINGLESTEP_SHIFT)) & ADC_SEQ_CTRL_SINGLESTEP_MASK) #define ADC_SEQ_CTRL_LOWPRIO_MASK (0x20000000U) #define ADC_SEQ_CTRL_LOWPRIO_SHIFT (29U) /*! LOWPRIO - Set priority for sequence A. * 0b0..Low priority. Any B trigger which occurs while an A conversion sequence is active will be ignored and lost. * 0b1..High priority. Setting this bit to a 1 will permit any enabled B sequence trigger (including a B sequence * software start) to immediately interrupt sequence A and launch a B sequence in it's place. The conversion * currently in progress will be terminated. The A sequence that was interrupted will automatically resume * after the B sequence completes. The channel whose conversion was terminated will be re-sampled and the * conversion sequence will resume from that point. */ #define ADC_SEQ_CTRL_LOWPRIO(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_LOWPRIO_SHIFT)) & ADC_SEQ_CTRL_LOWPRIO_MASK) #define ADC_SEQ_CTRL_MODE_MASK (0x40000000U) #define ADC_SEQ_CTRL_MODE_SHIFT (30U) /*! MODE - Indicates whether the primary method for retrieving conversion results for this sequence * will be accomplished via reading the global data register (SEQA_GDAT) at the end of each * conversion, or the individual channel result registers at the end of the entire sequence. Impacts * when conversion-complete interrupt/DMA trigger for sequence-A will be generated and which * overrun conditions contribute to an overrun interrupt as described below. * 0b0..End of conversion. The sequence A interrupt/DMA trigger will be set at the end of each individual ADC * conversion performed under sequence A. This flag will mirror the DATAVALID bit in the SEQA_GDAT register. The * OVERRUN bit in the SEQA_GDAT register will contribute to generation of an overrun interrupt/DMA trigger * if enabled. * 0b1..End of sequence. The sequence A interrupt/DMA trigger will be set when the entire set of sequence-A * conversions completes. This flag will need to be explicitly cleared by software or by the DMA-clear signal in * this mode. The OVERRUN bit in the SEQA_GDAT register will NOT contribute to generation of an overrun * interrupt/DMA trigger since it is assumed this register may not be utilized in this mode. */ #define ADC_SEQ_CTRL_MODE(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_MODE_SHIFT)) & ADC_SEQ_CTRL_MODE_MASK) #define ADC_SEQ_CTRL_SEQ_ENA_MASK (0x80000000U) #define ADC_SEQ_CTRL_SEQ_ENA_SHIFT (31U) /*! SEQ_ENA - Sequence Enable. In order to avoid spuriously triggering the sequence, care should be * taken to only set the SEQn_ENA bit when the selected trigger input is in its INACTIVE state * (as defined by the TRIGPOL bit). If this condition is not met, the sequence will be triggered * immediately upon being enabled. In order to avoid spuriously triggering the sequence, care * should be taken to only set the SEQn_ENA bit when the selected trigger input is in its INACTIVE * state (as defined by the TRIGPOL bit). If this condition is not met, the sequence will be * triggered immediately upon being enabled. * 0b0..Disabled. Sequence n is disabled. Sequence n triggers are ignored. If this bit is cleared while sequence * n is in progress, the sequence will be halted at the end of the current conversion. After the sequence is * re-enabled, a new trigger will be required to restart the sequence beginning with the next enabled channel. * 0b1..Enabled. Sequence n is enabled. */ #define ADC_SEQ_CTRL_SEQ_ENA(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_CTRL_SEQ_ENA_SHIFT)) & ADC_SEQ_CTRL_SEQ_ENA_MASK) /*! @} */ /* The count of ADC_SEQ_CTRL */ #define ADC_SEQ_CTRL_COUNT (2U) /*! @name SEQ_GDAT - ADC Sequence-n Global Data register. This register contains the result of the most recent ADC conversion performed under sequence-n. */ /*! @{ */ #define ADC_SEQ_GDAT_RESULT_MASK (0xFFF0U) #define ADC_SEQ_GDAT_RESULT_SHIFT (4U) /*! RESULT - This field contains the 12-bit ADC conversion result from the most recent conversion * performed under conversion sequence associated with this register. The result is a binary * fraction representing the voltage on the currently-selected input channel as it falls within the * range of VREFP to VREFN. Zero in the field indicates that the voltage on the input pin was less * than, equal to, or close to that on VREFN, while 0xFFF indicates that the voltage on the input * was close to, equal to, or greater than that on VREFP. DATAVALID = 1 indicates that this * result has not yet been read. */ #define ADC_SEQ_GDAT_RESULT(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_RESULT_SHIFT)) & ADC_SEQ_GDAT_RESULT_MASK) #define ADC_SEQ_GDAT_THCMPRANGE_MASK (0x30000U) #define ADC_SEQ_GDAT_THCMPRANGE_SHIFT (16U) /*! THCMPRANGE - Indicates whether the result of the last conversion performed was above, below or * within the range established by the designated threshold comparison registers (THRn_LOW and * THRn_HIGH). */ #define ADC_SEQ_GDAT_THCMPRANGE(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_THCMPRANGE_SHIFT)) & ADC_SEQ_GDAT_THCMPRANGE_MASK) #define ADC_SEQ_GDAT_THCMPCROSS_MASK (0xC0000U) #define ADC_SEQ_GDAT_THCMPCROSS_SHIFT (18U) /*! THCMPCROSS - Indicates whether the result of the last conversion performed represented a * crossing of the threshold level established by the designated LOW threshold comparison register * (THRn_LOW) and, if so, in what direction the crossing occurred. */ #define ADC_SEQ_GDAT_THCMPCROSS(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_THCMPCROSS_SHIFT)) & ADC_SEQ_GDAT_THCMPCROSS_MASK) #define ADC_SEQ_GDAT_CHN_MASK (0x3C000000U) #define ADC_SEQ_GDAT_CHN_SHIFT (26U) /*! CHN - These bits contain the channel from which the RESULT bits were converted (e.g. 0000 * identifies channel 0, 0001 channel 1, etc.). */ #define ADC_SEQ_GDAT_CHN(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_CHN_SHIFT)) & ADC_SEQ_GDAT_CHN_MASK) #define ADC_SEQ_GDAT_OVERRUN_MASK (0x40000000U) #define ADC_SEQ_GDAT_OVERRUN_SHIFT (30U) /*! OVERRUN - This bit is set if a new conversion result is loaded into the RESULT field before a * previous result has been read - i.e. while the DATAVALID bit is set. This bit is cleared, along * with the DATAVALID bit, whenever this register is read. This bit will contribute to an overrun * interrupt/DMA trigger if the MODE bit (in SEQAA_CTRL) for the corresponding sequence is set * to '0' (and if the overrun interrupt is enabled). */ #define ADC_SEQ_GDAT_OVERRUN(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_OVERRUN_SHIFT)) & ADC_SEQ_GDAT_OVERRUN_MASK) #define ADC_SEQ_GDAT_DATAVALID_MASK (0x80000000U) #define ADC_SEQ_GDAT_DATAVALID_SHIFT (31U) /*! DATAVALID - This bit is set to '1' at the end of each conversion when a new result is loaded * into the RESULT field. It is cleared whenever this register is read. This bit will cause a * conversion-complete interrupt for the corresponding sequence if the MODE bit (in SEQA_CTRL) for that * sequence is set to 0 (and if the interrupt is enabled). */ #define ADC_SEQ_GDAT_DATAVALID(x) (((uint32_t)(((uint32_t)(x)) << ADC_SEQ_GDAT_DATAVALID_SHIFT)) & ADC_SEQ_GDAT_DATAVALID_MASK) /*! @} */ /* The count of ADC_SEQ_GDAT */ #define ADC_SEQ_GDAT_COUNT (2U) /*! @name DAT - ADC Channel N Data register. This register contains the result of the most recent conversion completed on channel N. */ /*! @{ */ #define ADC_DAT_RESULT_MASK (0xFFF0U) #define ADC_DAT_RESULT_SHIFT (4U) /*! RESULT - This field contains the 12-bit ADC conversion result from the last conversion performed * on this channel. This will be a binary fraction representing the voltage on the AD0[n] pin, * as it falls within the range of VREFP to VREFN. Zero in the field indicates that the voltage on * the input pin was less than, equal to, or close to that on VREFN, while 0xFFF indicates that * the voltage on the input was close to, equal to, or greater than that on VREFP. */ #define ADC_DAT_RESULT(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_RESULT_SHIFT)) & ADC_DAT_RESULT_MASK) #define ADC_DAT_THCMPRANGE_MASK (0x30000U) #define ADC_DAT_THCMPRANGE_SHIFT (16U) /*! THCMPRANGE - Threshold Range Comparison result. 0x0 = In Range: The last completed conversion * was greater than or equal to the value programmed into the designated LOW threshold register * (THRn_LOW) but less than or equal to the value programmed into the designated HIGH threshold * register (THRn_HIGH). 0x1 = Below Range: The last completed conversion on was less than the value * programmed into the designated LOW threshold register (THRn_LOW). 0x2 = Above Range: The last * completed conversion was greater than the value programmed into the designated HIGH threshold * register (THRn_HIGH). 0x3 = Reserved. */ #define ADC_DAT_THCMPRANGE(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_THCMPRANGE_SHIFT)) & ADC_DAT_THCMPRANGE_MASK) #define ADC_DAT_THCMPCROSS_MASK (0xC0000U) #define ADC_DAT_THCMPCROSS_SHIFT (18U) /*! THCMPCROSS - Threshold Crossing Comparison result. 0x0 = No threshold Crossing detected: The * most recent completed conversion on this channel had the same relationship (above or below) to * the threshold value established by the designated LOW threshold register (THRn_LOW) as did the * previous conversion on this channel. 0x1 = Reserved. 0x2 = Downward Threshold Crossing * Detected. Indicates that a threshold crossing in the downward direction has occurred - i.e. the * previous sample on this channel was above the threshold value established by the designated LOW * threshold register (THRn_LOW) and the current sample is below that threshold. 0x3 = Upward * Threshold Crossing Detected. Indicates that a threshold crossing in the upward direction has occurred * - i.e. the previous sample on this channel was below the threshold value established by the * designated LOW threshold register (THRn_LOW) and the current sample is above that threshold. */ #define ADC_DAT_THCMPCROSS(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_THCMPCROSS_SHIFT)) & ADC_DAT_THCMPCROSS_MASK) #define ADC_DAT_CHANNEL_MASK (0x3C000000U) #define ADC_DAT_CHANNEL_SHIFT (26U) /*! CHANNEL - This field is hard-coded to contain the channel number that this particular register * relates to (i.e. this field will contain 0b0000 for the DAT0 register, 0b0001 for the DAT1 * register, etc) */ #define ADC_DAT_CHANNEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_CHANNEL_SHIFT)) & ADC_DAT_CHANNEL_MASK) #define ADC_DAT_OVERRUN_MASK (0x40000000U) #define ADC_DAT_OVERRUN_SHIFT (30U) /*! OVERRUN - This bit will be set to a 1 if a new conversion on this channel completes and * overwrites the previous contents of the RESULT field before it has been read - i.e. while the DONE bit * is set. This bit is cleared, along with the DONE bit, whenever this register is read or when * the data related to this channel is read from either of the global SEQn_GDAT registers. This * bit (in any of the 12 registers) will cause an overrun interrupt/DMA trigger to be asserted if * the overrun interrupt is enabled. While it is allowed to include the same channels in both * conversion sequences, doing so may cause erratic behavior of the DONE and OVERRUN bits in the * data registers associated with any of the channels that are shared between the two sequences. Any * erratic OVERRUN behavior will also affect overrun interrupt generation, if enabled. */ #define ADC_DAT_OVERRUN(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_OVERRUN_SHIFT)) & ADC_DAT_OVERRUN_MASK) #define ADC_DAT_DATAVALID_MASK (0x80000000U) #define ADC_DAT_DATAVALID_SHIFT (31U) /*! DATAVALID - This bit is set to 1 when an ADC conversion on this channel completes. This bit is * cleared whenever this register is read or when the data related to this channel is read from * either of the global SEQn_GDAT registers. While it is allowed to include the same channels in * both conversion sequences, doing so may cause erratic behavior of the DONE and OVERRUN bits in * the data registers associated with any of the channels that are shared between the two * sequences. Any erratic OVERRUN behavior will also affect overrun interrupt generation, if enabled. */ #define ADC_DAT_DATAVALID(x) (((uint32_t)(((uint32_t)(x)) << ADC_DAT_DATAVALID_SHIFT)) & ADC_DAT_DATAVALID_MASK) /*! @} */ /* The count of ADC_DAT */ #define ADC_DAT_COUNT (12U) /*! @name THR0_LOW - ADC Low Compare Threshold register 0: Contains the lower threshold level for automatic threshold comparison for any channels linked to threshold pair 0. */ /*! @{ */ #define ADC_THR0_LOW_THRLOW_MASK (0xFFF0U) #define ADC_THR0_LOW_THRLOW_SHIFT (4U) /*! THRLOW - Low threshold value against which ADC results will be compared */ #define ADC_THR0_LOW_THRLOW(x) (((uint32_t)(((uint32_t)(x)) << ADC_THR0_LOW_THRLOW_SHIFT)) & ADC_THR0_LOW_THRLOW_MASK) /*! @} */ /*! @name THR1_LOW - ADC Low Compare Threshold register 1: Contains the lower threshold level for automatic threshold comparison for any channels linked to threshold pair 1. */ /*! @{ */ #define ADC_THR1_LOW_THRLOW_MASK (0xFFF0U) #define ADC_THR1_LOW_THRLOW_SHIFT (4U) /*! THRLOW - Low threshold value against which ADC results will be compared */ #define ADC_THR1_LOW_THRLOW(x) (((uint32_t)(((uint32_t)(x)) << ADC_THR1_LOW_THRLOW_SHIFT)) & ADC_THR1_LOW_THRLOW_MASK) /*! @} */ /*! @name THR0_HIGH - ADC High Compare Threshold register 0: Contains the upper threshold level for automatic threshold comparison for any channels linked to threshold pair 0. */ /*! @{ */ #define ADC_THR0_HIGH_THRHIGH_MASK (0xFFF0U) #define ADC_THR0_HIGH_THRHIGH_SHIFT (4U) /*! THRHIGH - High threshold value against which ADC results will be compared */ #define ADC_THR0_HIGH_THRHIGH(x) (((uint32_t)(((uint32_t)(x)) << ADC_THR0_HIGH_THRHIGH_SHIFT)) & ADC_THR0_HIGH_THRHIGH_MASK) /*! @} */ /*! @name THR1_HIGH - ADC High Compare Threshold register 1: Contains the upper threshold level for automatic threshold comparison for any channels linked to threshold pair 1. */ /*! @{ */ #define ADC_THR1_HIGH_THRHIGH_MASK (0xFFF0U) #define ADC_THR1_HIGH_THRHIGH_SHIFT (4U) /*! THRHIGH - High threshold value against which ADC results will be compared */ #define ADC_THR1_HIGH_THRHIGH(x) (((uint32_t)(((uint32_t)(x)) << ADC_THR1_HIGH_THRHIGH_SHIFT)) & ADC_THR1_HIGH_THRHIGH_MASK) /*! @} */ /*! @name CHAN_THRSEL - ADC Channel-Threshold Select register. Specifies which set of threshold compare registers are to be used for each channel */ /*! @{ */ #define ADC_CHAN_THRSEL_CH0_THRSEL_MASK (0x1U) #define ADC_CHAN_THRSEL_CH0_THRSEL_SHIFT (0U) /*! CH0_THRSEL - Threshold select for channel 0. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH0_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH0_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH0_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH1_THRSEL_MASK (0x2U) #define ADC_CHAN_THRSEL_CH1_THRSEL_SHIFT (1U) /*! CH1_THRSEL - Threshold select for channel 1 * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH1_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH1_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH1_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH2_THRSEL_MASK (0x4U) #define ADC_CHAN_THRSEL_CH2_THRSEL_SHIFT (2U) /*! CH2_THRSEL - Threshold select for channel 2. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH2_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH2_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH2_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH3_THRSEL_MASK (0x8U) #define ADC_CHAN_THRSEL_CH3_THRSEL_SHIFT (3U) /*! CH3_THRSEL - Threshold select for channel 3. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH3_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH3_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH3_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH4_THRSEL_MASK (0x10U) #define ADC_CHAN_THRSEL_CH4_THRSEL_SHIFT (4U) /*! CH4_THRSEL - Threshold select for channel 4. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH4_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH4_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH4_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH5_THRSEL_MASK (0x20U) #define ADC_CHAN_THRSEL_CH5_THRSEL_SHIFT (5U) /*! CH5_THRSEL - Threshold select for channel 5. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH5_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH5_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH5_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH6_THRSEL_MASK (0x40U) #define ADC_CHAN_THRSEL_CH6_THRSEL_SHIFT (6U) /*! CH6_THRSEL - Threshold select for channel 6. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH6_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH6_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH6_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH7_THRSEL_MASK (0x80U) #define ADC_CHAN_THRSEL_CH7_THRSEL_SHIFT (7U) /*! CH7_THRSEL - Threshold select for channel 7. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH7_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH7_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH7_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH8_THRSEL_MASK (0x100U) #define ADC_CHAN_THRSEL_CH8_THRSEL_SHIFT (8U) /*! CH8_THRSEL - Threshold select for channel 8. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH8_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH8_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH8_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH9_THRSEL_MASK (0x200U) #define ADC_CHAN_THRSEL_CH9_THRSEL_SHIFT (9U) /*! CH9_THRSEL - Threshold select for channel 9. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH9_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH9_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH9_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH10_THRSEL_MASK (0x400U) #define ADC_CHAN_THRSEL_CH10_THRSEL_SHIFT (10U) /*! CH10_THRSEL - Threshold select for channel 10. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH10_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH10_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH10_THRSEL_MASK) #define ADC_CHAN_THRSEL_CH11_THRSEL_MASK (0x800U) #define ADC_CHAN_THRSEL_CH11_THRSEL_SHIFT (11U) /*! CH11_THRSEL - Threshold select for channel 11. * 0b0..Threshold 0. Results for this channel will be compared against the threshold levels indicated in the THR0_LOW and THR0_HIGH registers. * 0b1..Threshold 1. Results for this channel will be compared against the threshold levels indicated in the THR1_LOW and THR1_HIGH registers. */ #define ADC_CHAN_THRSEL_CH11_THRSEL(x) (((uint32_t)(((uint32_t)(x)) << ADC_CHAN_THRSEL_CH11_THRSEL_SHIFT)) & ADC_CHAN_THRSEL_CH11_THRSEL_MASK) /*! @} */ /*! @name INTEN - ADC Interrupt Enable register. This register contains enable bits that enable the sequence-A, sequence-B, threshold compare and data overrun interrupts to be generated. */ /*! @{ */ #define ADC_INTEN_SEQA_INTEN_MASK (0x1U) #define ADC_INTEN_SEQA_INTEN_SHIFT (0U) /*! SEQA_INTEN - Sequence A interrupt enable. * 0b0..Disabled. The sequence A interrupt/DMA trigger is disabled. * 0b1..Enabled. The sequence A interrupt/DMA trigger is enabled and will be asserted either upon completion of * each individual conversion performed as part of sequence A, or upon completion of the entire A sequence of * conversions, depending on the MODE bit in the SEQA_CTRL register. */ #define ADC_INTEN_SEQA_INTEN(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_SEQA_INTEN_SHIFT)) & ADC_INTEN_SEQA_INTEN_MASK) #define ADC_INTEN_SEQB_INTEN_MASK (0x2U) #define ADC_INTEN_SEQB_INTEN_SHIFT (1U) /*! SEQB_INTEN - Sequence B interrupt enable. * 0b0..Disabled. The sequence B interrupt/DMA trigger is disabled. * 0b1..Enabled. The sequence B interrupt/DMA trigger is enabled and will be asserted either upon completion of * each individual conversion performed as part of sequence B, or upon completion of the entire B sequence of * conversions, depending on the MODE bit in the SEQB_CTRL register. */ #define ADC_INTEN_SEQB_INTEN(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_SEQB_INTEN_SHIFT)) & ADC_INTEN_SEQB_INTEN_MASK) #define ADC_INTEN_OVR_INTEN_MASK (0x4U) #define ADC_INTEN_OVR_INTEN_SHIFT (2U) /*! OVR_INTEN - Overrun interrupt enable. * 0b0..Disabled. The overrun interrupt is disabled. * 0b1..Enabled. The overrun interrupt is enabled. Detection of an overrun condition on any of the 12 channel * data registers will cause an overrun interrupt/DMA trigger. In addition, if the MODE bit for a particular * sequence is 0, then an overrun in the global data register for that sequence will also cause this * interrupt/DMA trigger to be asserted. */ #define ADC_INTEN_OVR_INTEN(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_OVR_INTEN_SHIFT)) & ADC_INTEN_OVR_INTEN_MASK) #define ADC_INTEN_ADCMPINTEN0_MASK (0x18U) #define ADC_INTEN_ADCMPINTEN0_SHIFT (3U) /*! ADCMPINTEN0 - Threshold comparison interrupt enable for channel 0. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN0(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN0_SHIFT)) & ADC_INTEN_ADCMPINTEN0_MASK) #define ADC_INTEN_ADCMPINTEN1_MASK (0x60U) #define ADC_INTEN_ADCMPINTEN1_SHIFT (5U) /*! ADCMPINTEN1 - Channel 1 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN1(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN1_SHIFT)) & ADC_INTEN_ADCMPINTEN1_MASK) #define ADC_INTEN_ADCMPINTEN2_MASK (0x180U) #define ADC_INTEN_ADCMPINTEN2_SHIFT (7U) /*! ADCMPINTEN2 - Channel 2 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN2(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN2_SHIFT)) & ADC_INTEN_ADCMPINTEN2_MASK) #define ADC_INTEN_ADCMPINTEN3_MASK (0x600U) #define ADC_INTEN_ADCMPINTEN3_SHIFT (9U) /*! ADCMPINTEN3 - Channel 3 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN3(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN3_SHIFT)) & ADC_INTEN_ADCMPINTEN3_MASK) #define ADC_INTEN_ADCMPINTEN4_MASK (0x1800U) #define ADC_INTEN_ADCMPINTEN4_SHIFT (11U) /*! ADCMPINTEN4 - Channel 4 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN4(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN4_SHIFT)) & ADC_INTEN_ADCMPINTEN4_MASK) #define ADC_INTEN_ADCMPINTEN5_MASK (0x6000U) #define ADC_INTEN_ADCMPINTEN5_SHIFT (13U) /*! ADCMPINTEN5 - Channel 5 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN5(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN5_SHIFT)) & ADC_INTEN_ADCMPINTEN5_MASK) #define ADC_INTEN_ADCMPINTEN6_MASK (0x18000U) #define ADC_INTEN_ADCMPINTEN6_SHIFT (15U) /*! ADCMPINTEN6 - Channel 6 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN6(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN6_SHIFT)) & ADC_INTEN_ADCMPINTEN6_MASK) #define ADC_INTEN_ADCMPINTEN7_MASK (0x60000U) #define ADC_INTEN_ADCMPINTEN7_SHIFT (17U) /*! ADCMPINTEN7 - Channel 7 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN7(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN7_SHIFT)) & ADC_INTEN_ADCMPINTEN7_MASK) #define ADC_INTEN_ADCMPINTEN8_MASK (0x180000U) #define ADC_INTEN_ADCMPINTEN8_SHIFT (19U) /*! ADCMPINTEN8 - Channel 8 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN8(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN8_SHIFT)) & ADC_INTEN_ADCMPINTEN8_MASK) #define ADC_INTEN_ADCMPINTEN9_MASK (0x600000U) #define ADC_INTEN_ADCMPINTEN9_SHIFT (21U) /*! ADCMPINTEN9 - Channel 9 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN9(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN9_SHIFT)) & ADC_INTEN_ADCMPINTEN9_MASK) #define ADC_INTEN_ADCMPINTEN10_MASK (0x1800000U) #define ADC_INTEN_ADCMPINTEN10_SHIFT (23U) /*! ADCMPINTEN10 - Channel 10 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN10(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN10_SHIFT)) & ADC_INTEN_ADCMPINTEN10_MASK) #define ADC_INTEN_ADCMPINTEN11_MASK (0x6000000U) #define ADC_INTEN_ADCMPINTEN11_SHIFT (25U) /*! ADCMPINTEN11 - Channel 11 threshold comparison interrupt enable. * 0b00..Disabled. * 0b01..Outside threshold. * 0b10..Crossing threshold. * 0b11..Reserved */ #define ADC_INTEN_ADCMPINTEN11(x) (((uint32_t)(((uint32_t)(x)) << ADC_INTEN_ADCMPINTEN11_SHIFT)) & ADC_INTEN_ADCMPINTEN11_MASK) /*! @} */ /*! @name FLAGS - ADC Flags register. Contains the four interrupt/DMA trigger flags and the individual component overrun and threshold-compare flags. (The overrun bits replicate information stored in the result registers). */ /*! @{ */ #define ADC_FLAGS_THCMP0_MASK (0x1U) #define ADC_FLAGS_THCMP0_SHIFT (0U) /*! THCMP0 - Threshold comparison event on Channel 0. Set to 1 upon either an out-of-range result or * a threshold-crossing result if enabled to do so in the INTEN register. This bit is cleared by * writing a 1. */ #define ADC_FLAGS_THCMP0(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP0_SHIFT)) & ADC_FLAGS_THCMP0_MASK) #define ADC_FLAGS_THCMP1_MASK (0x2U) #define ADC_FLAGS_THCMP1_SHIFT (1U) /*! THCMP1 - Threshold comparison event on Channel 1. See description for channel 0. */ #define ADC_FLAGS_THCMP1(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP1_SHIFT)) & ADC_FLAGS_THCMP1_MASK) #define ADC_FLAGS_THCMP2_MASK (0x4U) #define ADC_FLAGS_THCMP2_SHIFT (2U) /*! THCMP2 - Threshold comparison event on Channel 2. See description for channel 0. */ #define ADC_FLAGS_THCMP2(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP2_SHIFT)) & ADC_FLAGS_THCMP2_MASK) #define ADC_FLAGS_THCMP3_MASK (0x8U) #define ADC_FLAGS_THCMP3_SHIFT (3U) /*! THCMP3 - Threshold comparison event on Channel 3. See description for channel 0. */ #define ADC_FLAGS_THCMP3(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP3_SHIFT)) & ADC_FLAGS_THCMP3_MASK) #define ADC_FLAGS_THCMP4_MASK (0x10U) #define ADC_FLAGS_THCMP4_SHIFT (4U) /*! THCMP4 - Threshold comparison event on Channel 4. See description for channel 0. */ #define ADC_FLAGS_THCMP4(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP4_SHIFT)) & ADC_FLAGS_THCMP4_MASK) #define ADC_FLAGS_THCMP5_MASK (0x20U) #define ADC_FLAGS_THCMP5_SHIFT (5U) /*! THCMP5 - Threshold comparison event on Channel 5. See description for channel 0. */ #define ADC_FLAGS_THCMP5(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP5_SHIFT)) & ADC_FLAGS_THCMP5_MASK) #define ADC_FLAGS_THCMP6_MASK (0x40U) #define ADC_FLAGS_THCMP6_SHIFT (6U) /*! THCMP6 - Threshold comparison event on Channel 6. See description for channel 0. */ #define ADC_FLAGS_THCMP6(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP6_SHIFT)) & ADC_FLAGS_THCMP6_MASK) #define ADC_FLAGS_THCMP7_MASK (0x80U) #define ADC_FLAGS_THCMP7_SHIFT (7U) /*! THCMP7 - Threshold comparison event on Channel 7. See description for channel 0. */ #define ADC_FLAGS_THCMP7(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP7_SHIFT)) & ADC_FLAGS_THCMP7_MASK) #define ADC_FLAGS_THCMP8_MASK (0x100U) #define ADC_FLAGS_THCMP8_SHIFT (8U) /*! THCMP8 - Threshold comparison event on Channel 8. See description for channel 0. */ #define ADC_FLAGS_THCMP8(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP8_SHIFT)) & ADC_FLAGS_THCMP8_MASK) #define ADC_FLAGS_THCMP9_MASK (0x200U) #define ADC_FLAGS_THCMP9_SHIFT (9U) /*! THCMP9 - Threshold comparison event on Channel 9. See description for channel 0. */ #define ADC_FLAGS_THCMP9(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP9_SHIFT)) & ADC_FLAGS_THCMP9_MASK) #define ADC_FLAGS_THCMP10_MASK (0x400U) #define ADC_FLAGS_THCMP10_SHIFT (10U) /*! THCMP10 - Threshold comparison event on Channel 10. See description for channel 0. */ #define ADC_FLAGS_THCMP10(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP10_SHIFT)) & ADC_FLAGS_THCMP10_MASK) #define ADC_FLAGS_THCMP11_MASK (0x800U) #define ADC_FLAGS_THCMP11_SHIFT (11U) /*! THCMP11 - Threshold comparison event on Channel 11. See description for channel 0. */ #define ADC_FLAGS_THCMP11(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP11_SHIFT)) & ADC_FLAGS_THCMP11_MASK) #define ADC_FLAGS_OVERRUN0_MASK (0x1000U) #define ADC_FLAGS_OVERRUN0_SHIFT (12U) /*! OVERRUN0 - Mirrors the OVERRRUN status flag from the result register for ADC channel 0 */ #define ADC_FLAGS_OVERRUN0(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN0_SHIFT)) & ADC_FLAGS_OVERRUN0_MASK) #define ADC_FLAGS_OVERRUN1_MASK (0x2000U) #define ADC_FLAGS_OVERRUN1_SHIFT (13U) /*! OVERRUN1 - Mirrors the OVERRRUN status flag from the result register for ADC channel 1 */ #define ADC_FLAGS_OVERRUN1(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN1_SHIFT)) & ADC_FLAGS_OVERRUN1_MASK) #define ADC_FLAGS_OVERRUN2_MASK (0x4000U) #define ADC_FLAGS_OVERRUN2_SHIFT (14U) /*! OVERRUN2 - Mirrors the OVERRRUN status flag from the result register for ADC channel 2 */ #define ADC_FLAGS_OVERRUN2(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN2_SHIFT)) & ADC_FLAGS_OVERRUN2_MASK) #define ADC_FLAGS_OVERRUN3_MASK (0x8000U) #define ADC_FLAGS_OVERRUN3_SHIFT (15U) /*! OVERRUN3 - Mirrors the OVERRRUN status flag from the result register for ADC channel 3 */ #define ADC_FLAGS_OVERRUN3(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN3_SHIFT)) & ADC_FLAGS_OVERRUN3_MASK) #define ADC_FLAGS_OVERRUN4_MASK (0x10000U) #define ADC_FLAGS_OVERRUN4_SHIFT (16U) /*! OVERRUN4 - Mirrors the OVERRRUN status flag from the result register for ADC channel 4 */ #define ADC_FLAGS_OVERRUN4(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN4_SHIFT)) & ADC_FLAGS_OVERRUN4_MASK) #define ADC_FLAGS_OVERRUN5_MASK (0x20000U) #define ADC_FLAGS_OVERRUN5_SHIFT (17U) /*! OVERRUN5 - Mirrors the OVERRRUN status flag from the result register for ADC channel 5 */ #define ADC_FLAGS_OVERRUN5(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN5_SHIFT)) & ADC_FLAGS_OVERRUN5_MASK) #define ADC_FLAGS_OVERRUN6_MASK (0x40000U) #define ADC_FLAGS_OVERRUN6_SHIFT (18U) /*! OVERRUN6 - Mirrors the OVERRRUN status flag from the result register for ADC channel 6 */ #define ADC_FLAGS_OVERRUN6(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN6_SHIFT)) & ADC_FLAGS_OVERRUN6_MASK) #define ADC_FLAGS_OVERRUN7_MASK (0x80000U) #define ADC_FLAGS_OVERRUN7_SHIFT (19U) /*! OVERRUN7 - Mirrors the OVERRRUN status flag from the result register for ADC channel 7 */ #define ADC_FLAGS_OVERRUN7(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN7_SHIFT)) & ADC_FLAGS_OVERRUN7_MASK) #define ADC_FLAGS_OVERRUN8_MASK (0x100000U) #define ADC_FLAGS_OVERRUN8_SHIFT (20U) /*! OVERRUN8 - Mirrors the OVERRRUN status flag from the result register for ADC channel 8 */ #define ADC_FLAGS_OVERRUN8(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN8_SHIFT)) & ADC_FLAGS_OVERRUN8_MASK) #define ADC_FLAGS_OVERRUN9_MASK (0x200000U) #define ADC_FLAGS_OVERRUN9_SHIFT (21U) /*! OVERRUN9 - Mirrors the OVERRRUN status flag from the result register for ADC channel 9 */ #define ADC_FLAGS_OVERRUN9(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN9_SHIFT)) & ADC_FLAGS_OVERRUN9_MASK) #define ADC_FLAGS_OVERRUN10_MASK (0x400000U) #define ADC_FLAGS_OVERRUN10_SHIFT (22U) /*! OVERRUN10 - Mirrors the OVERRRUN status flag from the result register for ADC channel 10 */ #define ADC_FLAGS_OVERRUN10(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN10_SHIFT)) & ADC_FLAGS_OVERRUN10_MASK) #define ADC_FLAGS_OVERRUN11_MASK (0x800000U) #define ADC_FLAGS_OVERRUN11_SHIFT (23U) /*! OVERRUN11 - Mirrors the OVERRRUN status flag from the result register for ADC channel 11 */ #define ADC_FLAGS_OVERRUN11(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVERRUN11_SHIFT)) & ADC_FLAGS_OVERRUN11_MASK) #define ADC_FLAGS_SEQA_OVR_MASK (0x1000000U) #define ADC_FLAGS_SEQA_OVR_SHIFT (24U) /*! SEQA_OVR - Mirrors the global OVERRUN status flag in the SEQA_GDAT register */ #define ADC_FLAGS_SEQA_OVR(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_SEQA_OVR_SHIFT)) & ADC_FLAGS_SEQA_OVR_MASK) #define ADC_FLAGS_SEQB_OVR_MASK (0x2000000U) #define ADC_FLAGS_SEQB_OVR_SHIFT (25U) /*! SEQB_OVR - Mirrors the global OVERRUN status flag in the SEQB_GDAT register */ #define ADC_FLAGS_SEQB_OVR(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_SEQB_OVR_SHIFT)) & ADC_FLAGS_SEQB_OVR_MASK) #define ADC_FLAGS_SEQA_INT_MASK (0x10000000U) #define ADC_FLAGS_SEQA_INT_SHIFT (28U) /*! SEQA_INT - Sequence A interrupt/DMA trigger. If the MODE bit in the SEQA_CTRL register is 0, * this flag will mirror the DATAVALID bit in the sequence A global data register (SEQA_GDAT), which * is set at the end of every ADC conversion performed as part of sequence A. It will be cleared * automatically when the SEQA_GDAT register is read. If the MODE bit in the SEQA_CTRL register * is 1, this flag will be set upon completion of an entire A sequence. In this case it must be * cleared by writing a 1 to this SEQA_INT bit. This interrupt must be enabled in the INTEN * register. */ #define ADC_FLAGS_SEQA_INT(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_SEQA_INT_SHIFT)) & ADC_FLAGS_SEQA_INT_MASK) #define ADC_FLAGS_SEQB_INT_MASK (0x20000000U) #define ADC_FLAGS_SEQB_INT_SHIFT (29U) /*! SEQB_INT - Sequence A interrupt/DMA trigger. If the MODE bit in the SEQB_CTRL register is 0, * this flag will mirror the DATAVALID bit in the sequence A global data register (SEQB_GDAT), which * is set at the end of every ADC conversion performed as part of sequence B. It will be cleared * automatically when the SEQB_GDAT register is read. If the MODE bit in the SEQB_CTRL register * is 1, this flag will be set upon completion of an entire B sequence. In this case it must be * cleared by writing a 1 to this SEQB_INT bit. This interrupt must be enabled in the INTEN * register. */ #define ADC_FLAGS_SEQB_INT(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_SEQB_INT_SHIFT)) & ADC_FLAGS_SEQB_INT_MASK) #define ADC_FLAGS_THCMP_INT_MASK (0x40000000U) #define ADC_FLAGS_THCMP_INT_SHIFT (30U) /*! THCMP_INT - Threshold Comparison Interrupt. This bit will be set if any of the THCMP flags in * the lower bits of this register are set to 1 (due to an enabled out-of-range or * threshold-crossing event on any channel). Each type of threshold comparison interrupt on each channel must be * individually enabled in the INTEN register to cause this interrupt. This bit will be cleared * when all of the individual threshold flags are cleared via writing 1s to those bits. */ #define ADC_FLAGS_THCMP_INT(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_THCMP_INT_SHIFT)) & ADC_FLAGS_THCMP_INT_MASK) #define ADC_FLAGS_OVR_INT_MASK (0x80000000U) #define ADC_FLAGS_OVR_INT_SHIFT (31U) /*! OVR_INT - Overrun Interrupt flag. Any overrun bit in any of the individual channel data * registers will cause this interrupt. In addition, if the MODE bit in either of the SEQn_CTRL registers * is 0 then the OVERRUN bit in the corresponding SEQn_GDAT register will also cause this * interrupt. This interrupt must be enabled in the INTEN register. This bit will be cleared when all * of the individual overrun bits have been cleared via reading the corresponding data registers. */ #define ADC_FLAGS_OVR_INT(x) (((uint32_t)(((uint32_t)(x)) << ADC_FLAGS_OVR_INT_SHIFT)) & ADC_FLAGS_OVR_INT_MASK) /*! @} */ /*! @name TRM - ADC Startup register. */ /*! @{ */ #define ADC_TRM_VRANGE_MASK (0x20U) #define ADC_TRM_VRANGE_SHIFT (5U) /*! VRANGE - 2.4V to 3.6V Vdd range: This bit MUST be set to '1' if operation below 2.7V is to be * used. Failure to set this bit will result in invalid ADC results. Note: This bit will not be * spec'd on parts that do not support operation below 2.7V * 0b0..High voltage * 0b1..Low voltage */ #define ADC_TRM_VRANGE(x) (((uint32_t)(((uint32_t)(x)) << ADC_TRM_VRANGE_SHIFT)) & ADC_TRM_VRANGE_MASK) /*! @} */ /*! * @} */ /* end of group ADC_Register_Masks */ /* ADC - Peripheral instance base addresses */ /** Peripheral ADC0 base address */ #define ADC0_BASE (0x4001C000u) /** Peripheral ADC0 base pointer */ #define ADC0 ((ADC_Type *)ADC0_BASE) /** Array initializer of ADC peripheral base addresses */ #define ADC_BASE_ADDRS { ADC0_BASE } /** Array initializer of ADC peripheral base pointers */ #define ADC_BASE_PTRS { ADC0 } /** Interrupt vectors for the ADC peripheral type */ #define ADC_SEQ_IRQS { ADC0_SEQA_IRQn, ADC0_SEQB_IRQn } #define ADC_THCMP_IRQS { ADC0_THCMP_IRQn } /*! * @} */ /* end of group ADC_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- CRC Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup CRC_Peripheral_Access_Layer CRC Peripheral Access Layer * @{ */ /** CRC - Register Layout Typedef */ typedef struct { __IO uint32_t MODE; /**< CRC mode register, offset: 0x0 */ __IO uint32_t SEED; /**< CRC seed register, offset: 0x4 */ union { /* offset: 0x8 */ __I uint32_t SUM; /**< CRC checksum register, offset: 0x8 */ __O uint32_t WR_DATA; /**< CRC data register, offset: 0x8 */ }; } CRC_Type; /* ---------------------------------------------------------------------------- -- CRC Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup CRC_Register_Masks CRC Register Masks * @{ */ /*! @name MODE - CRC mode register */ /*! @{ */ #define CRC_MODE_CRC_POLY_MASK (0x3U) #define CRC_MODE_CRC_POLY_SHIFT (0U) /*! CRC_POLY - CRC polynomial: 1X = CRC-32 polynomial 01 = CRC-16 polynomial 00 = CRC-CCITT polynomial */ #define CRC_MODE_CRC_POLY(x) (((uint32_t)(((uint32_t)(x)) << CRC_MODE_CRC_POLY_SHIFT)) & CRC_MODE_CRC_POLY_MASK) #define CRC_MODE_BIT_RVS_WR_MASK (0x4U) #define CRC_MODE_BIT_RVS_WR_SHIFT (2U) /*! BIT_RVS_WR - Data bit order: 1 = Bit order reverse for CRC_WR_DATA (per byte) 0 = No bit order reverse for CRC_WR_DATA (per byte) */ #define CRC_MODE_BIT_RVS_WR(x) (((uint32_t)(((uint32_t)(x)) << CRC_MODE_BIT_RVS_WR_SHIFT)) & CRC_MODE_BIT_RVS_WR_MASK) #define CRC_MODE_CMPL_WR_MASK (0x8U) #define CRC_MODE_CMPL_WR_SHIFT (3U) /*! CMPL_WR - Data complement: 1 = 1's complement for CRC_WR_DATA 0 = No 1's complement for CRC_WR_DATA */ #define CRC_MODE_CMPL_WR(x) (((uint32_t)(((uint32_t)(x)) << CRC_MODE_CMPL_WR_SHIFT)) & CRC_MODE_CMPL_WR_MASK) #define CRC_MODE_BIT_RVS_SUM_MASK (0x10U) #define CRC_MODE_BIT_RVS_SUM_SHIFT (4U) /*! BIT_RVS_SUM - CRC sum bit order: 1 = Bit order reverse for CRC_SUM 0 = No bit order reverse for CRC_SUM */ #define CRC_MODE_BIT_RVS_SUM(x) (((uint32_t)(((uint32_t)(x)) << CRC_MODE_BIT_RVS_SUM_SHIFT)) & CRC_MODE_BIT_RVS_SUM_MASK) #define CRC_MODE_CMPL_SUM_MASK (0x20U) #define CRC_MODE_CMPL_SUM_SHIFT (5U) /*! CMPL_SUM - CRC sum complement: 1 = 1's complement for CRC_SUM 0 = No 1's complement for CRC_SUM */ #define CRC_MODE_CMPL_SUM(x) (((uint32_t)(((uint32_t)(x)) << CRC_MODE_CMPL_SUM_SHIFT)) & CRC_MODE_CMPL_SUM_MASK) /*! @} */ /*! @name SEED - CRC seed register */ /*! @{ */ #define CRC_SEED_CRC_SEED_MASK (0xFFFFFFFFU) #define CRC_SEED_CRC_SEED_SHIFT (0U) /*! CRC_SEED - A write access to this register will load CRC seed value to CRC_SUM register with * selected bit order and 1's complement pre-processes. A write access to this register will * overrule the CRC calculation in progresses. */ #define CRC_SEED_CRC_SEED(x) (((uint32_t)(((uint32_t)(x)) << CRC_SEED_CRC_SEED_SHIFT)) & CRC_SEED_CRC_SEED_MASK) /*! @} */ /*! @name SUM - CRC checksum register */ /*! @{ */ #define CRC_SUM_CRC_SUM_MASK (0xFFFFFFFFU) #define CRC_SUM_CRC_SUM_SHIFT (0U) /*! CRC_SUM - The most recent CRC sum can be read through this register with selected bit order and 1's complement post-processes. */ #define CRC_SUM_CRC_SUM(x) (((uint32_t)(((uint32_t)(x)) << CRC_SUM_CRC_SUM_SHIFT)) & CRC_SUM_CRC_SUM_MASK) /*! @} */ /*! @name WR_DATA - CRC data register */ /*! @{ */ #define CRC_WR_DATA_CRC_WR_DATA_MASK (0xFFFFFFFFU) #define CRC_WR_DATA_CRC_WR_DATA_SHIFT (0U) /*! CRC_WR_DATA - Data written to this register will be taken to perform CRC calculation with * selected bit order and 1's complement pre-process. Any write size 8, 16 or 32-bit are allowed and * accept back-to-back transactions. */ #define CRC_WR_DATA_CRC_WR_DATA(x) (((uint32_t)(((uint32_t)(x)) << CRC_WR_DATA_CRC_WR_DATA_SHIFT)) & CRC_WR_DATA_CRC_WR_DATA_MASK) /*! @} */ /*! * @} */ /* end of group CRC_Register_Masks */ /* CRC - Peripheral instance base addresses */ /** Peripheral CRC base address */ #define CRC_BASE (0x50000000u) /** Peripheral CRC base pointer */ #define CRC ((CRC_Type *)CRC_BASE) /** Array initializer of CRC peripheral base addresses */ #define CRC_BASE_ADDRS { CRC_BASE } /** Array initializer of CRC peripheral base pointers */ #define CRC_BASE_PTRS { CRC } /*! * @} */ /* end of group CRC_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- DMA Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup DMA_Peripheral_Access_Layer DMA Peripheral Access Layer * @{ */ /** DMA - Register Layout Typedef */ typedef struct { __IO uint32_t CTRL; /**< DMA control., offset: 0x0 */ __I uint32_t INTSTAT; /**< Interrupt status., offset: 0x4 */ __IO uint32_t SRAMBASE; /**< SRAM address of the channel configuration table., offset: 0x8 */ uint8_t RESERVED_0[20]; struct { /* offset: 0x20, array step: 0x5C */ __IO uint32_t ENABLESET; /**< Channel Enable read and Set for all DMA channels., array offset: 0x20, array step: 0x5C */ uint8_t RESERVED_0[4]; __IO uint32_t ENABLECLR; /**< Channel Enable Clear for all DMA channels., array offset: 0x28, array step: 0x5C */ uint8_t RESERVED_1[4]; __I uint32_t ACTIVE; /**< Channel Active status for all DMA channels., array offset: 0x30, array step: 0x5C */ uint8_t RESERVED_2[4]; __I uint32_t BUSY; /**< Channel Busy status for all DMA channels., array offset: 0x38, array step: 0x5C */ uint8_t RESERVED_3[4]; __IO uint32_t ERRINT; /**< Error Interrupt status for all DMA channels., array offset: 0x40, array step: 0x5C */ uint8_t RESERVED_4[4]; __IO uint32_t INTENSET; /**< Interrupt Enable read and Set for all DMA channels., array offset: 0x48, array step: 0x5C */ uint8_t RESERVED_5[4]; __IO uint32_t INTENCLR; /**< Interrupt Enable Clear for all DMA channels., array offset: 0x50, array step: 0x5C */ uint8_t RESERVED_6[4]; __IO uint32_t INTA; /**< Interrupt A status for all DMA channels., array offset: 0x58, array step: 0x5C */ uint8_t RESERVED_7[4]; __IO uint32_t INTB; /**< Interrupt B status for all DMA channels., array offset: 0x60, array step: 0x5C */ uint8_t RESERVED_8[4]; __IO uint32_t SETVALID; /**< Set ValidPending control bits for all DMA channels., array offset: 0x68, array step: 0x5C */ uint8_t RESERVED_9[4]; __IO uint32_t SETTRIG; /**< Set Trigger control bits for all DMA channels., array offset: 0x70, array step: 0x5C */ uint8_t RESERVED_10[4]; __IO uint32_t ABORT; /**< Channel Abort control for all DMA channels., array offset: 0x78, array step: 0x5C */ } COMMON[1]; uint8_t RESERVED_1[900]; struct { /* offset: 0x400, array step: 0x10 */ __IO uint32_t CFG; /**< Configuration register for DMA channel ., array offset: 0x400, array step: 0x10 */ __I uint32_t CTLSTAT; /**< Control and status register for DMA channel ., array offset: 0x404, array step: 0x10 */ __IO uint32_t XFERCFG; /**< Transfer configuration register for DMA channel ., array offset: 0x408, array step: 0x10 */ uint8_t RESERVED_0[4]; } CHANNEL[18]; } DMA_Type; /* ---------------------------------------------------------------------------- -- DMA Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup DMA_Register_Masks DMA Register Masks * @{ */ /*! @name CTRL - DMA control. */ /*! @{ */ #define DMA_CTRL_ENABLE_MASK (0x1U) #define DMA_CTRL_ENABLE_SHIFT (0U) /*! ENABLE - DMA controller master enable. * 0b0..Disabled. The DMA controller is disabled. This clears any triggers that were asserted at the point when * disabled, but does not prevent re-triggering when the DMA controller is re-enabled. * 0b1..Enabled. The DMA controller is enabled. */ #define DMA_CTRL_ENABLE(x) (((uint32_t)(((uint32_t)(x)) << DMA_CTRL_ENABLE_SHIFT)) & DMA_CTRL_ENABLE_MASK) /*! @} */ /*! @name INTSTAT - Interrupt status. */ /*! @{ */ #define DMA_INTSTAT_ACTIVEINT_MASK (0x2U) #define DMA_INTSTAT_ACTIVEINT_SHIFT (1U) /*! ACTIVEINT - Summarizes whether any enabled interrupts (other than error interrupts) are pending. * 0b0..Not pending. No enabled interrupts are pending. * 0b1..Pending. At least one enabled interrupt is pending. */ #define DMA_INTSTAT_ACTIVEINT(x) (((uint32_t)(((uint32_t)(x)) << DMA_INTSTAT_ACTIVEINT_SHIFT)) & DMA_INTSTAT_ACTIVEINT_MASK) #define DMA_INTSTAT_ACTIVEERRINT_MASK (0x4U) #define DMA_INTSTAT_ACTIVEERRINT_SHIFT (2U) /*! ACTIVEERRINT - Summarizes whether any error interrupts are pending. * 0b0..Not pending. No error interrupts are pending. * 0b1..Pending. At least one error interrupt is pending. */ #define DMA_INTSTAT_ACTIVEERRINT(x) (((uint32_t)(((uint32_t)(x)) << DMA_INTSTAT_ACTIVEERRINT_SHIFT)) & DMA_INTSTAT_ACTIVEERRINT_MASK) /*! @} */ /*! @name SRAMBASE - SRAM address of the channel configuration table. */ /*! @{ */ #define DMA_SRAMBASE_OFFSET_MASK (0xFFFFFE00U) #define DMA_SRAMBASE_OFFSET_SHIFT (9U) /*! OFFSET - Address bits 31:9 of the beginning of the DMA descriptor table. For 18 channels, the * table must begin on a 512 byte boundary. */ #define DMA_SRAMBASE_OFFSET(x) (((uint32_t)(((uint32_t)(x)) << DMA_SRAMBASE_OFFSET_SHIFT)) & DMA_SRAMBASE_OFFSET_MASK) /*! @} */ /*! @name COMMON_ENABLESET - Channel Enable read and Set for all DMA channels. */ /*! @{ */ #define DMA_COMMON_ENABLESET_ENA_MASK (0x3FFFFU) #define DMA_COMMON_ENABLESET_ENA_SHIFT (0U) /*! ENA - Enable for DMA channels. Bit n enables or disables DMA channel n. The number of bits = * number of DMA channels in this device. Other bits are reserved. 0 = disabled. 1 = enabled. */ #define DMA_COMMON_ENABLESET_ENA(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_ENABLESET_ENA_SHIFT)) & DMA_COMMON_ENABLESET_ENA_MASK) /*! @} */ /* The count of DMA_COMMON_ENABLESET */ #define DMA_COMMON_ENABLESET_COUNT (1U) /*! @name COMMON_ENABLECLR - Channel Enable Clear for all DMA channels. */ /*! @{ */ #define DMA_COMMON_ENABLECLR_CLR_MASK (0x3FFFFU) #define DMA_COMMON_ENABLECLR_CLR_SHIFT (0U) /*! CLR - Writing ones to this register clears the corresponding bits in ENABLESET0. Bit n clears * the channel enable bit n. The number of bits = number of DMA channels in this device. Other bits * are reserved. */ #define DMA_COMMON_ENABLECLR_CLR(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_ENABLECLR_CLR_SHIFT)) & DMA_COMMON_ENABLECLR_CLR_MASK) /*! @} */ /* The count of DMA_COMMON_ENABLECLR */ #define DMA_COMMON_ENABLECLR_COUNT (1U) /*! @name COMMON_ACTIVE - Channel Active status for all DMA channels. */ /*! @{ */ #define DMA_COMMON_ACTIVE_ACT_MASK (0x3FFFFU) #define DMA_COMMON_ACTIVE_ACT_SHIFT (0U) /*! ACT - Active flag for DMA channel n. Bit n corresponds to DMA channel n. The number of bits = * number of DMA channels in this device. Other bits are reserved. 0 = not active. 1 = active. */ #define DMA_COMMON_ACTIVE_ACT(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_ACTIVE_ACT_SHIFT)) & DMA_COMMON_ACTIVE_ACT_MASK) /*! @} */ /* The count of DMA_COMMON_ACTIVE */ #define DMA_COMMON_ACTIVE_COUNT (1U) /*! @name COMMON_BUSY - Channel Busy status for all DMA channels. */ /*! @{ */ #define DMA_COMMON_BUSY_BSY_MASK (0x3FFFFU) #define DMA_COMMON_BUSY_BSY_SHIFT (0U) /*! BSY - Busy flag for DMA channel n. Bit n corresponds to DMA channel n. The number of bits = * number of DMA channels in this device. Other bits are reserved. 0 = not busy. 1 = busy. */ #define DMA_COMMON_BUSY_BSY(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_BUSY_BSY_SHIFT)) & DMA_COMMON_BUSY_BSY_MASK) /*! @} */ /* The count of DMA_COMMON_BUSY */ #define DMA_COMMON_BUSY_COUNT (1U) /*! @name COMMON_ERRINT - Error Interrupt status for all DMA channels. */ /*! @{ */ #define DMA_COMMON_ERRINT_ERR_MASK (0x3FFFFU) #define DMA_COMMON_ERRINT_ERR_SHIFT (0U) /*! ERR - Error Interrupt flag for DMA channel n. Bit n corresponds to DMA channel n. The number of * bits = number of DMA channels in this device. Other bits are reserved. 0 = error interrupt is * not active. 1 = error interrupt is active. */ #define DMA_COMMON_ERRINT_ERR(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_ERRINT_ERR_SHIFT)) & DMA_COMMON_ERRINT_ERR_MASK) /*! @} */ /* The count of DMA_COMMON_ERRINT */ #define DMA_COMMON_ERRINT_COUNT (1U) /*! @name COMMON_INTENSET - Interrupt Enable read and Set for all DMA channels. */ /*! @{ */ #define DMA_COMMON_INTENSET_INTEN_MASK (0x3FFFFU) #define DMA_COMMON_INTENSET_INTEN_SHIFT (0U) /*! INTEN - Interrupt Enable read and set for DMA channel n. Bit n corresponds to DMA channel n. The * number of bits = number of DMA channels in this device. Other bits are reserved. 0 = * interrupt for DMA channel is disabled. 1 = interrupt for DMA channel is enabled. */ #define DMA_COMMON_INTENSET_INTEN(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_INTENSET_INTEN_SHIFT)) & DMA_COMMON_INTENSET_INTEN_MASK) /*! @} */ /* The count of DMA_COMMON_INTENSET */ #define DMA_COMMON_INTENSET_COUNT (1U) /*! @name COMMON_INTENCLR - Interrupt Enable Clear for all DMA channels. */ /*! @{ */ #define DMA_COMMON_INTENCLR_CLR_MASK (0x3FFFFU) #define DMA_COMMON_INTENCLR_CLR_SHIFT (0U) /*! CLR - Writing ones to this register clears corresponding bits in the INTENSET0. Bit n * corresponds to DMA channel n. The number of bits = number of DMA channels in this device. Other bits are * reserved. */ #define DMA_COMMON_INTENCLR_CLR(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_INTENCLR_CLR_SHIFT)) & DMA_COMMON_INTENCLR_CLR_MASK) /*! @} */ /* The count of DMA_COMMON_INTENCLR */ #define DMA_COMMON_INTENCLR_COUNT (1U) /*! @name COMMON_INTA - Interrupt A status for all DMA channels. */ /*! @{ */ #define DMA_COMMON_INTA_IA_MASK (0x3FFFFU) #define DMA_COMMON_INTA_IA_SHIFT (0U) /*! IA - Interrupt A status for DMA channel n. Bit n corresponds to DMA channel n. The number of * bits = number of DMA channels in this device. Other bits are reserved. 0 = the DMA channel * interrupt A is not active. 1 = the DMA channel interrupt A is active. */ #define DMA_COMMON_INTA_IA(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_INTA_IA_SHIFT)) & DMA_COMMON_INTA_IA_MASK) /*! @} */ /* The count of DMA_COMMON_INTA */ #define DMA_COMMON_INTA_COUNT (1U) /*! @name COMMON_INTB - Interrupt B status for all DMA channels. */ /*! @{ */ #define DMA_COMMON_INTB_IB_MASK (0x3FFFFU) #define DMA_COMMON_INTB_IB_SHIFT (0U) /*! IB - Interrupt B status for DMA channel n. Bit n corresponds to DMA channel n. The number of * bits = number of DMA channels in this device. Other bits are reserved. 0 = the DMA channel * interrupt B is not active. 1 = the DMA channel interrupt B is active. */ #define DMA_COMMON_INTB_IB(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_INTB_IB_SHIFT)) & DMA_COMMON_INTB_IB_MASK) /*! @} */ /* The count of DMA_COMMON_INTB */ #define DMA_COMMON_INTB_COUNT (1U) /*! @name COMMON_SETVALID - Set ValidPending control bits for all DMA channels. */ /*! @{ */ #define DMA_COMMON_SETVALID_SV_MASK (0x3FFFFU) #define DMA_COMMON_SETVALID_SV_SHIFT (0U) /*! SV - SETVALID control for DMA channel n. Bit n corresponds to DMA channel n. The number of bits * = number of DMA channels in this device. Other bits are reserved. 0 = no effect. 1 = sets the * VALIDPENDING control bit for DMA channel n */ #define DMA_COMMON_SETVALID_SV(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_SETVALID_SV_SHIFT)) & DMA_COMMON_SETVALID_SV_MASK) /*! @} */ /* The count of DMA_COMMON_SETVALID */ #define DMA_COMMON_SETVALID_COUNT (1U) /*! @name COMMON_SETTRIG - Set Trigger control bits for all DMA channels. */ /*! @{ */ #define DMA_COMMON_SETTRIG_TRIG_MASK (0x3FFFFU) #define DMA_COMMON_SETTRIG_TRIG_SHIFT (0U) /*! TRIG - Set Trigger control bit for DMA channel 0. Bit n corresponds to DMA channel n. The number * of bits = number of DMA channels in this device. Other bits are reserved. 0 = no effect. 1 = * sets the TRIG bit for DMA channel n. */ #define DMA_COMMON_SETTRIG_TRIG(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_SETTRIG_TRIG_SHIFT)) & DMA_COMMON_SETTRIG_TRIG_MASK) /*! @} */ /* The count of DMA_COMMON_SETTRIG */ #define DMA_COMMON_SETTRIG_COUNT (1U) /*! @name COMMON_ABORT - Channel Abort control for all DMA channels. */ /*! @{ */ #define DMA_COMMON_ABORT_ABORTCTRL_MASK (0x3FFFFU) #define DMA_COMMON_ABORT_ABORTCTRL_SHIFT (0U) /*! ABORTCTRL - Abort control for DMA channel 0. Bit n corresponds to DMA channel n. 0 = no effect. * 1 = aborts DMA operations on channel n. */ #define DMA_COMMON_ABORT_ABORTCTRL(x) (((uint32_t)(((uint32_t)(x)) << DMA_COMMON_ABORT_ABORTCTRL_SHIFT)) & DMA_COMMON_ABORT_ABORTCTRL_MASK) /*! @} */ /* The count of DMA_COMMON_ABORT */ #define DMA_COMMON_ABORT_COUNT (1U) /*! @name CHANNEL_CFG - Configuration register for DMA channel . */ /*! @{ */ #define DMA_CHANNEL_CFG_PERIPHREQEN_MASK (0x1U) #define DMA_CHANNEL_CFG_PERIPHREQEN_SHIFT (0U) /*! PERIPHREQEN - Peripheral request Enable. If a DMA channel is used to perform a memory-to-memory * move, any peripheral DMA request associated with that channel can be disabled to prevent any * interaction between the peripheral and the DMA controller. * 0b0..Disabled. Peripheral DMA requests are disabled. * 0b1..Enabled. Peripheral DMA requests are enabled. */ #define DMA_CHANNEL_CFG_PERIPHREQEN(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_PERIPHREQEN_SHIFT)) & DMA_CHANNEL_CFG_PERIPHREQEN_MASK) #define DMA_CHANNEL_CFG_HWTRIGEN_MASK (0x2U) #define DMA_CHANNEL_CFG_HWTRIGEN_SHIFT (1U) /*! HWTRIGEN - Hardware Triggering Enable for this channel. * 0b0..Disabled. Hardware triggering is not used. * 0b1..Enabled. Use hardware triggering. */ #define DMA_CHANNEL_CFG_HWTRIGEN(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_HWTRIGEN_SHIFT)) & DMA_CHANNEL_CFG_HWTRIGEN_MASK) #define DMA_CHANNEL_CFG_TRIGPOL_MASK (0x10U) #define DMA_CHANNEL_CFG_TRIGPOL_SHIFT (4U) /*! TRIGPOL - Trigger Polarity. Selects the polarity of a hardware trigger for this channel. * 0b0..Active low - falling edge. Hardware trigger is active low or falling edge triggered, based on TRIGTYPE. * 0b1..Active high - rising edge. Hardware trigger is active high or rising edge triggered, based on TRIGTYPE. */ #define DMA_CHANNEL_CFG_TRIGPOL(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_TRIGPOL_SHIFT)) & DMA_CHANNEL_CFG_TRIGPOL_MASK) #define DMA_CHANNEL_CFG_TRIGTYPE_MASK (0x20U) #define DMA_CHANNEL_CFG_TRIGTYPE_SHIFT (5U) /*! TRIGTYPE - Trigger Type. Selects hardware trigger as edge triggered or level triggered. * 0b0..Edge. Hardware trigger is edge triggered. Transfers will be initiated and completed, as specified for a single trigger. * 0b1..Level. Hardware trigger is level triggered. Note that when level triggering without burst (BURSTPOWER = * 0) is selected, only hardware triggers should be used on that channel. Transfers continue as long as the * trigger level is asserted. Once the trigger is de-asserted, the transfer will be paused until the trigger * is, again, asserted. However, the transfer will not be paused until any remaining transfers within the * current BURSTPOWER length are completed. */ #define DMA_CHANNEL_CFG_TRIGTYPE(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_TRIGTYPE_SHIFT)) & DMA_CHANNEL_CFG_TRIGTYPE_MASK) #define DMA_CHANNEL_CFG_TRIGBURST_MASK (0x40U) #define DMA_CHANNEL_CFG_TRIGBURST_SHIFT (6U) /*! TRIGBURST - Trigger Burst. Selects whether hardware triggers cause a single or burst transfer. * 0b0..Single transfer. Hardware trigger causes a single transfer. * 0b1..Burst transfer. When the trigger for this channel is set to edge triggered, a hardware trigger causes a * burst transfer, as defined by BURSTPOWER. When the trigger for this channel is set to level triggered, a * hardware trigger causes transfers to continue as long as the trigger is asserted, unless the transfer is * complete. */ #define DMA_CHANNEL_CFG_TRIGBURST(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_TRIGBURST_SHIFT)) & DMA_CHANNEL_CFG_TRIGBURST_MASK) #define DMA_CHANNEL_CFG_BURSTPOWER_MASK (0xF00U) #define DMA_CHANNEL_CFG_BURSTPOWER_SHIFT (8U) /*! BURSTPOWER - Burst Power is used in two ways. It always selects the address wrap size when * SRCBURSTWRAP and/or DSTBURSTWRAP modes are selected (see descriptions elsewhere in this register). * When the TRIGBURST field elsewhere in this register = 1, Burst Power selects how many * transfers are performed for each DMA trigger. This can be used, for example, with peripherals that * contain a FIFO that can initiate a DMA operation when the FIFO reaches a certain level. 0000: * Burst size = 1 (20). 0001: Burst size = 2 (21). 0010: Burst size = 4 (22). 1010: Burst size = * 1024 (210). This corresponds to the maximum supported transfer count. others: not supported. The * total transfer length as defined in the XFERCOUNT bits in the XFERCFG register must be an even * multiple of the burst size. */ #define DMA_CHANNEL_CFG_BURSTPOWER(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_BURSTPOWER_SHIFT)) & DMA_CHANNEL_CFG_BURSTPOWER_MASK) #define DMA_CHANNEL_CFG_SRCBURSTWRAP_MASK (0x4000U) #define DMA_CHANNEL_CFG_SRCBURSTWRAP_SHIFT (14U) /*! SRCBURSTWRAP - Source Burst Wrap. When enabled, the source data address for the DMA is * 'wrapped', meaning that the source address range for each burst will be the same. As an example, this * could be used to read several sequential registers from a peripheral for each DMA burst, * reading the same registers again for each burst. * 0b0..Disabled. Source burst wrapping is not enabled for this DMA channel. * 0b1..Enabled. Source burst wrapping is enabled for this DMA channel. */ #define DMA_CHANNEL_CFG_SRCBURSTWRAP(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_SRCBURSTWRAP_SHIFT)) & DMA_CHANNEL_CFG_SRCBURSTWRAP_MASK) #define DMA_CHANNEL_CFG_DSTBURSTWRAP_MASK (0x8000U) #define DMA_CHANNEL_CFG_DSTBURSTWRAP_SHIFT (15U) /*! DSTBURSTWRAP - Destination Burst Wrap. When enabled, the destination data address for the DMA is * 'wrapped', meaning that the destination address range for each burst will be the same. As an * example, this could be used to write several sequential registers to a peripheral for each DMA * burst, writing the same registers again for each burst. * 0b0..Disabled. Destination burst wrapping is not enabled for this DMA channel. * 0b1..Enabled. Destination burst wrapping is enabled for this DMA channel. */ #define DMA_CHANNEL_CFG_DSTBURSTWRAP(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_DSTBURSTWRAP_SHIFT)) & DMA_CHANNEL_CFG_DSTBURSTWRAP_MASK) #define DMA_CHANNEL_CFG_CHPRIORITY_MASK (0x70000U) #define DMA_CHANNEL_CFG_CHPRIORITY_SHIFT (16U) /*! CHPRIORITY - Priority of this channel when multiple DMA requests are pending. Eight priority * levels are supported: 0x0 = highest priority. 0x7 = lowest priority. */ #define DMA_CHANNEL_CFG_CHPRIORITY(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CFG_CHPRIORITY_SHIFT)) & DMA_CHANNEL_CFG_CHPRIORITY_MASK) /*! @} */ /* The count of DMA_CHANNEL_CFG */ #define DMA_CHANNEL_CFG_COUNT (18U) /*! @name CHANNEL_CTLSTAT - Control and status register for DMA channel . */ /*! @{ */ #define DMA_CHANNEL_CTLSTAT_VALIDPENDING_MASK (0x1U) #define DMA_CHANNEL_CTLSTAT_VALIDPENDING_SHIFT (0U) /*! VALIDPENDING - Valid pending flag for this channel. This bit is set when a 1 is written to the * corresponding bit in the related SETVALID register when CFGVALID = 1 for the same channel. * 0b0..No effect. No effect on DMA operation. * 0b1..Valid pending. */ #define DMA_CHANNEL_CTLSTAT_VALIDPENDING(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CTLSTAT_VALIDPENDING_SHIFT)) & DMA_CHANNEL_CTLSTAT_VALIDPENDING_MASK) #define DMA_CHANNEL_CTLSTAT_TRIG_MASK (0x4U) #define DMA_CHANNEL_CTLSTAT_TRIG_SHIFT (2U) /*! TRIG - Trigger flag. Indicates that the trigger for this channel is currently set. This bit is * cleared at the end of an entire transfer or upon reload when CLRTRIG = 1. * 0b0..Not triggered. The trigger for this DMA channel is not set. DMA operations will not be carried out. * 0b1..Triggered. The trigger for this DMA channel is set. DMA operations will be carried out. */ #define DMA_CHANNEL_CTLSTAT_TRIG(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_CTLSTAT_TRIG_SHIFT)) & DMA_CHANNEL_CTLSTAT_TRIG_MASK) /*! @} */ /* The count of DMA_CHANNEL_CTLSTAT */ #define DMA_CHANNEL_CTLSTAT_COUNT (18U) /*! @name CHANNEL_XFERCFG - Transfer configuration register for DMA channel . */ /*! @{ */ #define DMA_CHANNEL_XFERCFG_CFGVALID_MASK (0x1U) #define DMA_CHANNEL_XFERCFG_CFGVALID_SHIFT (0U) /*! CFGVALID - Configuration Valid flag. This bit indicates whether the current channel descriptor * is valid and can potentially be acted upon, if all other activation criteria are fulfilled. * 0b0..Not valid. The channel descriptor is not considered valid until validated by an associated SETVALID0 setting. * 0b1..Valid. The current channel descriptor is considered valid. */ #define DMA_CHANNEL_XFERCFG_CFGVALID(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_CFGVALID_SHIFT)) & DMA_CHANNEL_XFERCFG_CFGVALID_MASK) #define DMA_CHANNEL_XFERCFG_RELOAD_MASK (0x2U) #define DMA_CHANNEL_XFERCFG_RELOAD_SHIFT (1U) /*! RELOAD - Indicates whether the channel's control structure will be reloaded when the current * descriptor is exhausted. Reloading allows ping-pong and linked transfers. * 0b0..Disabled. Do not reload the channels' control structure when the current descriptor is exhausted. * 0b1..Enabled. Reload the channels' control structure when the current descriptor is exhausted. */ #define DMA_CHANNEL_XFERCFG_RELOAD(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_RELOAD_SHIFT)) & DMA_CHANNEL_XFERCFG_RELOAD_MASK) #define DMA_CHANNEL_XFERCFG_SWTRIG_MASK (0x4U) #define DMA_CHANNEL_XFERCFG_SWTRIG_SHIFT (2U) /*! SWTRIG - Software Trigger. * 0b0..Not set. When written by software, the trigger for this channel is not set. A new trigger, as defined by * the HWTRIGEN, TRIGPOL, and TRIGTYPE will be needed to start the channel. * 0b1..Set. When written by software, the trigger for this channel is set immediately. This feature should not * be used with level triggering when TRIGBURST = 0. */ #define DMA_CHANNEL_XFERCFG_SWTRIG(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_SWTRIG_SHIFT)) & DMA_CHANNEL_XFERCFG_SWTRIG_MASK) #define DMA_CHANNEL_XFERCFG_CLRTRIG_MASK (0x8U) #define DMA_CHANNEL_XFERCFG_CLRTRIG_SHIFT (3U) /*! CLRTRIG - Clear Trigger. * 0b0..Not cleared. The trigger is not cleared when this descriptor is exhausted. If there is a reload, the next descriptor will be started. * 0b1..Cleared. The trigger is cleared when this descriptor is exhausted */ #define DMA_CHANNEL_XFERCFG_CLRTRIG(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_CLRTRIG_SHIFT)) & DMA_CHANNEL_XFERCFG_CLRTRIG_MASK) #define DMA_CHANNEL_XFERCFG_SETINTA_MASK (0x10U) #define DMA_CHANNEL_XFERCFG_SETINTA_SHIFT (4U) /*! SETINTA - Set Interrupt flag A for this channel. There is no hardware distinction between * interrupt A and B. They can be used by software to assist with more complex descriptor usage. By * convention, interrupt A may be used when only one interrupt flag is needed. * 0b0..No effect. * 0b1..Set. The INTA flag for this channel will be set when the current descriptor is exhausted. */ #define DMA_CHANNEL_XFERCFG_SETINTA(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_SETINTA_SHIFT)) & DMA_CHANNEL_XFERCFG_SETINTA_MASK) #define DMA_CHANNEL_XFERCFG_SETINTB_MASK (0x20U) #define DMA_CHANNEL_XFERCFG_SETINTB_SHIFT (5U) /*! SETINTB - Set Interrupt flag B for this channel. There is no hardware distinction between * interrupt A and B. They can be used by software to assist with more complex descriptor usage. By * convention, interrupt A may be used when only one interrupt flag is needed. * 0b0..No effect. * 0b1..Set. The INTB flag for this channel will be set when the current descriptor is exhausted. */ #define DMA_CHANNEL_XFERCFG_SETINTB(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_SETINTB_SHIFT)) & DMA_CHANNEL_XFERCFG_SETINTB_MASK) #define DMA_CHANNEL_XFERCFG_WIDTH_MASK (0x300U) #define DMA_CHANNEL_XFERCFG_WIDTH_SHIFT (8U) /*! WIDTH - Transfer width used for this DMA channel. * 0b00..8-bit. 8-bit transfers are performed (8-bit source reads and destination writes). * 0b01..16-bit. 6-bit transfers are performed (16-bit source reads and destination writes). * 0b10..32-bit. 32-bit transfers are performed (32-bit source reads and destination writes). * 0b11..Reserved. Reserved setting, do not use. */ #define DMA_CHANNEL_XFERCFG_WIDTH(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_WIDTH_SHIFT)) & DMA_CHANNEL_XFERCFG_WIDTH_MASK) #define DMA_CHANNEL_XFERCFG_SRCINC_MASK (0x3000U) #define DMA_CHANNEL_XFERCFG_SRCINC_SHIFT (12U) /*! SRCINC - Determines whether the source address is incremented for each DMA transfer. * 0b00..No increment. The source address is not incremented for each transfer. This is the usual case when the source is a peripheral device. * 0b01..1 x width. The source address is incremented by the amount specified by Width for each transfer. This is * the usual case when the source is memory. * 0b10..2 x width. The source address is incremented by 2 times the amount specified by Width for each transfer. * 0b11..4 x width. The source address is incremented by 4 times the amount specified by Width for each transfer. */ #define DMA_CHANNEL_XFERCFG_SRCINC(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_SRCINC_SHIFT)) & DMA_CHANNEL_XFERCFG_SRCINC_MASK) #define DMA_CHANNEL_XFERCFG_DSTINC_MASK (0xC000U) #define DMA_CHANNEL_XFERCFG_DSTINC_SHIFT (14U) /*! DSTINC - Determines whether the destination address is incremented for each DMA transfer. * 0b00..No increment. The destination address is not incremented for each transfer. This is the usual case when * the destination is a peripheral device. * 0b01..1 x width. The destination address is incremented by the amount specified by Width for each transfer. * This is the usual case when the destination is memory. * 0b10..2 x width. The destination address is incremented by 2 times the amount specified by Width for each transfer. * 0b11..4 x width. The destination address is incremented by 4 times the amount specified by Width for each transfer. */ #define DMA_CHANNEL_XFERCFG_DSTINC(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_DSTINC_SHIFT)) & DMA_CHANNEL_XFERCFG_DSTINC_MASK) #define DMA_CHANNEL_XFERCFG_XFERCOUNT_MASK (0x3FF0000U) #define DMA_CHANNEL_XFERCFG_XFERCOUNT_SHIFT (16U) /*! XFERCOUNT - Total number of transfers to be performed, minus 1 encoded. The number of bytes * transferred is: (XFERCOUNT + 1) x data width (as defined by the WIDTH field). The DMA controller * uses this bit field during transfer to count down. Hence, it cannot be used by software to read * back the size of the transfer, for instance, in an interrupt handler. 0x0 = a total of 1 * transfer will be performed. 0x1 = a total of 2 transfers will be performed. 0x3FF = a total of * 1,024 transfers will be performed. */ #define DMA_CHANNEL_XFERCFG_XFERCOUNT(x) (((uint32_t)(((uint32_t)(x)) << DMA_CHANNEL_XFERCFG_XFERCOUNT_SHIFT)) & DMA_CHANNEL_XFERCFG_XFERCOUNT_MASK) /*! @} */ /* The count of DMA_CHANNEL_XFERCFG */ #define DMA_CHANNEL_XFERCFG_COUNT (18U) /*! * @} */ /* end of group DMA_Register_Masks */ /* DMA - Peripheral instance base addresses */ /** Peripheral DMA0 base address */ #define DMA0_BASE (0x50008000u) /** Peripheral DMA0 base pointer */ #define DMA0 ((DMA_Type *)DMA0_BASE) /** Array initializer of DMA peripheral base addresses */ #define DMA_BASE_ADDRS { DMA0_BASE } /** Array initializer of DMA peripheral base pointers */ #define DMA_BASE_PTRS { DMA0 } /** Interrupt vectors for the DMA peripheral type */ #define DMA_IRQS { DMA0_IRQn } /*! * @} */ /* end of group DMA_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- FLASH_CTRL Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup FLASH_CTRL_Peripheral_Access_Layer FLASH_CTRL Peripheral Access Layer * @{ */ /** FLASH_CTRL - Register Layout Typedef */ typedef struct { uint8_t RESERVED_0[16]; __IO uint32_t FLASHCFG; /**< Flash configuration register, offset: 0x10 */ uint8_t RESERVED_1[12]; __IO uint32_t FMSSTART; /**< Flash signature start address register, offset: 0x20 */ __IO uint32_t FMSSTOP; /**< Flash signaure stop address register, offset: 0x24 */ uint8_t RESERVED_2[4]; __I uint32_t FMSW0; /**< Flash signature generation result register returns the flash signature produced by the embedded signature generator.., offset: 0x2C */ uint8_t RESERVED_3[4016]; __I uint32_t FMSTAT; /**< Flash signature generation status bit, offset: 0xFE0 */ uint8_t RESERVED_4[4]; __O uint32_t FMSTATCLR; /**< Clear FLASH signature generation status bit, offset: 0xFE8 */ } FLASH_CTRL_Type; /* ---------------------------------------------------------------------------- -- FLASH_CTRL Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup FLASH_CTRL_Register_Masks FLASH_CTRL Register Masks * @{ */ /*! @name FLASHCFG - Flash configuration register */ /*! @{ */ #define FLASH_CTRL_FLASHCFG_FLASHTIM_MASK (0x3U) #define FLASH_CTRL_FLASHCFG_FLASHTIM_SHIFT (0U) /*! FLASHTIM - Flash memory access time. FLASHTIM +1 is equal to the number of system clocks used for flash access. * 0b00..1 system clock flash access time. * 0b01..2 system clock flash access time. * 0b10-0b11..Reserved. */ #define FLASH_CTRL_FLASHCFG_FLASHTIM(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FLASHCFG_FLASHTIM_SHIFT)) & FLASH_CTRL_FLASHCFG_FLASHTIM_MASK) /*! @} */ /*! @name FMSSTART - Flash signature start address register */ /*! @{ */ #define FLASH_CTRL_FMSSTART_START_MASK (0x1FFFFU) #define FLASH_CTRL_FMSSTART_START_SHIFT (0U) /*! START - Signature generation start address (corresponds to AHB byte address bits[18:2]). */ #define FLASH_CTRL_FMSSTART_START(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSSTART_START_SHIFT)) & FLASH_CTRL_FMSSTART_START_MASK) /*! @} */ /*! @name FMSSTOP - Flash signaure stop address register */ /*! @{ */ #define FLASH_CTRL_FMSSTOP_STOPA_MASK (0x1FFFFU) #define FLASH_CTRL_FMSSTOP_STOPA_SHIFT (0U) /*! STOPA - Stop address for signature generation (the word specified by STOP is included in the * address range). The address is in units of memory words, not bytes. */ #define FLASH_CTRL_FMSSTOP_STOPA(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSSTOP_STOPA_SHIFT)) & FLASH_CTRL_FMSSTOP_STOPA_MASK) #define FLASH_CTRL_FMSSTOP_STRTBIST_MASK (0x80000000U) #define FLASH_CTRL_FMSSTOP_STRTBIST_SHIFT (31U) /*! STRTBIST - When this bit is written to 1, signature generation starts. At the end of signature * generation, this bit is automatically cleared. */ #define FLASH_CTRL_FMSSTOP_STRTBIST(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSSTOP_STRTBIST_SHIFT)) & FLASH_CTRL_FMSSTOP_STRTBIST_MASK) /*! @} */ /*! @name FMSW0 - Flash signature generation result register returns the flash signature produced by the embedded signature generator.. */ /*! @{ */ #define FLASH_CTRL_FMSW0_SIG_MASK (0xFFFFFFFFU) #define FLASH_CTRL_FMSW0_SIG_SHIFT (0U) /*! SIG - 32-bit signature. */ #define FLASH_CTRL_FMSW0_SIG(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSW0_SIG_SHIFT)) & FLASH_CTRL_FMSW0_SIG_MASK) /*! @} */ /*! @name FMSTAT - Flash signature generation status bit */ /*! @{ */ #define FLASH_CTRL_FMSTAT_SIGNATURE_DONE_MASK (0x2U) #define FLASH_CTRL_FMSTAT_SIGNATURE_DONE_SHIFT (1U) /*! SIGNATURE_DONE - This status bit is set at the end of signature computation */ #define FLASH_CTRL_FMSTAT_SIGNATURE_DONE(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSTAT_SIGNATURE_DONE_SHIFT)) & FLASH_CTRL_FMSTAT_SIGNATURE_DONE_MASK) /*! @} */ /*! @name FMSTATCLR - Clear FLASH signature generation status bit */ /*! @{ */ #define FLASH_CTRL_FMSTATCLR_SIGNATURE_DONE_CLR_MASK (0x2U) #define FLASH_CTRL_FMSTATCLR_SIGNATURE_DONE_CLR_SHIFT (1U) /*! SIGNATURE_DONE_CLR - When the bit is written to 1, the SIGNATURE_DONE bit is cleared. */ #define FLASH_CTRL_FMSTATCLR_SIGNATURE_DONE_CLR(x) (((uint32_t)(((uint32_t)(x)) << FLASH_CTRL_FMSTATCLR_SIGNATURE_DONE_CLR_SHIFT)) & FLASH_CTRL_FMSTATCLR_SIGNATURE_DONE_CLR_MASK) /*! @} */ /*! * @} */ /* end of group FLASH_CTRL_Register_Masks */ /* FLASH_CTRL - Peripheral instance base addresses */ /** Peripheral FLASH_CTRL base address */ #define FLASH_CTRL_BASE (0x40040000u) /** Peripheral FLASH_CTRL base pointer */ #define FLASH_CTRL ((FLASH_CTRL_Type *)FLASH_CTRL_BASE) /** Array initializer of FLASH_CTRL peripheral base addresses */ #define FLASH_CTRL_BASE_ADDRS { FLASH_CTRL_BASE } /** Array initializer of FLASH_CTRL peripheral base pointers */ #define FLASH_CTRL_BASE_PTRS { FLASH_CTRL } /** Interrupt vectors for the FLASH_CTRL peripheral type */ #define FLASH_CTRL_IRQS { FLASH_IRQn } /*! * @} */ /* end of group FLASH_CTRL_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- GPIO Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup GPIO_Peripheral_Access_Layer GPIO Peripheral Access Layer * @{ */ /** GPIO - Register Layout Typedef */ typedef struct { __IO uint8_t B[1][29]; /**< Byte pin registers for all port 0 and 1 GPIO pins, array offset: 0x0, array step: index*0x1D, index2*0x1 */ uint8_t RESERVED_0[4067]; __IO uint32_t W[1][29]; /**< Word pin registers for all port 0 and 1 GPIO pins, array offset: 0x1000, array step: index*0x74, index2*0x4 */ uint8_t RESERVED_1[3980]; __IO uint32_t DIR[1]; /**< Direction registers, array offset: 0x2000, array step: 0x4 */ uint8_t RESERVED_2[124]; __IO uint32_t MASK[1]; /**< Mask register, array offset: 0x2080, array step: 0x4 */ uint8_t RESERVED_3[124]; __IO uint32_t PIN[1]; /**< Port pin register, array offset: 0x2100, array step: 0x4 */ uint8_t RESERVED_4[124]; __IO uint32_t MPIN[1]; /**< Masked port register, array offset: 0x2180, array step: 0x4 */ uint8_t RESERVED_5[124]; __IO uint32_t SET[1]; /**< Write: Set register for port Read: output bits for port, array offset: 0x2200, array step: 0x4 */ uint8_t RESERVED_6[124]; __O uint32_t CLR[1]; /**< Clear port, array offset: 0x2280, array step: 0x4 */ uint8_t RESERVED_7[124]; __O uint32_t NOT[1]; /**< Toggle port, array offset: 0x2300, array step: 0x4 */ uint8_t RESERVED_8[124]; __O uint32_t DIRSET[1]; /**< Set pin direction bits for port, array offset: 0x2380, array step: 0x4 */ uint8_t RESERVED_9[124]; __O uint32_t DIRCLR[1]; /**< Clear pin direction bits for port, array offset: 0x2400, array step: 0x4 */ uint8_t RESERVED_10[124]; __O uint32_t DIRNOT[1]; /**< Toggle pin direction bits for port, array offset: 0x2480, array step: 0x4 */ } GPIO_Type; /* ---------------------------------------------------------------------------- -- GPIO Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup GPIO_Register_Masks GPIO Register Masks * @{ */ /*! @name B - Byte pin registers for all port 0 and 1 GPIO pins */ /*! @{ */ #define GPIO_B_PBYTE_MASK (0x1U) #define GPIO_B_PBYTE_SHIFT (0U) /*! PBYTE - Read: state of the pin PIOm_n, regardless of direction, masking, or alternate function, * except that pins configured as analog I/O always read as 0. One register for each port pin. * Supported pins depends on the specific device and package. Write: loads the pin's output bit. * One register for each port pin. Supported pins depends on the specific device and package. */ #define GPIO_B_PBYTE(x) (((uint8_t)(((uint8_t)(x)) << GPIO_B_PBYTE_SHIFT)) & GPIO_B_PBYTE_MASK) /*! @} */ /* The count of GPIO_B */ #define GPIO_B_COUNT (1U) /* The count of GPIO_B */ #define GPIO_B_COUNT2 (29U) /*! @name W - Word pin registers for all port 0 and 1 GPIO pins */ /*! @{ */ #define GPIO_W_PWORD_MASK (0xFFFFFFFFU) #define GPIO_W_PWORD_SHIFT (0U) /*! PWORD - Read 0: pin PIOm_n is LOW. Write 0: clear output bit. Read 0xFFFF FFFF: pin PIOm_n is * HIGH. Write any value 0x0000 0001 to 0xFFFF FFFF: set output bit. Only 0 or 0xFFFF FFFF can be * read. Writing any value other than 0 will set the output bit. One register for each port pin. * Supported pins depends on the specific device and package. */ #define GPIO_W_PWORD(x) (((uint32_t)(((uint32_t)(x)) << GPIO_W_PWORD_SHIFT)) & GPIO_W_PWORD_MASK) /*! @} */ /* The count of GPIO_W */ #define GPIO_W_COUNT (1U) /* The count of GPIO_W */ #define GPIO_W_COUNT2 (29U) /*! @name DIR - Direction registers */ /*! @{ */ #define GPIO_DIR_DIRP_MASK (0x1FFFFFFFU) #define GPIO_DIR_DIRP_SHIFT (0U) /*! DIRP - Selects pin direction for pin PIOm_n (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported * pins depends on the specific device and package. 0 = input. 1 = output. */ #define GPIO_DIR_DIRP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_DIR_DIRP_SHIFT)) & GPIO_DIR_DIRP_MASK) /*! @} */ /* The count of GPIO_DIR */ #define GPIO_DIR_COUNT (1U) /*! @name MASK - Mask register */ /*! @{ */ #define GPIO_MASK_MASKP_MASK (0x1FFFFFFFU) #define GPIO_MASK_MASKP_SHIFT (0U) /*! MASKP - Controls which bits corresponding to PIOm_n are active in the MPORT register (bit 0 = * PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on the specific device and package. 0 = * Read MPORT: pin state; write MPORT: load output bit. 1 = Read MPORT: 0; write MPORT: output bit * not affected. */ #define GPIO_MASK_MASKP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_MASK_MASKP_SHIFT)) & GPIO_MASK_MASKP_MASK) /*! @} */ /* The count of GPIO_MASK */ #define GPIO_MASK_COUNT (1U) /*! @name PIN - Port pin register */ /*! @{ */ #define GPIO_PIN_PORT_MASK (0x1FFFFFFFU) #define GPIO_PIN_PORT_SHIFT (0U) /*! PORT - Reads pin states or loads output bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported * pins depends on the specific device and package. 0 = Read: pin is low; write: clear output bit. * 1 = Read: pin is high; write: set output bit. */ #define GPIO_PIN_PORT(x) (((uint32_t)(((uint32_t)(x)) << GPIO_PIN_PORT_SHIFT)) & GPIO_PIN_PORT_MASK) /*! @} */ /* The count of GPIO_PIN */ #define GPIO_PIN_COUNT (1U) /*! @name MPIN - Masked port register */ /*! @{ */ #define GPIO_MPIN_MPORTP_MASK (0x1FFFFFFFU) #define GPIO_MPIN_MPORTP_SHIFT (0U) /*! MPORTP - Masked port register (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on * the specific device and package. 0 = Read: pin is LOW and/or the corresponding bit in the MASK * register is 1; write: clear output bit if the corresponding bit in the MASK register is 0. 1 * = Read: pin is HIGH and the corresponding bit in the MASK register is 0; write: set output bit * if the corresponding bit in the MASK register is 0. */ #define GPIO_MPIN_MPORTP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_MPIN_MPORTP_SHIFT)) & GPIO_MPIN_MPORTP_MASK) /*! @} */ /* The count of GPIO_MPIN */ #define GPIO_MPIN_COUNT (1U) /*! @name SET - Write: Set register for port Read: output bits for port */ /*! @{ */ #define GPIO_SET_SETP_MASK (0x1FFFFFFFU) #define GPIO_SET_SETP_SHIFT (0U) /*! SETP - Read or set output bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on * the specific device and package. 0 = Read: output bit: write: no operation. 1 = Read: output * bit; write: set output bit. */ #define GPIO_SET_SETP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_SET_SETP_SHIFT)) & GPIO_SET_SETP_MASK) /*! @} */ /* The count of GPIO_SET */ #define GPIO_SET_COUNT (1U) /*! @name CLR - Clear port */ /*! @{ */ #define GPIO_CLR_CLRP_MASK (0x1FFFFFFFU) #define GPIO_CLR_CLRP_SHIFT (0U) /*! CLRP - Clear output bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on the * specific device and package. 0 = No operation. 1 = Clear output bit. */ #define GPIO_CLR_CLRP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_CLR_CLRP_SHIFT)) & GPIO_CLR_CLRP_MASK) /*! @} */ /* The count of GPIO_CLR */ #define GPIO_CLR_COUNT (1U) /*! @name NOT - Toggle port */ /*! @{ */ #define GPIO_NOT_NOTP_MASK (0x1FFFFFFFU) #define GPIO_NOT_NOTP_SHIFT (0U) /*! NOTP - Toggle output bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on the * specific device and package. 0 = no operation. 1 = Toggle output bit. */ #define GPIO_NOT_NOTP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_NOT_NOTP_SHIFT)) & GPIO_NOT_NOTP_MASK) /*! @} */ /* The count of GPIO_NOT */ #define GPIO_NOT_COUNT (1U) /*! @name DIRSET - Set pin direction bits for port */ /*! @{ */ #define GPIO_DIRSET_DIRSETP_MASK (0x1FFFFFFFU) #define GPIO_DIRSET_DIRSETP_SHIFT (0U) /*! DIRSETP - Set direction bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on * the specific device and package. 0 = No operation. 1 = Set direction bit. */ #define GPIO_DIRSET_DIRSETP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_DIRSET_DIRSETP_SHIFT)) & GPIO_DIRSET_DIRSETP_MASK) /*! @} */ /* The count of GPIO_DIRSET */ #define GPIO_DIRSET_COUNT (1U) /*! @name DIRCLR - Clear pin direction bits for port */ /*! @{ */ #define GPIO_DIRCLR_DIRCLRP_MASK (0x1FFFFFFFU) #define GPIO_DIRCLR_DIRCLRP_SHIFT (0U) /*! DIRCLRP - Clear direction bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends on * the specific device and package. 0 = No operation. 1 = Clear direction bit. */ #define GPIO_DIRCLR_DIRCLRP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_DIRCLR_DIRCLRP_SHIFT)) & GPIO_DIRCLR_DIRCLRP_MASK) /*! @} */ /* The count of GPIO_DIRCLR */ #define GPIO_DIRCLR_COUNT (1U) /*! @name DIRNOT - Toggle pin direction bits for port */ /*! @{ */ #define GPIO_DIRNOT_DIRNOTP_MASK (0x1FFFFFFFU) #define GPIO_DIRNOT_DIRNOTP_SHIFT (0U) /*! DIRNOTP - Toggle direction bits (bit 0 = PIOn_0, bit 1 = PIOn_1, etc.). Supported pins depends * on the specific device and package. 0 = no operation. 1 = Toggle direction bit. */ #define GPIO_DIRNOT_DIRNOTP(x) (((uint32_t)(((uint32_t)(x)) << GPIO_DIRNOT_DIRNOTP_SHIFT)) & GPIO_DIRNOT_DIRNOTP_MASK) /*! @} */ /* The count of GPIO_DIRNOT */ #define GPIO_DIRNOT_COUNT (1U) /*! * @} */ /* end of group GPIO_Register_Masks */ /* GPIO - Peripheral instance base addresses */ /** Peripheral GPIO base address */ #define GPIO_BASE (0xA0000000u) /** Peripheral GPIO base pointer */ #define GPIO ((GPIO_Type *)GPIO_BASE) /** Array initializer of GPIO peripheral base addresses */ #define GPIO_BASE_ADDRS { GPIO_BASE } /** Array initializer of GPIO peripheral base pointers */ #define GPIO_BASE_PTRS { GPIO } /*! * @} */ /* end of group GPIO_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- I2C Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup I2C_Peripheral_Access_Layer I2C Peripheral Access Layer * @{ */ /** I2C - Register Layout Typedef */ typedef struct { __IO uint32_t CFG; /**< Configuration for shared functions., offset: 0x0 */ __IO uint32_t STAT; /**< Status register for Master, Slave, and Monitor functions., offset: 0x4 */ __IO uint32_t INTENSET; /**< Interrupt Enable Set and read register., offset: 0x8 */ __O uint32_t INTENCLR; /**< Interrupt Enable Clear register., offset: 0xC */ __IO uint32_t TIMEOUT; /**< Time-out value register., offset: 0x10 */ __IO uint32_t CLKDIV; /**< Clock pre-divider for the entire I2C interface. This determines what time increments are used for the MSTTIME register, and controls some timing of the Slave function., offset: 0x14 */ __I uint32_t INTSTAT; /**< Interrupt Status register for Master, Slave, and Monitor functions., offset: 0x18 */ uint8_t RESERVED_0[4]; __IO uint32_t MSTCTL; /**< Master control register., offset: 0x20 */ __IO uint32_t MSTTIME; /**< Master timing configuration., offset: 0x24 */ __IO uint32_t MSTDAT; /**< Combined Master receiver and transmitter data register., offset: 0x28 */ uint8_t RESERVED_1[20]; __IO uint32_t SLVCTL; /**< Slave control register., offset: 0x40 */ __IO uint32_t SLVDAT; /**< Combined Slave receiver and transmitter data register., offset: 0x44 */ __IO uint32_t SLVADR[4]; /**< Slave address register., array offset: 0x48, array step: 0x4 */ __IO uint32_t SLVQUAL0; /**< Slave Qualification for address 0., offset: 0x58 */ uint8_t RESERVED_2[36]; __I uint32_t MONRXDAT; /**< Monitor receiver data register., offset: 0x80 */ } I2C_Type; /* ---------------------------------------------------------------------------- -- I2C Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup I2C_Register_Masks I2C Register Masks * @{ */ /*! @name CFG - Configuration for shared functions. */ /*! @{ */ #define I2C_CFG_MSTEN_MASK (0x1U) #define I2C_CFG_MSTEN_SHIFT (0U) /*! MSTEN - Master Enable. When disabled, configurations settings for the Master function are not * changed, but the Master function is internally reset. * 0b0..Disabled. The I2C Master function is disabled. * 0b1..Enabled. The I2C Master function is enabled. */ #define I2C_CFG_MSTEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_CFG_MSTEN_SHIFT)) & I2C_CFG_MSTEN_MASK) #define I2C_CFG_SLVEN_MASK (0x2U) #define I2C_CFG_SLVEN_SHIFT (1U) /*! SLVEN - Slave Enable. When disabled, configurations settings for the Slave function are not * changed, but the Slave function is internally reset. * 0b0..Disabled. The I2C slave function is disabled. * 0b1..Enabled. The I2C slave function is enabled. */ #define I2C_CFG_SLVEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_CFG_SLVEN_SHIFT)) & I2C_CFG_SLVEN_MASK) #define I2C_CFG_MONEN_MASK (0x4U) #define I2C_CFG_MONEN_SHIFT (2U) /*! MONEN - Monitor Enable. When disabled, configurations settings for the Monitor function are not * changed, but the Monitor function is internally reset. * 0b0..Disabled. The I2C Monitor function is disabled. * 0b1..Enabled. The I2C Monitor function is enabled. */ #define I2C_CFG_MONEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_CFG_MONEN_SHIFT)) & I2C_CFG_MONEN_MASK) #define I2C_CFG_TIMEOUTEN_MASK (0x8U) #define I2C_CFG_TIMEOUTEN_SHIFT (3U) /*! TIMEOUTEN - I2C bus Time-out Enable. When disabled, the time-out function is internally reset. * 0b0..Disabled. Time-out function is disabled. * 0b1..Enabled. Time-out function is enabled. Both types of time-out flags will be generated and will cause * interrupts if they are enabled. Typically, only one time-out will be used in a system. */ #define I2C_CFG_TIMEOUTEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_CFG_TIMEOUTEN_SHIFT)) & I2C_CFG_TIMEOUTEN_MASK) #define I2C_CFG_MONCLKSTR_MASK (0x10U) #define I2C_CFG_MONCLKSTR_SHIFT (4U) /*! MONCLKSTR - Monitor function Clock Stretching. * 0b0..Disabled. The Monitor function will not perform clock stretching. Software or DMA may not always be able * to read data provided by the Monitor function before it is overwritten. This mode may be used when * non-invasive monitoring is critical. * 0b1..Enabled. The Monitor function will perform clock stretching in order to ensure that software or DMA can * read all incoming data supplied by the Monitor function. */ #define I2C_CFG_MONCLKSTR(x) (((uint32_t)(((uint32_t)(x)) << I2C_CFG_MONCLKSTR_SHIFT)) & I2C_CFG_MONCLKSTR_MASK) /*! @} */ /*! @name STAT - Status register for Master, Slave, and Monitor functions. */ /*! @{ */ #define I2C_STAT_MSTPENDING_MASK (0x1U) #define I2C_STAT_MSTPENDING_SHIFT (0U) /*! MSTPENDING - Master Pending. Indicates that the Master is waiting to continue communication on * the I2C-bus (pending) or is idle. When the master is pending, the MSTSTATE bits indicate what * type of software service if any the master expects. This flag will cause an interrupt when set * if, enabled via the INTENSET register. The MSTPENDING flag is not set when the DMA is handling * an event (if the MSTDMA bit in the MSTCTL register is set). If the master is in the idle * state, and no communication is needed, mask this interrupt. * 0b0..In progress. Communication is in progress and the Master function is busy and cannot currently accept a command. * 0b1..Pending. The Master function needs software service or is in the idle state. If the master is not in the * idle state, it is waiting to receive or transmit data or the NACK bit. */ #define I2C_STAT_MSTPENDING(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MSTPENDING_SHIFT)) & I2C_STAT_MSTPENDING_MASK) #define I2C_STAT_MSTSTATE_MASK (0xEU) #define I2C_STAT_MSTSTATE_SHIFT (1U) /*! MSTSTATE - Master State code. The master state code reflects the master state when the * MSTPENDING bit is set, that is the master is pending or in the idle state. Each value of this field * indicates a specific required service for the Master function. All other values are reserved. See * Table 400 for details of state values and appropriate responses. * 0b000..Idle. The Master function is available to be used for a new transaction. * 0b001..Receive ready. Received data available (Master Receiver mode). Address plus Read was previously sent and Acknowledged by slave. * 0b010..Transmit ready. Data can be transmitted (Master Transmitter mode). Address plus Write was previously sent and Acknowledged by slave. * 0b011..NACK Address. Slave NACKed address. * 0b100..NACK Data. Slave NACKed transmitted data. */ #define I2C_STAT_MSTSTATE(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MSTSTATE_SHIFT)) & I2C_STAT_MSTSTATE_MASK) #define I2C_STAT_MSTARBLOSS_MASK (0x10U) #define I2C_STAT_MSTARBLOSS_SHIFT (4U) /*! MSTARBLOSS - Master Arbitration Loss flag. This flag can be cleared by software writing a 1 to * this bit. It is also cleared automatically a 1 is written to MSTCONTINUE. * 0b0..No Arbitration Loss has occurred. * 0b1..Arbitration loss. The Master function has experienced an Arbitration Loss. At this point, the Master * function has already stopped driving the bus and gone to an idle state. Software can respond by doing nothing, * or by sending a Start in order to attempt to gain control of the bus when it next becomes idle. */ #define I2C_STAT_MSTARBLOSS(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MSTARBLOSS_SHIFT)) & I2C_STAT_MSTARBLOSS_MASK) #define I2C_STAT_MSTSTSTPERR_MASK (0x40U) #define I2C_STAT_MSTSTSTPERR_SHIFT (6U) /*! MSTSTSTPERR - Master Start/Stop Error flag. This flag can be cleared by software writing a 1 to * this bit. It is also cleared automatically a 1 is written to MSTCONTINUE. * 0b0..No Start/Stop Error has occurred. * 0b1..The Master function has experienced a Start/Stop Error. A Start or Stop was detected at a time when it is * not allowed by the I2C specification. The Master interface has stopped driving the bus and gone to an * idle state, no action is required. A request for a Start could be made, or software could attempt to insure * that the bus has not stalled. */ #define I2C_STAT_MSTSTSTPERR(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MSTSTSTPERR_SHIFT)) & I2C_STAT_MSTSTSTPERR_MASK) #define I2C_STAT_SLVPENDING_MASK (0x100U) #define I2C_STAT_SLVPENDING_SHIFT (8U) /*! SLVPENDING - Slave Pending. Indicates that the Slave function is waiting to continue * communication on the I2C-bus and needs software service. This flag will cause an interrupt when set if * enabled via INTENSET. The SLVPENDING flag is not set when the DMA is handling an event (if the * SLVDMA bit in the SLVCTL register is set). The SLVPENDING flag is read-only and is * automatically cleared when a 1 is written to the SLVCONTINUE bit in the SLVCTL register. The point in time * when SlvPending is set depends on whether the I2C interface is in HSCAPABLE mode. See Section * 25.7.2.2.2. When the I2C interface is configured to be HSCAPABLE, HS master codes are * detected automatically. Due to the requirements of the HS I2C specification, slave addresses must * also be detected automatically, since the address must be acknowledged before the clock can be * stretched. * 0b0..In progress. The Slave function does not currently need service. * 0b1..Pending. The Slave function needs service. Information on what is needed can be found in the adjacent SLVSTATE field. */ #define I2C_STAT_SLVPENDING(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVPENDING_SHIFT)) & I2C_STAT_SLVPENDING_MASK) #define I2C_STAT_SLVSTATE_MASK (0x600U) #define I2C_STAT_SLVSTATE_SHIFT (9U) /*! SLVSTATE - Slave State code. Each value of this field indicates a specific required service for * the Slave function. All other values are reserved. See Table 401 for state values and actions. * note that the occurrence of some states and how they are handled are affected by DMA mode and * Automatic Operation modes. * 0b00..Slave address. Address plus R/W received. At least one of the four slave addresses has been matched by hardware. * 0b01..Slave receive. Received data is available (Slave Receiver mode). * 0b10..Slave transmit. Data can be transmitted (Slave Transmitter mode). */ #define I2C_STAT_SLVSTATE(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVSTATE_SHIFT)) & I2C_STAT_SLVSTATE_MASK) #define I2C_STAT_SLVNOTSTR_MASK (0x800U) #define I2C_STAT_SLVNOTSTR_SHIFT (11U) /*! SLVNOTSTR - Slave Not Stretching. Indicates when the slave function is stretching the I2C clock. * This is needed in order to gracefully invoke Deep Sleep or Power-down modes during slave * operation. This read-only flag reflects the slave function status in real time. * 0b0..Stretching. The slave function is currently stretching the I2C bus clock. Deep-Sleep or Power-down mode cannot be entered at this time. * 0b1..Not stretching. The slave function is not currently stretching the I 2C bus clock. Deep-sleep or * Power-down mode could be entered at this time. */ #define I2C_STAT_SLVNOTSTR(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVNOTSTR_SHIFT)) & I2C_STAT_SLVNOTSTR_MASK) #define I2C_STAT_SLVIDX_MASK (0x3000U) #define I2C_STAT_SLVIDX_SHIFT (12U) /*! SLVIDX - Slave address match Index. This field is valid when the I2C slave function has been * selected by receiving an address that matches one of the slave addresses defined by any enabled * slave address registers, and provides an identification of the address that was matched. It is * possible that more than one address could be matched, but only one match can be reported here. * 0b00..Address 0. Slave address 0 was matched. * 0b01..Address 1. Slave address 1 was matched. * 0b10..Address 2. Slave address 2 was matched. * 0b11..Address 3. Slave address 3 was matched. */ #define I2C_STAT_SLVIDX(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVIDX_SHIFT)) & I2C_STAT_SLVIDX_MASK) #define I2C_STAT_SLVSEL_MASK (0x4000U) #define I2C_STAT_SLVSEL_SHIFT (14U) /*! SLVSEL - Slave selected flag. SLVSEL is set after an address match when software tells the Slave * function to acknowledge the address, or when the address has been automatically acknowledged. * It is cleared when another address cycle presents an address that does not match an enabled * address on the Slave function, when slave software decides to NACK a matched address, when * there is a Stop detected on the bus, when the master NACKs slave data, and in some combinations of * Automatic Operation. SLVSEL is not cleared if software NACKs data. * 0b0..Not selected. The Slave function is not currently selected. * 0b1..Selected. The Slave function is currently selected. */ #define I2C_STAT_SLVSEL(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVSEL_SHIFT)) & I2C_STAT_SLVSEL_MASK) #define I2C_STAT_SLVDESEL_MASK (0x8000U) #define I2C_STAT_SLVDESEL_SHIFT (15U) /*! SLVDESEL - Slave Deselected flag. This flag will cause an interrupt when set if enabled via * INTENSET. This flag can be cleared by writing a 1 to this bit. * 0b0..Not deselected. The Slave function has not become deselected. This does not mean that it is currently * selected. That information can be found in the SLVSEL flag. * 0b1..Deselected. The Slave function has become deselected. This is specifically caused by the SLVSEL flag * changing from 1 to 0. See the description of SLVSEL for details on when that event occurs. */ #define I2C_STAT_SLVDESEL(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SLVDESEL_SHIFT)) & I2C_STAT_SLVDESEL_MASK) #define I2C_STAT_MONRDY_MASK (0x10000U) #define I2C_STAT_MONRDY_SHIFT (16U) /*! MONRDY - Monitor Ready. This flag is cleared when the MONRXDAT register is read. * 0b0..No data. The Monitor function does not currently have data available. * 0b1..Data waiting. The Monitor function has data waiting to be read. */ #define I2C_STAT_MONRDY(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MONRDY_SHIFT)) & I2C_STAT_MONRDY_MASK) #define I2C_STAT_MONOV_MASK (0x20000U) #define I2C_STAT_MONOV_SHIFT (17U) /*! MONOV - Monitor Overflow flag. * 0b0..No overrun. Monitor data has not overrun. * 0b1..Overrun. A Monitor data overrun has occurred. This can only happen when Monitor clock stretching not * enabled via the MONCLKSTR bit in the CFG register. Writing 1 to this bit clears the flag. */ #define I2C_STAT_MONOV(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MONOV_SHIFT)) & I2C_STAT_MONOV_MASK) #define I2C_STAT_MONACTIVE_MASK (0x40000U) #define I2C_STAT_MONACTIVE_SHIFT (18U) /*! MONACTIVE - Monitor Active flag. Indicates when the Monitor function considers the I 2C bus to * be active. Active is defined here as when some Master is on the bus: a bus Start has occurred * more recently than a bus Stop. * 0b0..Inactive. The Monitor function considers the I2C bus to be inactive. * 0b1..Active. The Monitor function considers the I2C bus to be active. */ #define I2C_STAT_MONACTIVE(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MONACTIVE_SHIFT)) & I2C_STAT_MONACTIVE_MASK) #define I2C_STAT_MONIDLE_MASK (0x80000U) #define I2C_STAT_MONIDLE_SHIFT (19U) /*! MONIDLE - Monitor Idle flag. This flag is set when the Monitor function sees the I2C bus change * from active to inactive. This can be used by software to decide when to process data * accumulated by the Monitor function. This flag will cause an interrupt when set if enabled via the * INTENSET register. The flag can be cleared by writing a 1 to this bit. * 0b0..Not idle. The I2C bus is not idle, or this flag has been cleared by software. * 0b1..Idle. The I2C bus has gone idle at least once since the last time this flag was cleared by software. */ #define I2C_STAT_MONIDLE(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_MONIDLE_SHIFT)) & I2C_STAT_MONIDLE_MASK) #define I2C_STAT_EVENTTIMEOUT_MASK (0x1000000U) #define I2C_STAT_EVENTTIMEOUT_SHIFT (24U) /*! EVENTTIMEOUT - Event Time-out Interrupt flag. Indicates when the time between events has been * longer than the time specified by the TIMEOUT register. Events include Start, Stop, and clock * edges. The flag is cleared by writing a 1 to this bit. No time-out is created when the I2C-bus * is idle. * 0b0..No time-out. I2C bus events have not caused a time-out. * 0b1..Event time-out. The time between I2C bus events has been longer than the time specified by the TIMEOUT register. */ #define I2C_STAT_EVENTTIMEOUT(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_EVENTTIMEOUT_SHIFT)) & I2C_STAT_EVENTTIMEOUT_MASK) #define I2C_STAT_SCLTIMEOUT_MASK (0x2000000U) #define I2C_STAT_SCLTIMEOUT_SHIFT (25U) /*! SCLTIMEOUT - SCL Time-out Interrupt flag. Indicates when SCL has remained low longer than the * time specific by the TIMEOUT register. The flag is cleared by writing a 1 to this bit. * 0b0..No time-out. SCL low time has not caused a time-out. * 0b1..Time-out. SCL low time has caused a time-out. */ #define I2C_STAT_SCLTIMEOUT(x) (((uint32_t)(((uint32_t)(x)) << I2C_STAT_SCLTIMEOUT_SHIFT)) & I2C_STAT_SCLTIMEOUT_MASK) /*! @} */ /*! @name INTENSET - Interrupt Enable Set and read register. */ /*! @{ */ #define I2C_INTENSET_MSTPENDINGEN_MASK (0x1U) #define I2C_INTENSET_MSTPENDINGEN_SHIFT (0U) /*! MSTPENDINGEN - Master Pending interrupt Enable. * 0b0..Disabled. The MstPending interrupt is disabled. * 0b1..Enabled. The MstPending interrupt is enabled. */ #define I2C_INTENSET_MSTPENDINGEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MSTPENDINGEN_SHIFT)) & I2C_INTENSET_MSTPENDINGEN_MASK) #define I2C_INTENSET_MSTARBLOSSEN_MASK (0x10U) #define I2C_INTENSET_MSTARBLOSSEN_SHIFT (4U) /*! MSTARBLOSSEN - Master Arbitration Loss interrupt Enable. * 0b0..Disabled. The MstArbLoss interrupt is disabled. * 0b1..Enabled. The MstArbLoss interrupt is enabled. */ #define I2C_INTENSET_MSTARBLOSSEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MSTARBLOSSEN_SHIFT)) & I2C_INTENSET_MSTARBLOSSEN_MASK) #define I2C_INTENSET_MSTSTSTPERREN_MASK (0x40U) #define I2C_INTENSET_MSTSTSTPERREN_SHIFT (6U) /*! MSTSTSTPERREN - Master Start/Stop Error interrupt Enable. * 0b0..Disabled. The MstStStpErr interrupt is disabled. * 0b1..Enabled. The MstStStpErr interrupt is enabled. */ #define I2C_INTENSET_MSTSTSTPERREN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MSTSTSTPERREN_SHIFT)) & I2C_INTENSET_MSTSTSTPERREN_MASK) #define I2C_INTENSET_SLVPENDINGEN_MASK (0x100U) #define I2C_INTENSET_SLVPENDINGEN_SHIFT (8U) /*! SLVPENDINGEN - Slave Pending interrupt Enable. * 0b0..Disabled. The SlvPending interrupt is disabled. * 0b1..Enabled. The SlvPending interrupt is enabled. */ #define I2C_INTENSET_SLVPENDINGEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_SLVPENDINGEN_SHIFT)) & I2C_INTENSET_SLVPENDINGEN_MASK) #define I2C_INTENSET_SLVNOTSTREN_MASK (0x800U) #define I2C_INTENSET_SLVNOTSTREN_SHIFT (11U) /*! SLVNOTSTREN - Slave Not Stretching interrupt Enable. * 0b0..Disabled. The SlvNotStr interrupt is disabled. * 0b1..Enabled. The SlvNotStr interrupt is enabled. */ #define I2C_INTENSET_SLVNOTSTREN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_SLVNOTSTREN_SHIFT)) & I2C_INTENSET_SLVNOTSTREN_MASK) #define I2C_INTENSET_SLVDESELEN_MASK (0x8000U) #define I2C_INTENSET_SLVDESELEN_SHIFT (15U) /*! SLVDESELEN - Slave Deselect interrupt Enable. * 0b0..Disabled. The SlvDeSel interrupt is disabled. * 0b1..Enabled. The SlvDeSel interrupt is enabled. */ #define I2C_INTENSET_SLVDESELEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_SLVDESELEN_SHIFT)) & I2C_INTENSET_SLVDESELEN_MASK) #define I2C_INTENSET_MONRDYEN_MASK (0x10000U) #define I2C_INTENSET_MONRDYEN_SHIFT (16U) /*! MONRDYEN - Monitor data Ready interrupt Enable. * 0b0..Disabled. The MonRdy interrupt is disabled. * 0b1..Enabled. The MonRdy interrupt is enabled. */ #define I2C_INTENSET_MONRDYEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MONRDYEN_SHIFT)) & I2C_INTENSET_MONRDYEN_MASK) #define I2C_INTENSET_MONOVEN_MASK (0x20000U) #define I2C_INTENSET_MONOVEN_SHIFT (17U) /*! MONOVEN - Monitor Overrun interrupt Enable. * 0b0..Disabled. The MonOv interrupt is disabled. * 0b1..Enabled. The MonOv interrupt is enabled. */ #define I2C_INTENSET_MONOVEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MONOVEN_SHIFT)) & I2C_INTENSET_MONOVEN_MASK) #define I2C_INTENSET_MONIDLEEN_MASK (0x80000U) #define I2C_INTENSET_MONIDLEEN_SHIFT (19U) /*! MONIDLEEN - Monitor Idle interrupt Enable. * 0b0..Disabled. The MonIdle interrupt is disabled. * 0b1..Enabled. The MonIdle interrupt is enabled. */ #define I2C_INTENSET_MONIDLEEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_MONIDLEEN_SHIFT)) & I2C_INTENSET_MONIDLEEN_MASK) #define I2C_INTENSET_EVENTTIMEOUTEN_MASK (0x1000000U) #define I2C_INTENSET_EVENTTIMEOUTEN_SHIFT (24U) /*! EVENTTIMEOUTEN - Event time-out interrupt Enable. * 0b0..Disabled. The Event time-out interrupt is disabled. * 0b1..Enabled. The Event time-out interrupt is enabled. */ #define I2C_INTENSET_EVENTTIMEOUTEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_EVENTTIMEOUTEN_SHIFT)) & I2C_INTENSET_EVENTTIMEOUTEN_MASK) #define I2C_INTENSET_SCLTIMEOUTEN_MASK (0x2000000U) #define I2C_INTENSET_SCLTIMEOUTEN_SHIFT (25U) /*! SCLTIMEOUTEN - SCL time-out interrupt Enable. * 0b0..Disabled. The SCL time-out interrupt is disabled. * 0b1..Enabled. The SCL time-out interrupt is enabled. */ #define I2C_INTENSET_SCLTIMEOUTEN(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENSET_SCLTIMEOUTEN_SHIFT)) & I2C_INTENSET_SCLTIMEOUTEN_MASK) /*! @} */ /*! @name INTENCLR - Interrupt Enable Clear register. */ /*! @{ */ #define I2C_INTENCLR_MSTPENDINGCLR_MASK (0x1U) #define I2C_INTENCLR_MSTPENDINGCLR_SHIFT (0U) /*! MSTPENDINGCLR - Master Pending interrupt clear. Writing 1 to this bit clears the corresponding * bit in the INTENSET register if implemented. */ #define I2C_INTENCLR_MSTPENDINGCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MSTPENDINGCLR_SHIFT)) & I2C_INTENCLR_MSTPENDINGCLR_MASK) #define I2C_INTENCLR_MSTARBLOSSCLR_MASK (0x10U) #define I2C_INTENCLR_MSTARBLOSSCLR_SHIFT (4U) /*! MSTARBLOSSCLR - Master Arbitration Loss interrupt clear. */ #define I2C_INTENCLR_MSTARBLOSSCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MSTARBLOSSCLR_SHIFT)) & I2C_INTENCLR_MSTARBLOSSCLR_MASK) #define I2C_INTENCLR_MSTSTSTPERRCLR_MASK (0x40U) #define I2C_INTENCLR_MSTSTSTPERRCLR_SHIFT (6U) /*! MSTSTSTPERRCLR - Master Start/Stop Error interrupt clear. */ #define I2C_INTENCLR_MSTSTSTPERRCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MSTSTSTPERRCLR_SHIFT)) & I2C_INTENCLR_MSTSTSTPERRCLR_MASK) #define I2C_INTENCLR_SLVPENDINGCLR_MASK (0x100U) #define I2C_INTENCLR_SLVPENDINGCLR_SHIFT (8U) /*! SLVPENDINGCLR - Slave Pending interrupt clear. */ #define I2C_INTENCLR_SLVPENDINGCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_SLVPENDINGCLR_SHIFT)) & I2C_INTENCLR_SLVPENDINGCLR_MASK) #define I2C_INTENCLR_SLVNOTSTRCLR_MASK (0x800U) #define I2C_INTENCLR_SLVNOTSTRCLR_SHIFT (11U) /*! SLVNOTSTRCLR - Slave Not Stretching interrupt clear. */ #define I2C_INTENCLR_SLVNOTSTRCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_SLVNOTSTRCLR_SHIFT)) & I2C_INTENCLR_SLVNOTSTRCLR_MASK) #define I2C_INTENCLR_SLVDESELCLR_MASK (0x8000U) #define I2C_INTENCLR_SLVDESELCLR_SHIFT (15U) /*! SLVDESELCLR - Slave Deselect interrupt clear. */ #define I2C_INTENCLR_SLVDESELCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_SLVDESELCLR_SHIFT)) & I2C_INTENCLR_SLVDESELCLR_MASK) #define I2C_INTENCLR_MONRDYCLR_MASK (0x10000U) #define I2C_INTENCLR_MONRDYCLR_SHIFT (16U) /*! MONRDYCLR - Monitor data Ready interrupt clear. */ #define I2C_INTENCLR_MONRDYCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MONRDYCLR_SHIFT)) & I2C_INTENCLR_MONRDYCLR_MASK) #define I2C_INTENCLR_MONOVCLR_MASK (0x20000U) #define I2C_INTENCLR_MONOVCLR_SHIFT (17U) /*! MONOVCLR - Monitor Overrun interrupt clear. */ #define I2C_INTENCLR_MONOVCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MONOVCLR_SHIFT)) & I2C_INTENCLR_MONOVCLR_MASK) #define I2C_INTENCLR_MONIDLECLR_MASK (0x80000U) #define I2C_INTENCLR_MONIDLECLR_SHIFT (19U) /*! MONIDLECLR - Monitor Idle interrupt clear. */ #define I2C_INTENCLR_MONIDLECLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_MONIDLECLR_SHIFT)) & I2C_INTENCLR_MONIDLECLR_MASK) #define I2C_INTENCLR_EVENTTIMEOUTCLR_MASK (0x1000000U) #define I2C_INTENCLR_EVENTTIMEOUTCLR_SHIFT (24U) /*! EVENTTIMEOUTCLR - Event time-out interrupt clear. */ #define I2C_INTENCLR_EVENTTIMEOUTCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_EVENTTIMEOUTCLR_SHIFT)) & I2C_INTENCLR_EVENTTIMEOUTCLR_MASK) #define I2C_INTENCLR_SCLTIMEOUTCLR_MASK (0x2000000U) #define I2C_INTENCLR_SCLTIMEOUTCLR_SHIFT (25U) /*! SCLTIMEOUTCLR - SCL time-out interrupt clear. */ #define I2C_INTENCLR_SCLTIMEOUTCLR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTENCLR_SCLTIMEOUTCLR_SHIFT)) & I2C_INTENCLR_SCLTIMEOUTCLR_MASK) /*! @} */ /*! @name TIMEOUT - Time-out value register. */ /*! @{ */ #define I2C_TIMEOUT_TOMIN_MASK (0xFU) #define I2C_TIMEOUT_TOMIN_SHIFT (0U) /*! TOMIN - Time-out time value, bottom four bits. These are hard-wired to 0xF. This gives a minimum * time-out of 16 I2C function clocks and also a time-out resolution of 16 I2C function clocks. */ #define I2C_TIMEOUT_TOMIN(x) (((uint32_t)(((uint32_t)(x)) << I2C_TIMEOUT_TOMIN_SHIFT)) & I2C_TIMEOUT_TOMIN_MASK) #define I2C_TIMEOUT_TO_MASK (0xFFF0U) #define I2C_TIMEOUT_TO_SHIFT (4U) /*! TO - Time-out time value. Specifies the time-out interval value in increments of 16 I 2C * function clocks, as defined by the CLKDIV register. To change this value while I2C is in operation, * disable all time-outs, write a new value to TIMEOUT, then re-enable time-outs. 0x000 = A * time-out will occur after 16 counts of the I2C function clock. 0x001 = A time-out will occur after * 32 counts of the I2C function clock. 0xFFF = A time-out will occur after 65,536 counts of the * I2C function clock. */ #define I2C_TIMEOUT_TO(x) (((uint32_t)(((uint32_t)(x)) << I2C_TIMEOUT_TO_SHIFT)) & I2C_TIMEOUT_TO_MASK) /*! @} */ /*! @name CLKDIV - Clock pre-divider for the entire I2C interface. This determines what time increments are used for the MSTTIME register, and controls some timing of the Slave function. */ /*! @{ */ #define I2C_CLKDIV_DIVVAL_MASK (0xFFFFU) #define I2C_CLKDIV_DIVVAL_SHIFT (0U) /*! DIVVAL - This field controls how the Flexcomm clock (FCLK) is used by the I2C functions that * need an internal clock in order to operate. 0x0000 = FCLK is used directly by the I2C. 0x0001 = * FCLK is divided by 2 before use. 0x0002 = FCLK is divided by 3 before use. 0xFFFF = FCLK is * divided by 65,536 before use. */ #define I2C_CLKDIV_DIVVAL(x) (((uint32_t)(((uint32_t)(x)) << I2C_CLKDIV_DIVVAL_SHIFT)) & I2C_CLKDIV_DIVVAL_MASK) /*! @} */ /*! @name INTSTAT - Interrupt Status register for Master, Slave, and Monitor functions. */ /*! @{ */ #define I2C_INTSTAT_MSTPENDING_MASK (0x1U) #define I2C_INTSTAT_MSTPENDING_SHIFT (0U) /*! MSTPENDING - Master Pending. */ #define I2C_INTSTAT_MSTPENDING(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MSTPENDING_SHIFT)) & I2C_INTSTAT_MSTPENDING_MASK) #define I2C_INTSTAT_MSTARBLOSS_MASK (0x10U) #define I2C_INTSTAT_MSTARBLOSS_SHIFT (4U) /*! MSTARBLOSS - Master Arbitration Loss flag. */ #define I2C_INTSTAT_MSTARBLOSS(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MSTARBLOSS_SHIFT)) & I2C_INTSTAT_MSTARBLOSS_MASK) #define I2C_INTSTAT_MSTSTSTPERR_MASK (0x40U) #define I2C_INTSTAT_MSTSTSTPERR_SHIFT (6U) /*! MSTSTSTPERR - Master Start/Stop Error flag. */ #define I2C_INTSTAT_MSTSTSTPERR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MSTSTSTPERR_SHIFT)) & I2C_INTSTAT_MSTSTSTPERR_MASK) #define I2C_INTSTAT_SLVPENDING_MASK (0x100U) #define I2C_INTSTAT_SLVPENDING_SHIFT (8U) /*! SLVPENDING - Slave Pending. */ #define I2C_INTSTAT_SLVPENDING(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_SLVPENDING_SHIFT)) & I2C_INTSTAT_SLVPENDING_MASK) #define I2C_INTSTAT_SLVNOTSTR_MASK (0x800U) #define I2C_INTSTAT_SLVNOTSTR_SHIFT (11U) /*! SLVNOTSTR - Slave Not Stretching status. */ #define I2C_INTSTAT_SLVNOTSTR(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_SLVNOTSTR_SHIFT)) & I2C_INTSTAT_SLVNOTSTR_MASK) #define I2C_INTSTAT_SLVDESEL_MASK (0x8000U) #define I2C_INTSTAT_SLVDESEL_SHIFT (15U) /*! SLVDESEL - Slave Deselected flag. */ #define I2C_INTSTAT_SLVDESEL(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_SLVDESEL_SHIFT)) & I2C_INTSTAT_SLVDESEL_MASK) #define I2C_INTSTAT_MONRDY_MASK (0x10000U) #define I2C_INTSTAT_MONRDY_SHIFT (16U) /*! MONRDY - Monitor Ready. */ #define I2C_INTSTAT_MONRDY(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MONRDY_SHIFT)) & I2C_INTSTAT_MONRDY_MASK) #define I2C_INTSTAT_MONOV_MASK (0x20000U) #define I2C_INTSTAT_MONOV_SHIFT (17U) /*! MONOV - Monitor Overflow flag. */ #define I2C_INTSTAT_MONOV(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MONOV_SHIFT)) & I2C_INTSTAT_MONOV_MASK) #define I2C_INTSTAT_MONIDLE_MASK (0x80000U) #define I2C_INTSTAT_MONIDLE_SHIFT (19U) /*! MONIDLE - Monitor Idle flag. */ #define I2C_INTSTAT_MONIDLE(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_MONIDLE_SHIFT)) & I2C_INTSTAT_MONIDLE_MASK) #define I2C_INTSTAT_EVENTTIMEOUT_MASK (0x1000000U) #define I2C_INTSTAT_EVENTTIMEOUT_SHIFT (24U) /*! EVENTTIMEOUT - Event time-out Interrupt flag. */ #define I2C_INTSTAT_EVENTTIMEOUT(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_EVENTTIMEOUT_SHIFT)) & I2C_INTSTAT_EVENTTIMEOUT_MASK) #define I2C_INTSTAT_SCLTIMEOUT_MASK (0x2000000U) #define I2C_INTSTAT_SCLTIMEOUT_SHIFT (25U) /*! SCLTIMEOUT - SCL time-out Interrupt flag. */ #define I2C_INTSTAT_SCLTIMEOUT(x) (((uint32_t)(((uint32_t)(x)) << I2C_INTSTAT_SCLTIMEOUT_SHIFT)) & I2C_INTSTAT_SCLTIMEOUT_MASK) /*! @} */ /*! @name MSTCTL - Master control register. */ /*! @{ */ #define I2C_MSTCTL_MSTCONTINUE_MASK (0x1U) #define I2C_MSTCTL_MSTCONTINUE_SHIFT (0U) /*! MSTCONTINUE - Master Continue. * 0b0..No effect. * 0b1..Informs the Master function to continue to the next operation. */ #define I2C_MSTCTL_MSTCONTINUE(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTCTL_MSTCONTINUE_SHIFT)) & I2C_MSTCTL_MSTCONTINUE_MASK) #define I2C_MSTCTL_MSTSTART_MASK (0x2U) #define I2C_MSTCTL_MSTSTART_SHIFT (1U) /*! MSTSTART - Master Start control. * 0b0..No effect. * 0b1..Start. A Start will be generated on the I2C bus at the next allowed time. */ #define I2C_MSTCTL_MSTSTART(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTCTL_MSTSTART_SHIFT)) & I2C_MSTCTL_MSTSTART_MASK) #define I2C_MSTCTL_MSTSTOP_MASK (0x4U) #define I2C_MSTCTL_MSTSTOP_SHIFT (2U) /*! MSTSTOP - Master Stop control. * 0b0..No effect. * 0b1..Stop. A Stop will be generated on the I2C bus at the next allowed time, preceded by a NACK to the slave * if the master is receiving data from the slave (Master Receiver mode). */ #define I2C_MSTCTL_MSTSTOP(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTCTL_MSTSTOP_SHIFT)) & I2C_MSTCTL_MSTSTOP_MASK) #define I2C_MSTCTL_MSTDMA_MASK (0x8U) #define I2C_MSTCTL_MSTDMA_SHIFT (3U) /*! MSTDMA - Master DMA enable. Data operations of the I2C can be performed with DMA. Protocol type * operations such as Start, address, Stop, and address match must always be done with software, * typically via an interrupt. Address acknowledgement must also be done by software except when * the I2C is configured to be HSCAPABLE (and address acknowledgement is handled entirely by * hardware) or when Automatic Operation is enabled. When a DMA data transfer is complete, MSTDMA * must be cleared prior to beginning the next operation, typically a Start or Stop.This bit is * read/write. * 0b0..Disable. No DMA requests are generated for master operation. * 0b1..Enable. A DMA request is generated for I2C master data operations. When this I2C master is generating * Acknowledge bits in Master Receiver mode, the acknowledge is generated automatically. */ #define I2C_MSTCTL_MSTDMA(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTCTL_MSTDMA_SHIFT)) & I2C_MSTCTL_MSTDMA_MASK) /*! @} */ /*! @name MSTTIME - Master timing configuration. */ /*! @{ */ #define I2C_MSTTIME_MSTSCLLOW_MASK (0x7U) #define I2C_MSTTIME_MSTSCLLOW_SHIFT (0U) /*! MSTSCLLOW - Master SCL Low time. Specifies the minimum low time that will be asserted by this * master on SCL. Other devices on the bus (masters or slaves) could lengthen this time. This * corresponds to the parameter t LOW in the I2C bus specification. I2C bus specification parameters * tBUF and tSU;STA have the same values and are also controlled by MSTSCLLOW. * 0b000..2 clocks. Minimum SCL low time is 2 clocks of the I2C clock pre-divider. * 0b001..3 clocks. Minimum SCL low time is 3 clocks of the I2C clock pre-divider. * 0b010..4 clocks. Minimum SCL low time is 4 clocks of the I2C clock pre-divider. * 0b011..5 clocks. Minimum SCL low time is 5 clocks of the I2C clock pre-divider. * 0b100..6 clocks. Minimum SCL low time is 6 clocks of the I2C clock pre-divider. * 0b101..7 clocks. Minimum SCL low time is 7 clocks of the I2C clock pre-divider. * 0b110..8 clocks. Minimum SCL low time is 8 clocks of the I2C clock pre-divider. * 0b111..9 clocks. Minimum SCL low time is 9 clocks of the I2C clock pre-divider. */ #define I2C_MSTTIME_MSTSCLLOW(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTTIME_MSTSCLLOW_SHIFT)) & I2C_MSTTIME_MSTSCLLOW_MASK) #define I2C_MSTTIME_MSTSCLHIGH_MASK (0x70U) #define I2C_MSTTIME_MSTSCLHIGH_SHIFT (4U) /*! MSTSCLHIGH - Master SCL High time. Specifies the minimum high time that will be asserted by this * master on SCL. Other masters in a multi-master system could shorten this time. This * corresponds to the parameter tHIGH in the I2C bus specification. I2C bus specification parameters * tSU;STO and tHD;STA have the same values and are also controlled by MSTSCLHIGH. * 0b000..2 clocks. Minimum SCL high time is 2 clock of the I2C clock pre-divider. * 0b001..3 clocks. Minimum SCL high time is 3 clocks of the I2C clock pre-divider . * 0b010..4 clocks. Minimum SCL high time is 4 clock of the I2C clock pre-divider. * 0b011..5 clocks. Minimum SCL high time is 5 clock of the I2C clock pre-divider. * 0b100..6 clocks. Minimum SCL high time is 6 clock of the I2C clock pre-divider. * 0b101..7 clocks. Minimum SCL high time is 7 clock of the I2C clock pre-divider. * 0b110..8 clocks. Minimum SCL high time is 8 clock of the I2C clock pre-divider. * 0b111..9 clocks. Minimum SCL high time is 9 clocks of the I2C clock pre-divider. */ #define I2C_MSTTIME_MSTSCLHIGH(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTTIME_MSTSCLHIGH_SHIFT)) & I2C_MSTTIME_MSTSCLHIGH_MASK) /*! @} */ /*! @name MSTDAT - Combined Master receiver and transmitter data register. */ /*! @{ */ #define I2C_MSTDAT_DATA_MASK (0xFFU) #define I2C_MSTDAT_DATA_SHIFT (0U) /*! DATA - Master function data register. Read: read the most recently received data for the Master * function. Write: transmit data using the Master function. */ #define I2C_MSTDAT_DATA(x) (((uint32_t)(((uint32_t)(x)) << I2C_MSTDAT_DATA_SHIFT)) & I2C_MSTDAT_DATA_MASK) /*! @} */ /*! @name SLVCTL - Slave control register. */ /*! @{ */ #define I2C_SLVCTL_SLVCONTINUE_MASK (0x1U) #define I2C_SLVCTL_SLVCONTINUE_SHIFT (0U) /*! SLVCONTINUE - Slave Continue. * 0b0..No effect. * 0b1..Informs the Slave function to continue to the next operation. */ #define I2C_SLVCTL_SLVCONTINUE(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVCTL_SLVCONTINUE_SHIFT)) & I2C_SLVCTL_SLVCONTINUE_MASK) #define I2C_SLVCTL_SLVNACK_MASK (0x2U) #define I2C_SLVCTL_SLVNACK_SHIFT (1U) /*! SLVNACK - Slave NACK. * 0b0..No effect. * 0b1..NACK. Causes the Slave function to NACK the master when the slave is receiving data from the master (Slave Receiver mode). */ #define I2C_SLVCTL_SLVNACK(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVCTL_SLVNACK_SHIFT)) & I2C_SLVCTL_SLVNACK_MASK) #define I2C_SLVCTL_SLVDMA_MASK (0x8U) #define I2C_SLVCTL_SLVDMA_SHIFT (3U) /*! SLVDMA - Slave DMA enable. * 0b0..Disabled. No DMA requests are issued for Slave mode operation. * 0b1..Enabled. DMA requests are issued for I2C slave data transmission and reception. */ #define I2C_SLVCTL_SLVDMA(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVCTL_SLVDMA_SHIFT)) & I2C_SLVCTL_SLVDMA_MASK) /*! @} */ /*! @name SLVDAT - Combined Slave receiver and transmitter data register. */ /*! @{ */ #define I2C_SLVDAT_DATA_MASK (0xFFU) #define I2C_SLVDAT_DATA_SHIFT (0U) /*! DATA - Slave function data register. Read: read the most recently received data for the Slave * function. Write: transmit data using the Slave function. */ #define I2C_SLVDAT_DATA(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVDAT_DATA_SHIFT)) & I2C_SLVDAT_DATA_MASK) /*! @} */ /*! @name SLVADR - Slave address register. */ /*! @{ */ #define I2C_SLVADR_SADISABLE_MASK (0x1U) #define I2C_SLVADR_SADISABLE_SHIFT (0U) /*! SADISABLE - Slave Address n Disable. * 0b0..Enabled. Slave Address n is enabled. * 0b1..Ignored Slave Address n is ignored. */ #define I2C_SLVADR_SADISABLE(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVADR_SADISABLE_SHIFT)) & I2C_SLVADR_SADISABLE_MASK) #define I2C_SLVADR_SLVADR_MASK (0xFEU) #define I2C_SLVADR_SLVADR_SHIFT (1U) /*! SLVADR - Slave Address. Seven bit slave address that is compared to received addresses if enabled. */ #define I2C_SLVADR_SLVADR(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVADR_SLVADR_SHIFT)) & I2C_SLVADR_SLVADR_MASK) /*! @} */ /* The count of I2C_SLVADR */ #define I2C_SLVADR_COUNT (4U) /*! @name SLVQUAL0 - Slave Qualification for address 0. */ /*! @{ */ #define I2C_SLVQUAL0_QUALMODE0_MASK (0x1U) #define I2C_SLVQUAL0_QUALMODE0_SHIFT (0U) /*! QUALMODE0 - Qualify mode for slave address 0. * 0b0..Mask. The SLVQUAL0 field is used as a logical mask for matching address 0. * 0b1..Extend. The SLVQUAL0 field is used to extend address 0 matching in a range of addresses. */ #define I2C_SLVQUAL0_QUALMODE0(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVQUAL0_QUALMODE0_SHIFT)) & I2C_SLVQUAL0_QUALMODE0_MASK) #define I2C_SLVQUAL0_SLVQUAL0_MASK (0xFEU) #define I2C_SLVQUAL0_SLVQUAL0_SHIFT (1U) /*! SLVQUAL0 - Slave address Qualifier for address 0. A value of 0 causes the address in SLVADR0 to * be used as-is, assuming that it is enabled. If QUALMODE0 = 0, any bit in this field which is * set to 1 will cause an automatic match of the corresponding bit of the received address when it * is compared to the SLVADR0 register. If QUALMODE0 = 1, an address range is matched for * address 0. This range extends from the value defined by SLVADR0 to the address defined by SLVQUAL0 * (address matches when SLVADR0[7:1] <= received address <= SLVQUAL0[7:1]). */ #define I2C_SLVQUAL0_SLVQUAL0(x) (((uint32_t)(((uint32_t)(x)) << I2C_SLVQUAL0_SLVQUAL0_SHIFT)) & I2C_SLVQUAL0_SLVQUAL0_MASK) /*! @} */ /*! @name MONRXDAT - Monitor receiver data register. */ /*! @{ */ #define I2C_MONRXDAT_MONRXDAT_MASK (0xFFU) #define I2C_MONRXDAT_MONRXDAT_SHIFT (0U) /*! MONRXDAT - Monitor function Receiver Data. This reflects every data byte that passes on the I2C pins. */ #define I2C_MONRXDAT_MONRXDAT(x) (((uint32_t)(((uint32_t)(x)) << I2C_MONRXDAT_MONRXDAT_SHIFT)) & I2C_MONRXDAT_MONRXDAT_MASK) #define I2C_MONRXDAT_MONSTART_MASK (0x100U) #define I2C_MONRXDAT_MONSTART_SHIFT (8U) /*! MONSTART - Monitor Received Start. * 0b0..No start detected. The Monitor function has not detected a Start event on the I2C bus. * 0b1..Start detected. The Monitor function has detected a Start event on the I2C bus. */ #define I2C_MONRXDAT_MONSTART(x) (((uint32_t)(((uint32_t)(x)) << I2C_MONRXDAT_MONSTART_SHIFT)) & I2C_MONRXDAT_MONSTART_MASK) #define I2C_MONRXDAT_MONRESTART_MASK (0x200U) #define I2C_MONRXDAT_MONRESTART_SHIFT (9U) /*! MONRESTART - Monitor Received Repeated Start. * 0b0..No repeated start detected. The Monitor function has not detected a Repeated Start event on the I2C bus. * 0b1..Repeated start detected. The Monitor function has detected a Repeated Start event on the I2C bus. */ #define I2C_MONRXDAT_MONRESTART(x) (((uint32_t)(((uint32_t)(x)) << I2C_MONRXDAT_MONRESTART_SHIFT)) & I2C_MONRXDAT_MONRESTART_MASK) #define I2C_MONRXDAT_MONNACK_MASK (0x400U) #define I2C_MONRXDAT_MONNACK_SHIFT (10U) /*! MONNACK - Monitor Received NACK. * 0b0..Acknowledged. The data currently being provided by the Monitor function was acknowledged by at least one master or slave receiver. * 0b1..Not acknowledged. The data currently being provided by the Monitor function was not acknowledged by any receiver. */ #define I2C_MONRXDAT_MONNACK(x) (((uint32_t)(((uint32_t)(x)) << I2C_MONRXDAT_MONNACK_SHIFT)) & I2C_MONRXDAT_MONNACK_MASK) /*! @} */ /*! * @} */ /* end of group I2C_Register_Masks */ /* I2C - Peripheral instance base addresses */ /** Peripheral I2C0 base address */ #define I2C0_BASE (0x40050000u) /** Peripheral I2C0 base pointer */ #define I2C0 ((I2C_Type *)I2C0_BASE) /** Array initializer of I2C peripheral base addresses */ #define I2C_BASE_ADDRS { I2C0_BASE } /** Array initializer of I2C peripheral base pointers */ #define I2C_BASE_PTRS { I2C0 } /** Interrupt vectors for the I2C peripheral type */ #define I2C_IRQS { I2C0_IRQn } /*! * @} */ /* end of group I2C_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- INPUTMUX Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup INPUTMUX_Peripheral_Access_Layer INPUTMUX Peripheral Access Layer * @{ */ /** INPUTMUX - Register Layout Typedef */ typedef struct { __IO uint32_t DMA_ITRIG_INMUX[18]; /**< Trigger select register for DMA channel, array offset: 0x0, array step: 0x4 */ uint8_t RESERVED_0[16312]; __IO uint32_t DMA_INMUX_INMUX[2]; /**< DMA output trigger selection to become DMA trigger 7 and DMA trigger 8, array offset: 0x4000, array step: 0x4 */ uint8_t RESERVED_1[24]; __IO uint32_t SCT0_INMUX[4]; /**< input select register for SCT, array offset: 0x4020, array step: 0x4 */ } INPUTMUX_Type; /* ---------------------------------------------------------------------------- -- INPUTMUX Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup INPUTMUX_Register_Masks INPUTMUX Register Masks * @{ */ /*! @name DMA_ITRIG_INMUX - Trigger select register for DMA channel */ /*! @{ */ #define INPUTMUX_DMA_ITRIG_INMUX_INP_MASK (0xFU) #define INPUTMUX_DMA_ITRIG_INMUX_INP_SHIFT (0U) /*! INP - Input mux register for trigger inputs 0 to 23 connected to DMA channel 0. Selects from * ADC, SCT, ACMP, pin interrupts, and DMA requests. * 0b0000..ADC_SEQA_IRQ * 0b0001..ADC_SEQB_IRQ * 0b0010..SCT_DMA0 * 0b0011..SCT_DMA1 * 0b0100..ACMP_O * 0b0101..PININT0 * 0b0110..PININT1 * 0b0111..DMA trigger mux 0 * 0b1000..DMA trigger mux 1 * 0b1001-0b1111..None */ #define INPUTMUX_DMA_ITRIG_INMUX_INP(x) (((uint32_t)(((uint32_t)(x)) << INPUTMUX_DMA_ITRIG_INMUX_INP_SHIFT)) & INPUTMUX_DMA_ITRIG_INMUX_INP_MASK) /*! @} */ /* The count of INPUTMUX_DMA_ITRIG_INMUX */ #define INPUTMUX_DMA_ITRIG_INMUX_COUNT (18U) /*! @name DMA_INMUX_INMUX - DMA output trigger selection to become DMA trigger 7 and DMA trigger 8 */ /*! @{ */ #define INPUTMUX_DMA_INMUX_INMUX_INP_MASK (0x1FU) #define INPUTMUX_DMA_INMUX_INMUX_INP_SHIFT (0U) /*! INP - DMA trigger output number (decimal value) for DMA channel n (n = 0 to 17). */ #define INPUTMUX_DMA_INMUX_INMUX_INP(x) (((uint32_t)(((uint32_t)(x)) << INPUTMUX_DMA_INMUX_INMUX_INP_SHIFT)) & INPUTMUX_DMA_INMUX_INMUX_INP_MASK) /*! @} */ /* The count of INPUTMUX_DMA_INMUX_INMUX */ #define INPUTMUX_DMA_INMUX_INMUX_COUNT (2U) /*! @name SCT0_INMUX - input select register for SCT */ /*! @{ */ #define INPUTMUX_SCT0_INMUX_INP_N_MASK (0xFU) #define INPUTMUX_SCT0_INMUX_INP_N_SHIFT (0U) /*! INP_N - Input mux register for SCT input n (n = 0 to 3). 0 = sct input 0 1=sct input 1 2= sct * input 2 3= sct input 3 4= adc_thcmp_irq 5 = comparator out 6=arm_txev 7=debug_halted * 0b0000..SCT_PIN0 * 0b0001..SCT_PIN1 * 0b0010..SCT_PIN2 * 0b0011..SCT_PIN3 * 0b0100..ADC_THCMP_IRQ * 0b0101..ACMP_O * 0b0110..ARM_TXEV * 0b0111..DEBUG_HALTED * 0b1000-0b1111..None */ #define INPUTMUX_SCT0_INMUX_INP_N(x) (((uint32_t)(((uint32_t)(x)) << INPUTMUX_SCT0_INMUX_INP_N_SHIFT)) & INPUTMUX_SCT0_INMUX_INP_N_MASK) /*! @} */ /* The count of INPUTMUX_SCT0_INMUX */ #define INPUTMUX_SCT0_INMUX_COUNT (4U) /*! * @} */ /* end of group INPUTMUX_Register_Masks */ /* INPUTMUX - Peripheral instance base addresses */ /** Peripheral INPUTMUX base address */ #define INPUTMUX_BASE (0x40028000u) /** Peripheral INPUTMUX base pointer */ #define INPUTMUX ((INPUTMUX_Type *)INPUTMUX_BASE) /** Array initializer of INPUTMUX peripheral base addresses */ #define INPUTMUX_BASE_ADDRS { INPUTMUX_BASE } /** Array initializer of INPUTMUX peripheral base pointers */ #define INPUTMUX_BASE_PTRS { INPUTMUX } /*! * @} */ /* end of group INPUTMUX_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- IOCON Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup IOCON_Peripheral_Access_Layer IOCON Peripheral Access Layer * @{ */ /** IOCON - Register Layout Typedef */ typedef struct { __IO uint32_t PIO[31]; /**< Digital I/O control for pins PIO0_17..Digital I/O control for pins PIO0_18, array offset: 0x0, array step: 0x4 */ } IOCON_Type; /* ---------------------------------------------------------------------------- -- IOCON Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup IOCON_Register_Masks IOCON Register Masks * @{ */ /*! @name PIO - Digital I/O control for pins PIO0_17..Digital I/O control for pins PIO0_18 */ /*! @{ */ #define IOCON_PIO_MODE_MASK (0x18U) #define IOCON_PIO_MODE_SHIFT (3U) /*! MODE - Selects function mode (on-chip pull-up/pull-down resistor control). * 0b00..Inactive. Inactive (no pull-down/pull-up resistor enabled). * 0b01..Pull-down. Pull-down resistor enabled. * 0b10..Pull-up. Pull-up resistor enabled. * 0b11..Repeater. Repeater mode. */ #define IOCON_PIO_MODE(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_MODE_SHIFT)) & IOCON_PIO_MODE_MASK) #define IOCON_PIO_HYS_MASK (0x20U) #define IOCON_PIO_HYS_SHIFT (5U) /*! HYS - Hysteresis. * 0b0..Disable * 0b1..Enable */ #define IOCON_PIO_HYS(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_HYS_SHIFT)) & IOCON_PIO_HYS_MASK) #define IOCON_PIO_INV_MASK (0x40U) #define IOCON_PIO_INV_SHIFT (6U) /*! INV - Invert input * 0b0..Input not inverted (HIGH on pin reads as 1; LOW on pin reads as 0). * 0b1..Input inverted (HIGH on pin reads as 0, LOW on pin reads as 1). */ #define IOCON_PIO_INV(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_INV_SHIFT)) & IOCON_PIO_INV_MASK) #define IOCON_PIO_I2CMODE_MASK (0x300U) #define IOCON_PIO_I2CMODE_SHIFT (8U) /*! I2CMODE - Selects I2C mode. * 0b00..Standard mode/ Fast-mode I2C. * 0b01..Standard GPIO functionality. Requires external pull-up for GPIO output function. * 0b10..Fast-mode Plus I2C * 0b11..Reserved */ #define IOCON_PIO_I2CMODE(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_I2CMODE_SHIFT)) & IOCON_PIO_I2CMODE_MASK) #define IOCON_PIO_OD_MASK (0x400U) #define IOCON_PIO_OD_SHIFT (10U) /*! OD - Open-drain mode. * 0b0..Disable. * 0b1..Open-drain mode enabled. Remark: This is not a true open-drain mode. */ #define IOCON_PIO_OD(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_OD_SHIFT)) & IOCON_PIO_OD_MASK) #define IOCON_PIO_S_MODE_MASK (0x1800U) #define IOCON_PIO_S_MODE_SHIFT (11U) /*! S_MODE - Digital filter sample mode. * 0b00..Bypass input filter. * 0b01..1 clock cycle. Input pulses shorter than one filter clock are rejected. * 0b10..2 clock cycles. Input pulses shorter than two filter clocks are rejected. * 0b11..3 clock cycles. Input pulses shorter than three filter clocks are rejected. */ #define IOCON_PIO_S_MODE(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_S_MODE_SHIFT)) & IOCON_PIO_S_MODE_MASK) #define IOCON_PIO_CLK_DIV_MASK (0xE000U) #define IOCON_PIO_CLK_DIV_SHIFT (13U) /*! CLK_DIV - Select peripheral clock divider for input filter sampling clock. Value 0x7 is reserved. * 0b000..IOCONCLKDIV0 * 0b001..IOCONCLKDIV1 * 0b010..IOCONCLKDIV2 * 0b011..IOCONCLKDIV3 * 0b100..IOCONCLKDIV4 * 0b101..IOCONCLKDIV5 * 0b110..IOCONCLKDIV6 */ #define IOCON_PIO_CLK_DIV(x) (((uint32_t)(((uint32_t)(x)) << IOCON_PIO_CLK_DIV_SHIFT)) & IOCON_PIO_CLK_DIV_MASK) /*! @} */ /* The count of IOCON_PIO */ #define IOCON_PIO_COUNT (31U) /*! * @} */ /* end of group IOCON_Register_Masks */ /* IOCON - Peripheral instance base addresses */ /** Peripheral IOCON base address */ #define IOCON_BASE (0x40044000u) /** Peripheral IOCON base pointer */ #define IOCON ((IOCON_Type *)IOCON_BASE) /** Array initializer of IOCON peripheral base addresses */ #define IOCON_BASE_ADDRS { IOCON_BASE } /** Array initializer of IOCON peripheral base pointers */ #define IOCON_BASE_PTRS { IOCON } #define IOCON_INDEX_PIO0_17 (0 ) #define IOCON_INDEX_PIO0_13 (1 ) #define IOCON_INDEX_PIO0_12 (2 ) #define IOCON_INDEX_PIO0_5 (3 ) #define IOCON_INDEX_PIO0_4 (4 ) #define IOCON_INDEX_PIO0_3 (5 ) #define IOCON_INDEX_PIO0_2 (6 ) #define IOCON_INDEX_PIO0_11 (7 ) #define IOCON_INDEX_PIO0_10 (8 ) #define IOCON_INDEX_PIO0_16 (9 ) #define IOCON_INDEX_PIO0_15 (10) #define IOCON_INDEX_PIO0_1 (11) #define IOCON_INDEX_PIO0_9 (13) #define IOCON_INDEX_PIO0_8 (14) #define IOCON_INDEX_PIO0_7 (15) #define IOCON_INDEX_PIO0_6 (16) #define IOCON_INDEX_PIO0_0 (17) #define IOCON_INDEX_PIO0_14 (18) #define IOCON_INDEX_PIO0_28 (20) #define IOCON_INDEX_PIO0_27 (21) #define IOCON_INDEX_PIO0_26 (22) #define IOCON_INDEX_PIO0_25 (23) #define IOCON_INDEX_PIO0_24 (24) #define IOCON_INDEX_PIO0_23 (25) #define IOCON_INDEX_PIO0_22 (26) #define IOCON_INDEX_PIO0_21 (27) #define IOCON_INDEX_PIO0_20 (28) #define IOCON_INDEX_PIO0_19 (29) #define IOCON_INDEX_PIO0_18 (30) /*! * @} */ /* end of group IOCON_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- MRT Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup MRT_Peripheral_Access_Layer MRT Peripheral Access Layer * @{ */ /** MRT - Register Layout Typedef */ typedef struct { struct { /* offset: 0x0, array step: 0x10 */ __IO uint32_t INTVAL; /**< MRT Time interval value register. This value is loaded into the TIMER register., array offset: 0x0, array step: 0x10 */ __I uint32_t TIMER; /**< MRT Timer register. This register reads the value of the down-counter., array offset: 0x4, array step: 0x10 */ __IO uint32_t CTRL; /**< MRT Control register. This register controls the MRT modes., array offset: 0x8, array step: 0x10 */ __IO uint32_t STAT; /**< MRT Status register., array offset: 0xC, array step: 0x10 */ } CHANNEL[4]; uint8_t RESERVED_0[176]; __I uint32_t MODCFG; /**< Module Configuration register. This register provides information about this particular MRT instance., offset: 0xF0 */ __I uint32_t IDLE_CH; /**< Idle channel register. This register returns the number of the first idle channel., offset: 0xF4 */ __IO uint32_t IRQ_FLAG; /**< Global interrupt flag register, offset: 0xF8 */ } MRT_Type; /* ---------------------------------------------------------------------------- -- MRT Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup MRT_Register_Masks MRT Register Masks * @{ */ /*! @name CHANNEL_INTVAL - MRT Time interval value register. This value is loaded into the TIMER register. */ /*! @{ */ #define MRT_CHANNEL_INTVAL_IVALUE_MASK (0x7FFFFFFFU) #define MRT_CHANNEL_INTVAL_IVALUE_SHIFT (0U) /*! IVALUE - Time interval load value. This value is loaded into the TIMERn register and the MRT * channel n starts counting down from IVALUE -1. If the timer is idle, writing a non-zero value to * this bit field starts the timer immediately. If the timer is running, writing a zero to this * bit field does the following: If LOAD = 1, the timer stops immediately. If LOAD = 0, the timer * stops at the end of the time interval. */ #define MRT_CHANNEL_INTVAL_IVALUE(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_INTVAL_IVALUE_SHIFT)) & MRT_CHANNEL_INTVAL_IVALUE_MASK) #define MRT_CHANNEL_INTVAL_LOAD_MASK (0x80000000U) #define MRT_CHANNEL_INTVAL_LOAD_SHIFT (31U) /*! LOAD - Determines how the timer interval value IVALUE -1 is loaded into the TIMERn register. * This bit is write-only. Reading this bit always returns 0. * 0b0..No force load. The load from the INTVALn register to the TIMERn register is processed at the end of the * time interval if the repeat mode is selected. * 0b1..Force load. The INTVALn interval value IVALUE -1 is immediately loaded into the TIMERn register while TIMERn is running. */ #define MRT_CHANNEL_INTVAL_LOAD(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_INTVAL_LOAD_SHIFT)) & MRT_CHANNEL_INTVAL_LOAD_MASK) /*! @} */ /* The count of MRT_CHANNEL_INTVAL */ #define MRT_CHANNEL_INTVAL_COUNT (4U) /*! @name CHANNEL_TIMER - MRT Timer register. This register reads the value of the down-counter. */ /*! @{ */ #define MRT_CHANNEL_TIMER_VALUE_MASK (0x7FFFFFFFU) #define MRT_CHANNEL_TIMER_VALUE_SHIFT (0U) /*! VALUE - Holds the current timer value of the down-counter. The initial value of the TIMERn * register is loaded as IVALUE - 1 from the INTVALn register either at the end of the time interval * or immediately in the following cases: INTVALn register is updated in the idle state. INTVALn * register is updated with LOAD = 1. When the timer is in idle state, reading this bit fields * returns -1 (0x00FF FFFF). */ #define MRT_CHANNEL_TIMER_VALUE(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_TIMER_VALUE_SHIFT)) & MRT_CHANNEL_TIMER_VALUE_MASK) /*! @} */ /* The count of MRT_CHANNEL_TIMER */ #define MRT_CHANNEL_TIMER_COUNT (4U) /*! @name CHANNEL_CTRL - MRT Control register. This register controls the MRT modes. */ /*! @{ */ #define MRT_CHANNEL_CTRL_INTEN_MASK (0x1U) #define MRT_CHANNEL_CTRL_INTEN_SHIFT (0U) /*! INTEN - Enable the TIMERn interrupt. * 0b0..Disabled. TIMERn interrupt is disabled. * 0b1..Enabled. TIMERn interrupt is enabled. */ #define MRT_CHANNEL_CTRL_INTEN(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_CTRL_INTEN_SHIFT)) & MRT_CHANNEL_CTRL_INTEN_MASK) #define MRT_CHANNEL_CTRL_MODE_MASK (0x6U) #define MRT_CHANNEL_CTRL_MODE_SHIFT (1U) /*! MODE - Selects timer mode. * 0b00..Repeat interrupt mode. * 0b01..One-shot interrupt mode. * 0b10..One-shot stall mode. * 0b11..Reserved. */ #define MRT_CHANNEL_CTRL_MODE(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_CTRL_MODE_SHIFT)) & MRT_CHANNEL_CTRL_MODE_MASK) /*! @} */ /* The count of MRT_CHANNEL_CTRL */ #define MRT_CHANNEL_CTRL_COUNT (4U) /*! @name CHANNEL_STAT - MRT Status register. */ /*! @{ */ #define MRT_CHANNEL_STAT_INTFLAG_MASK (0x1U) #define MRT_CHANNEL_STAT_INTFLAG_SHIFT (0U) /*! INTFLAG - Monitors the interrupt flag. * 0b0..No pending interrupt. Writing a zero is equivalent to no operation. * 0b1..Pending interrupt. The interrupt is pending because TIMERn has reached the end of the time interval. If * the INTEN bit in the CONTROLn is also set to 1, the interrupt for timer channel n and the global interrupt * are raised. Writing a 1 to this bit clears the interrupt request. */ #define MRT_CHANNEL_STAT_INTFLAG(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_STAT_INTFLAG_SHIFT)) & MRT_CHANNEL_STAT_INTFLAG_MASK) #define MRT_CHANNEL_STAT_RUN_MASK (0x2U) #define MRT_CHANNEL_STAT_RUN_SHIFT (1U) /*! RUN - Indicates the state of TIMERn. This bit is read-only. * 0b0..Idle state. TIMERn is stopped. * 0b1..Running. TIMERn is running. */ #define MRT_CHANNEL_STAT_RUN(x) (((uint32_t)(((uint32_t)(x)) << MRT_CHANNEL_STAT_RUN_SHIFT)) & MRT_CHANNEL_STAT_RUN_MASK) /*! @} */ /* The count of MRT_CHANNEL_STAT */ #define MRT_CHANNEL_STAT_COUNT (4U) /*! @name MODCFG - Module Configuration register. This register provides information about this particular MRT instance. */ /*! @{ */ #define MRT_MODCFG_NOC_MASK (0xFU) #define MRT_MODCFG_NOC_SHIFT (0U) /*! NOC - Identifies the number of channels in this MRT.(4 channels on this device.) */ #define MRT_MODCFG_NOC(x) (((uint32_t)(((uint32_t)(x)) << MRT_MODCFG_NOC_SHIFT)) & MRT_MODCFG_NOC_MASK) #define MRT_MODCFG_NOB_MASK (0x1F0U) #define MRT_MODCFG_NOB_SHIFT (4U) /*! NOB - Identifies the number of timer bits in this MRT. (31 bits wide on this device.) */ #define MRT_MODCFG_NOB(x) (((uint32_t)(((uint32_t)(x)) << MRT_MODCFG_NOB_SHIFT)) & MRT_MODCFG_NOB_MASK) /*! @} */ /*! @name IDLE_CH - Idle channel register. This register returns the number of the first idle channel. */ /*! @{ */ #define MRT_IDLE_CH_CHAN_MASK (0xF0U) #define MRT_IDLE_CH_CHAN_SHIFT (4U) /*! CHAN - Idle channel. Reading the CHAN bits, returns the lowest idle timer channel. The number is * positioned such that it can be used as an offset from the MRT base address in order to access * the registers for the allocated channel. If all timer channels are running, CHAN = 0xF. See * text above for more details. */ #define MRT_IDLE_CH_CHAN(x) (((uint32_t)(((uint32_t)(x)) << MRT_IDLE_CH_CHAN_SHIFT)) & MRT_IDLE_CH_CHAN_MASK) /*! @} */ /*! @name IRQ_FLAG - Global interrupt flag register */ /*! @{ */ #define MRT_IRQ_FLAG_GFLAG0_MASK (0x1U) #define MRT_IRQ_FLAG_GFLAG0_SHIFT (0U) /*! GFLAG0 - Monitors the interrupt flag of TIMER0. * 0b0..No pending interrupt. Writing a zero is equivalent to no operation. * 0b1..Pending interrupt. The interrupt is pending because TIMER0 has reached the end of the time interval. If * the INTEN bit in the CONTROL0 register is also set to 1, the interrupt for timer channel 0 and the global * interrupt are raised. Writing a 1 to this bit clears the interrupt request. */ #define MRT_IRQ_FLAG_GFLAG0(x) (((uint32_t)(((uint32_t)(x)) << MRT_IRQ_FLAG_GFLAG0_SHIFT)) & MRT_IRQ_FLAG_GFLAG0_MASK) #define MRT_IRQ_FLAG_GFLAG1_MASK (0x2U) #define MRT_IRQ_FLAG_GFLAG1_SHIFT (1U) /*! GFLAG1 - Monitors the interrupt flag of TIMER1. See description of channel 0. */ #define MRT_IRQ_FLAG_GFLAG1(x) (((uint32_t)(((uint32_t)(x)) << MRT_IRQ_FLAG_GFLAG1_SHIFT)) & MRT_IRQ_FLAG_GFLAG1_MASK) #define MRT_IRQ_FLAG_GFLAG2_MASK (0x4U) #define MRT_IRQ_FLAG_GFLAG2_SHIFT (2U) /*! GFLAG2 - Monitors the interrupt flag of TIMER2. See description of channel 0. */ #define MRT_IRQ_FLAG_GFLAG2(x) (((uint32_t)(((uint32_t)(x)) << MRT_IRQ_FLAG_GFLAG2_SHIFT)) & MRT_IRQ_FLAG_GFLAG2_MASK) #define MRT_IRQ_FLAG_GFLAG3_MASK (0x8U) #define MRT_IRQ_FLAG_GFLAG3_SHIFT (3U) /*! GFLAG3 - Monitors the interrupt flag of TIMER3. See description of channel 0. */ #define MRT_IRQ_FLAG_GFLAG3(x) (((uint32_t)(((uint32_t)(x)) << MRT_IRQ_FLAG_GFLAG3_SHIFT)) & MRT_IRQ_FLAG_GFLAG3_MASK) /*! @} */ /*! * @} */ /* end of group MRT_Register_Masks */ /* MRT - Peripheral instance base addresses */ /** Peripheral MRT0 base address */ #define MRT0_BASE (0x40004000u) /** Peripheral MRT0 base pointer */ #define MRT0 ((MRT_Type *)MRT0_BASE) /** Array initializer of MRT peripheral base addresses */ #define MRT_BASE_ADDRS { MRT0_BASE } /** Array initializer of MRT peripheral base pointers */ #define MRT_BASE_PTRS { MRT0 } /** Interrupt vectors for the MRT peripheral type */ #define MRT_IRQS { MRT0_IRQn } /*! * @} */ /* end of group MRT_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- MTB Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup MTB_Peripheral_Access_Layer MTB Peripheral Access Layer * @{ */ /** MTB - Register Layout Typedef */ typedef struct { __IO uint32_t POSITION; /**< POSITION Register, offset: 0x0 */ __IO uint32_t MASTER; /**< MASTER Register, offset: 0x4 */ __IO uint32_t FLOW; /**< FLOW Register, offset: 0x8 */ __I uint32_t BASE; /**< Indicates where the SRAM is located in the processor memory map. This register is provided to enable auto discovery of the MTB SRAM location, by a debug agent., offset: 0xC */ } MTB_Type; /* ---------------------------------------------------------------------------- -- MTB Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup MTB_Register_Masks MTB Register Masks * @{ */ /*! @name POSITION - POSITION Register */ /*! @{ */ #define MTB_POSITION_WRAP_MASK (0x4U) #define MTB_POSITION_WRAP_SHIFT (2U) /*! WRAP - This bit is set to 1 automatically when the POINTER value wraps as determined by the * MASTER.MASK field in the MASTER Trace Control Register. */ #define MTB_POSITION_WRAP(x) (((uint32_t)(((uint32_t)(x)) << MTB_POSITION_WRAP_SHIFT)) & MTB_POSITION_WRAP_MASK) #define MTB_POSITION_POINTER_MASK (0xFFFFFFF8U) #define MTB_POSITION_POINTER_SHIFT (3U) /*! POINTER - Trace packet location pointer. Because a packet consists of two words, the POINTER * field is the location of the first word of a packet. This field contains bits [31:3] of the * address, in the SRAM, where the next trace packet will be written. The field points to an unused * location and is automatically incremented. A debug agent can calculate the system address, on * the AHB-Lite bus, of the SRAM location pointed to by the POSITION register using the following * equation: system address = BASE + ((P + (2AWIDTH - (BASE MOD 2AWIDTH))) MOD 2AWIDTH). Where P = * POSITION AND 0xFFFF_FFF8. Where BASE is the BASE register value */ #define MTB_POSITION_POINTER(x) (((uint32_t)(((uint32_t)(x)) << MTB_POSITION_POINTER_SHIFT)) & MTB_POSITION_POINTER_MASK) /*! @} */ /*! @name MASTER - MASTER Register */ /*! @{ */ #define MTB_MASTER_MASK_MASK (0x1FU) #define MTB_MASTER_MASK_SHIFT (0U) /*! MASK - This value determines the maximum size of the trace buffer in SRAM. It specifies the * most-significant bit of the POSITION.POINTER field that can be updated by automatic increment. If * the trace tries to advance past this power of two, the POSITION.WRAP bit is set to 1, the * POSITION.POINTER[MASK:0] bits are set to zero, and the POSITION.POINTER[AWIDTH-4:MASK+1] bits * remain unchanged. This field causes the trace packet information to be stored in a circular buffer * of size 2(MASK+4) bytes, that can be positioned in memory at multiples of this size. Valid * values of this field are zero to AWIDTH-4. Values greater than the maximum have the same effect * as the maximum. */ #define MTB_MASTER_MASK(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_MASK_SHIFT)) & MTB_MASTER_MASK_MASK) #define MTB_MASTER_TSTARTEN_MASK (0x20U) #define MTB_MASTER_TSTARTEN_SHIFT (5U) /*! TSTARTEN - Trace start input enable. If this bit is 1 and the TSTART signal is HIGH, then the EN * bit is set to 1. Tracing continues until a stop condition occurs. */ #define MTB_MASTER_TSTARTEN(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_TSTARTEN_SHIFT)) & MTB_MASTER_TSTARTEN_MASK) #define MTB_MASTER_TSTOPEN_MASK (0x40U) #define MTB_MASTER_TSTOPEN_SHIFT (6U) /*! TSTOPEN - Trace stop input enable. If this bit is 1 and the TSTOP signal is HIGH, then the EN * bit is set to 0. If a trace packet is being written to memory, the write is completed before * tracing is stopped. */ #define MTB_MASTER_TSTOPEN(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_TSTOPEN_SHIFT)) & MTB_MASTER_TSTOPEN_MASK) #define MTB_MASTER_SFRWPRIV_MASK (0x80U) #define MTB_MASTER_SFRWPRIV_SHIFT (7U) /*! SFRWPRIV - Special Function Register Write Privilege bit. If this bit is 0, then User or * Privileged AHB-Lite read and write accesses to the Special Function Registers are permitted. If this * bit is 1, then only Privileged write accesses are permitted and User write accesses are * ignored. The HPROT[1] signal determines if an access is User or Privileged. */ #define MTB_MASTER_SFRWPRIV(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_SFRWPRIV_SHIFT)) & MTB_MASTER_SFRWPRIV_MASK) #define MTB_MASTER_RAMPRIV_MASK (0x100U) #define MTB_MASTER_RAMPRIV_SHIFT (8U) /*! RAMPRIV - SRAM Privilege bit. If this bit is 0, then User or Privileged AHB-Lite read and write * accesses to the SRAM are permitted. If this bit is 1, then only Privileged AHB-Lite read and * write accesses to the SRAM are permitted and User accesses are RAZ/WI. The HPROT[1] signal * determines if an access is User or Privileged. */ #define MTB_MASTER_RAMPRIV(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_RAMPRIV_SHIFT)) & MTB_MASTER_RAMPRIV_MASK) #define MTB_MASTER_HALTREQ_MASK (0x200U) #define MTB_MASTER_HALTREQ_SHIFT (9U) /*! HALTREQ - Halt request bit. This bit is connected to the halt request signal of the trace logic, * EDBGRQ. When HALTREQ is set to 1, EDBGRQ is asserted if DBGEN is also HIGH. The HALTREQ bit * can be automatically set to 1 using the FLOW.WATERMARK field. */ #define MTB_MASTER_HALTREQ(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_HALTREQ_SHIFT)) & MTB_MASTER_HALTREQ_MASK) #define MTB_MASTER_EN_MASK (0x80000000U) #define MTB_MASTER_EN_SHIFT (31U) /*! EN - Main trace enable bit. When this bit is 1 trace data is written into the SRAM memory * location addressed by POSITION.POINTER. The POSITION.POINTER value auto increments after the trace * data packet is written. The EN bit can be automatically set to 0 using the FLOW.WATERMARK field * and the FLOW.AUTOSTOP bit. The EN bit is automatically set to 1 if the TSTARTEN bit is 1 and * the TSTART signal is HIGH. The EN bit is automatically set to 0 if TSTOPEN bit is 1 and the * TSTOP signal is HIGH. */ #define MTB_MASTER_EN(x) (((uint32_t)(((uint32_t)(x)) << MTB_MASTER_EN_SHIFT)) & MTB_MASTER_EN_MASK) /*! @} */ /*! @name FLOW - FLOW Register */ /*! @{ */ #define MTB_FLOW_AUTOSTOP_MASK (0x1U) #define MTB_FLOW_AUTOSTOP_SHIFT (0U) /*! AUTOSTOP - If this bit is 1 and WATERMARK is equal to POSITION.POINTER, then the MASTER.EN bit * is automatically set to 0. This stops tracing. */ #define MTB_FLOW_AUTOSTOP(x) (((uint32_t)(((uint32_t)(x)) << MTB_FLOW_AUTOSTOP_SHIFT)) & MTB_FLOW_AUTOSTOP_MASK) #define MTB_FLOW_AUTOHALT_MASK (0x2U) #define MTB_FLOW_AUTOHALT_SHIFT (1U) /*! AUTOHALT - If this bit is 1 and WATERMARK is equal to POSITION.POINTER, then the MASTER.HALTREQ * bit is automatically set to 1. If the DBGEN signal is HIGH, the MTB asserts this halt request * to the Cortex-M0+ processor by asserting the EDBGRQ signal. */ #define MTB_FLOW_AUTOHALT(x) (((uint32_t)(((uint32_t)(x)) << MTB_FLOW_AUTOHALT_SHIFT)) & MTB_FLOW_AUTOHALT_MASK) #define MTB_FLOW_WATERMARK_MASK (0xFFFFFFF8U) #define MTB_FLOW_WATERMARK_SHIFT (3U) /*! WATERMARK - WATERMARK value. This field contains an address in the same format as the * POSITION.POINTER field. When the POSITION.POINTER matches the WATERMARK field value, actions defined by * the AUTOHALT and AUTOSTOP bits are performed. */ #define MTB_FLOW_WATERMARK(x) (((uint32_t)(((uint32_t)(x)) << MTB_FLOW_WATERMARK_SHIFT)) & MTB_FLOW_WATERMARK_MASK) /*! @} */ /*! @name BASE - Indicates where the SRAM is located in the processor memory map. This register is provided to enable auto discovery of the MTB SRAM location, by a debug agent. */ /*! @{ */ #define MTB_BASE_BASE_MASK (0xFFFFFFFFU) #define MTB_BASE_BASE_SHIFT (0U) /*! BASE - The value provided is the value of the SRAMBASEADDR[31:0] signal. */ #define MTB_BASE_BASE(x) (((uint32_t)(((uint32_t)(x)) << MTB_BASE_BASE_SHIFT)) & MTB_BASE_BASE_MASK) /*! @} */ /*! * @} */ /* end of group MTB_Register_Masks */ /* MTB - Peripheral instance base addresses */ /** Peripheral MTB_SFR base address */ #define MTB_SFR_BASE (0x14000000u) /** Peripheral MTB_SFR base pointer */ #define MTB_SFR ((MTB_Type *)MTB_SFR_BASE) /** Array initializer of MTB peripheral base addresses */ #define MTB_BASE_ADDRS { MTB_SFR_BASE } /** Array initializer of MTB peripheral base pointers */ #define MTB_BASE_PTRS { MTB_SFR } /*! * @} */ /* end of group MTB_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- PINT Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup PINT_Peripheral_Access_Layer PINT Peripheral Access Layer * @{ */ /** PINT - Register Layout Typedef */ typedef struct { __IO uint32_t ISEL; /**< Pin Interrupt Mode register, offset: 0x0 */ __IO uint32_t IENR; /**< Pin interrupt level or rising edge interrupt enable register, offset: 0x4 */ __O uint32_t SIENR; /**< Pin interrupt level or rising edge interrupt set register, offset: 0x8 */ __O uint32_t CIENR; /**< Pin interrupt level (rising edge interrupt) clear register, offset: 0xC */ __IO uint32_t IENF; /**< Pin interrupt active level or falling edge interrupt enable register, offset: 0x10 */ __O uint32_t SIENF; /**< Pin interrupt active level or falling edge interrupt set register, offset: 0x14 */ __O uint32_t CIENF; /**< Pin interrupt active level or falling edge interrupt clear register, offset: 0x18 */ __IO uint32_t RISE; /**< Pin interrupt rising edge register, offset: 0x1C */ __IO uint32_t FALL; /**< Pin interrupt falling edge register, offset: 0x20 */ __IO uint32_t IST; /**< Pin interrupt status register, offset: 0x24 */ __IO uint32_t PMCTRL; /**< Pattern match interrupt control register, offset: 0x28 */ __IO uint32_t PMSRC; /**< Pattern match interrupt bit-slice source register, offset: 0x2C */ __IO uint32_t PMCFG; /**< Pattern match interrupt bit slice configuration register, offset: 0x30 */ } PINT_Type; /* ---------------------------------------------------------------------------- -- PINT Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup PINT_Register_Masks PINT Register Masks * @{ */ /*! @name ISEL - Pin Interrupt Mode register */ /*! @{ */ #define PINT_ISEL_PMODE_MASK (0xFFU) #define PINT_ISEL_PMODE_SHIFT (0U) /*! PMODE - Selects the interrupt mode for each pin interrupt. Bit n configures the pin interrupt * selected in PINTSELn. 0 = Edge sensitive 1 = Level sensitive */ #define PINT_ISEL_PMODE(x) (((uint32_t)(((uint32_t)(x)) << PINT_ISEL_PMODE_SHIFT)) & PINT_ISEL_PMODE_MASK) /*! @} */ /*! @name IENR - Pin interrupt level or rising edge interrupt enable register */ /*! @{ */ #define PINT_IENR_ENRL_MASK (0xFFU) #define PINT_IENR_ENRL_SHIFT (0U) /*! ENRL - Enables the rising edge or level interrupt for each pin interrupt. Bit n configures the * pin interrupt selected in PINTSELn. 0 = Disable rising edge or level interrupt. 1 = Enable * rising edge or level interrupt. */ #define PINT_IENR_ENRL(x) (((uint32_t)(((uint32_t)(x)) << PINT_IENR_ENRL_SHIFT)) & PINT_IENR_ENRL_MASK) /*! @} */ /*! @name SIENR - Pin interrupt level or rising edge interrupt set register */ /*! @{ */ #define PINT_SIENR_SETENRL_MASK (0xFFU) #define PINT_SIENR_SETENRL_SHIFT (0U) /*! SETENRL - Ones written to this address set bits in the IENR, thus enabling interrupts. Bit n * sets bit n in the IENR register. 0 = No operation. 1 = Enable rising edge or level interrupt. */ #define PINT_SIENR_SETENRL(x) (((uint32_t)(((uint32_t)(x)) << PINT_SIENR_SETENRL_SHIFT)) & PINT_SIENR_SETENRL_MASK) /*! @} */ /*! @name CIENR - Pin interrupt level (rising edge interrupt) clear register */ /*! @{ */ #define PINT_CIENR_CENRL_MASK (0xFFU) #define PINT_CIENR_CENRL_SHIFT (0U) /*! CENRL - Ones written to this address clear bits in the IENR, thus disabling the interrupts. Bit * n clears bit n in the IENR register. 0 = No operation. 1 = Disable rising edge or level * interrupt. */ #define PINT_CIENR_CENRL(x) (((uint32_t)(((uint32_t)(x)) << PINT_CIENR_CENRL_SHIFT)) & PINT_CIENR_CENRL_MASK) /*! @} */ /*! @name IENF - Pin interrupt active level or falling edge interrupt enable register */ /*! @{ */ #define PINT_IENF_ENAF_MASK (0xFFU) #define PINT_IENF_ENAF_SHIFT (0U) /*! ENAF - Enables the falling edge or configures the active level interrupt for each pin interrupt. * Bit n configures the pin interrupt selected in PINTSELn. 0 = Disable falling edge interrupt * or set active interrupt level LOW. 1 = Enable falling edge interrupt enabled or set active * interrupt level HIGH. */ #define PINT_IENF_ENAF(x) (((uint32_t)(((uint32_t)(x)) << PINT_IENF_ENAF_SHIFT)) & PINT_IENF_ENAF_MASK) /*! @} */ /*! @name SIENF - Pin interrupt active level or falling edge interrupt set register */ /*! @{ */ #define PINT_SIENF_SETENAF_MASK (0xFFU) #define PINT_SIENF_SETENAF_SHIFT (0U) /*! SETENAF - Ones written to this address set bits in the IENF, thus enabling interrupts. Bit n * sets bit n in the IENF register. 0 = No operation. 1 = Select HIGH-active interrupt or enable * falling edge interrupt. */ #define PINT_SIENF_SETENAF(x) (((uint32_t)(((uint32_t)(x)) << PINT_SIENF_SETENAF_SHIFT)) & PINT_SIENF_SETENAF_MASK) /*! @} */ /*! @name CIENF - Pin interrupt active level or falling edge interrupt clear register */ /*! @{ */ #define PINT_CIENF_CENAF_MASK (0xFFU) #define PINT_CIENF_CENAF_SHIFT (0U) /*! CENAF - Ones written to this address clears bits in the IENF, thus disabling interrupts. Bit n * clears bit n in the IENF register. 0 = No operation. 1 = LOW-active interrupt selected or * falling edge interrupt disabled. */ #define PINT_CIENF_CENAF(x) (((uint32_t)(((uint32_t)(x)) << PINT_CIENF_CENAF_SHIFT)) & PINT_CIENF_CENAF_MASK) /*! @} */ /*! @name RISE - Pin interrupt rising edge register */ /*! @{ */ #define PINT_RISE_RDET_MASK (0xFFU) #define PINT_RISE_RDET_SHIFT (0U) /*! RDET - Rising edge detect. Bit n detects the rising edge of the pin selected in PINTSELn. Read * 0: No rising edge has been detected on this pin since Reset or the last time a one was written * to this bit. Write 0: no operation. Read 1: a rising edge has been detected since Reset or the * last time a one was written to this bit. Write 1: clear rising edge detection for this pin. */ #define PINT_RISE_RDET(x) (((uint32_t)(((uint32_t)(x)) << PINT_RISE_RDET_SHIFT)) & PINT_RISE_RDET_MASK) /*! @} */ /*! @name FALL - Pin interrupt falling edge register */ /*! @{ */ #define PINT_FALL_FDET_MASK (0xFFU) #define PINT_FALL_FDET_SHIFT (0U) /*! FDET - Falling edge detect. Bit n detects the falling edge of the pin selected in PINTSELn. Read * 0: No falling edge has been detected on this pin since Reset or the last time a one was * written to this bit. Write 0: no operation. Read 1: a falling edge has been detected since Reset or * the last time a one was written to this bit. Write 1: clear falling edge detection for this * pin. */ #define PINT_FALL_FDET(x) (((uint32_t)(((uint32_t)(x)) << PINT_FALL_FDET_SHIFT)) & PINT_FALL_FDET_MASK) /*! @} */ /*! @name IST - Pin interrupt status register */ /*! @{ */ #define PINT_IST_PSTAT_MASK (0xFFU) #define PINT_IST_PSTAT_SHIFT (0U) /*! PSTAT - Pin interrupt status. Bit n returns the status, clears the edge interrupt, or inverts * the active level of the pin selected in PINTSELn. Read 0: interrupt is not being requested for * this interrupt pin. Write 0: no operation. Read 1: interrupt is being requested for this * interrupt pin. Write 1 (edge-sensitive): clear rising- and falling-edge detection for this pin. * Write 1 (level-sensitive): switch the active level for this pin (in the IENF register). */ #define PINT_IST_PSTAT(x) (((uint32_t)(((uint32_t)(x)) << PINT_IST_PSTAT_SHIFT)) & PINT_IST_PSTAT_MASK) /*! @} */ /*! @name PMCTRL - Pattern match interrupt control register */ /*! @{ */ #define PINT_PMCTRL_SEL_PMATCH_MASK (0x1U) #define PINT_PMCTRL_SEL_PMATCH_SHIFT (0U) /*! SEL_PMATCH - Specifies whether the 8 pin interrupts are controlled by the pin interrupt function or by the pattern match function. * 0b0..Pin interrupt. Interrupts are driven in response to the standard pin interrupt function. * 0b1..Pattern match. Interrupts are driven in response to pattern matches. */ #define PINT_PMCTRL_SEL_PMATCH(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCTRL_SEL_PMATCH_SHIFT)) & PINT_PMCTRL_SEL_PMATCH_MASK) #define PINT_PMCTRL_ENA_RXEV_MASK (0x2U) #define PINT_PMCTRL_ENA_RXEV_SHIFT (1U) /*! ENA_RXEV - Enables the RXEV output to the CPU and/or to a GPIO output when the specified boolean expression evaluates to true. * 0b0..Disabled. RXEV output to the CPU is disabled. * 0b1..Enabled. RXEV output to the CPU is enabled. */ #define PINT_PMCTRL_ENA_RXEV(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCTRL_ENA_RXEV_SHIFT)) & PINT_PMCTRL_ENA_RXEV_MASK) #define PINT_PMCTRL_PMAT_MASK (0xFF000000U) #define PINT_PMCTRL_PMAT_SHIFT (24U) /*! PMAT - This field displays the current state of pattern matches. A 1 in any bit of this field * indicates that the corresponding product term is matched by the current state of the appropriate * inputs. */ #define PINT_PMCTRL_PMAT(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCTRL_PMAT_SHIFT)) & PINT_PMCTRL_PMAT_MASK) /*! @} */ /*! @name PMSRC - Pattern match interrupt bit-slice source register */ /*! @{ */ #define PINT_PMSRC_SRC0_MASK (0x700U) #define PINT_PMSRC_SRC0_SHIFT (8U) /*! SRC0 - Selects the input source for bit slice 0 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 0. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 0. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 0. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 0. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 0. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 0. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 0. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 0. */ #define PINT_PMSRC_SRC0(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC0_SHIFT)) & PINT_PMSRC_SRC0_MASK) #define PINT_PMSRC_SRC1_MASK (0x3800U) #define PINT_PMSRC_SRC1_SHIFT (11U) /*! SRC1 - Selects the input source for bit slice 1 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 1. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 1. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 1. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 1. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 1. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 1. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 1. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 1. */ #define PINT_PMSRC_SRC1(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC1_SHIFT)) & PINT_PMSRC_SRC1_MASK) #define PINT_PMSRC_SRC2_MASK (0x1C000U) #define PINT_PMSRC_SRC2_SHIFT (14U) /*! SRC2 - Selects the input source for bit slice 2 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 2. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 2. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 2. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 2. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 2. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 2. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 2. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 2. */ #define PINT_PMSRC_SRC2(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC2_SHIFT)) & PINT_PMSRC_SRC2_MASK) #define PINT_PMSRC_SRC3_MASK (0xE0000U) #define PINT_PMSRC_SRC3_SHIFT (17U) /*! SRC3 - Selects the input source for bit slice 3 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 3. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 3. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 3. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 3. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 3. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 3. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 3. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 3. */ #define PINT_PMSRC_SRC3(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC3_SHIFT)) & PINT_PMSRC_SRC3_MASK) #define PINT_PMSRC_SRC4_MASK (0x700000U) #define PINT_PMSRC_SRC4_SHIFT (20U) /*! SRC4 - Selects the input source for bit slice 4 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 4. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 4. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 4. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 4. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 4. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 4. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 4. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 4. */ #define PINT_PMSRC_SRC4(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC4_SHIFT)) & PINT_PMSRC_SRC4_MASK) #define PINT_PMSRC_SRC5_MASK (0x3800000U) #define PINT_PMSRC_SRC5_SHIFT (23U) /*! SRC5 - Selects the input source for bit slice 5 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 5. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 5. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 5. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 5. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 5. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 5. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 5. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 5. */ #define PINT_PMSRC_SRC5(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC5_SHIFT)) & PINT_PMSRC_SRC5_MASK) #define PINT_PMSRC_SRC6_MASK (0x1C000000U) #define PINT_PMSRC_SRC6_SHIFT (26U) /*! SRC6 - Selects the input source for bit slice 6 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 6. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 6. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 6. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 6. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 6. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 6. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 6. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 6. */ #define PINT_PMSRC_SRC6(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC6_SHIFT)) & PINT_PMSRC_SRC6_MASK) #define PINT_PMSRC_SRC7_MASK (0xE0000000U) #define PINT_PMSRC_SRC7_SHIFT (29U) /*! SRC7 - Selects the input source for bit slice 7 * 0b000..Input 0. Selects the pin selected in the PINTSEL0 register as the source to bit slice 7. * 0b001..Input 1. Selects the pin selected in the PINTSEL1 register as the source to bit slice 7. * 0b010..Input 2. Selects the pin selected in the PINTSEL2 register as the source to bit slice 7. * 0b011..Input 3. Selects the pin selected in the PINTSEL3 register as the source to bit slice 7. * 0b100..Input 4. Selects the pin selected in the PINTSEL4 register as the source to bit slice 7. * 0b101..Input 5. Selects the pin selected in the PINTSEL5 register as the source to bit slice 7. * 0b110..Input 6. Selects the pin selected in the PINTSEL6 register as the source to bit slice 7. * 0b111..Input 7. Selects the pin selected in the PINTSEL7 register as the source to bit slice 7. */ #define PINT_PMSRC_SRC7(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMSRC_SRC7_SHIFT)) & PINT_PMSRC_SRC7_MASK) /*! @} */ /*! @name PMCFG - Pattern match interrupt bit slice configuration register */ /*! @{ */ #define PINT_PMCFG_PROD_ENDPTS0_MASK (0x1U) #define PINT_PMCFG_PROD_ENDPTS0_SHIFT (0U) /*! PROD_ENDPTS0 - Determines whether slice 0 is an endpoint. * 0b0..No effect. Slice 0 is not an endpoint. * 0b1..endpoint. Slice 0 is the endpoint of a product term (minterm). Pin interrupt 0 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS0(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS0_SHIFT)) & PINT_PMCFG_PROD_ENDPTS0_MASK) #define PINT_PMCFG_PROD_ENDPTS1_MASK (0x2U) #define PINT_PMCFG_PROD_ENDPTS1_SHIFT (1U) /*! PROD_ENDPTS1 - Determines whether slice 1 is an endpoint. * 0b0..No effect. Slice 1 is not an endpoint. * 0b1..endpoint. Slice 1 is the endpoint of a product term (minterm). Pin interrupt 1 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS1(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS1_SHIFT)) & PINT_PMCFG_PROD_ENDPTS1_MASK) #define PINT_PMCFG_PROD_ENDPTS2_MASK (0x4U) #define PINT_PMCFG_PROD_ENDPTS2_SHIFT (2U) /*! PROD_ENDPTS2 - Determines whether slice 2 is an endpoint. * 0b0..No effect. Slice 2 is not an endpoint. * 0b1..endpoint. Slice 2 is the endpoint of a product term (minterm). Pin interrupt 2 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS2(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS2_SHIFT)) & PINT_PMCFG_PROD_ENDPTS2_MASK) #define PINT_PMCFG_PROD_ENDPTS3_MASK (0x8U) #define PINT_PMCFG_PROD_ENDPTS3_SHIFT (3U) /*! PROD_ENDPTS3 - Determines whether slice 3 is an endpoint. * 0b0..No effect. Slice 3 is not an endpoint. * 0b1..endpoint. Slice 3 is the endpoint of a product term (minterm). Pin interrupt 3 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS3(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS3_SHIFT)) & PINT_PMCFG_PROD_ENDPTS3_MASK) #define PINT_PMCFG_PROD_ENDPTS4_MASK (0x10U) #define PINT_PMCFG_PROD_ENDPTS4_SHIFT (4U) /*! PROD_ENDPTS4 - Determines whether slice 4 is an endpoint. * 0b0..No effect. Slice 4 is not an endpoint. * 0b1..endpoint. Slice 4 is the endpoint of a product term (minterm). Pin interrupt 4 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS4(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS4_SHIFT)) & PINT_PMCFG_PROD_ENDPTS4_MASK) #define PINT_PMCFG_PROD_ENDPTS5_MASK (0x20U) #define PINT_PMCFG_PROD_ENDPTS5_SHIFT (5U) /*! PROD_ENDPTS5 - Determines whether slice 5 is an endpoint. * 0b0..No effect. Slice 5 is not an endpoint. * 0b1..endpoint. Slice 5 is the endpoint of a product term (minterm). Pin interrupt 5 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS5(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS5_SHIFT)) & PINT_PMCFG_PROD_ENDPTS5_MASK) #define PINT_PMCFG_PROD_ENDPTS6_MASK (0x40U) #define PINT_PMCFG_PROD_ENDPTS6_SHIFT (6U) /*! PROD_ENDPTS6 - Determines whether slice 6 is an endpoint. * 0b0..No effect. Slice 6 is not an endpoint. * 0b1..endpoint. Slice 6 is the endpoint of a product term (minterm). Pin interrupt 6 in the NVIC is raised if the minterm evaluates as true. */ #define PINT_PMCFG_PROD_ENDPTS6(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_PROD_ENDPTS6_SHIFT)) & PINT_PMCFG_PROD_ENDPTS6_MASK) #define PINT_PMCFG_CFG0_MASK (0x700U) #define PINT_PMCFG_CFG0_SHIFT (8U) /*! CFG0 - Specifies the match contribution condition for bit slice 0. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG0(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG0_SHIFT)) & PINT_PMCFG_CFG0_MASK) #define PINT_PMCFG_CFG1_MASK (0x3800U) #define PINT_PMCFG_CFG1_SHIFT (11U) /*! CFG1 - Specifies the match contribution condition for bit slice 1. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG1(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG1_SHIFT)) & PINT_PMCFG_CFG1_MASK) #define PINT_PMCFG_CFG2_MASK (0x1C000U) #define PINT_PMCFG_CFG2_SHIFT (14U) /*! CFG2 - Specifies the match contribution condition for bit slice 2. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG2(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG2_SHIFT)) & PINT_PMCFG_CFG2_MASK) #define PINT_PMCFG_CFG3_MASK (0xE0000U) #define PINT_PMCFG_CFG3_SHIFT (17U) /*! CFG3 - Specifies the match contribution condition for bit slice 3. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG3(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG3_SHIFT)) & PINT_PMCFG_CFG3_MASK) #define PINT_PMCFG_CFG4_MASK (0x700000U) #define PINT_PMCFG_CFG4_SHIFT (20U) /*! CFG4 - Specifies the match contribution condition for bit slice 4. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG4(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG4_SHIFT)) & PINT_PMCFG_CFG4_MASK) #define PINT_PMCFG_CFG5_MASK (0x3800000U) #define PINT_PMCFG_CFG5_SHIFT (23U) /*! CFG5 - Specifies the match contribution condition for bit slice 5. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG5(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG5_SHIFT)) & PINT_PMCFG_CFG5_MASK) #define PINT_PMCFG_CFG6_MASK (0x1C000000U) #define PINT_PMCFG_CFG6_SHIFT (26U) /*! CFG6 - Specifies the match contribution condition for bit slice 6. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG6(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG6_SHIFT)) & PINT_PMCFG_CFG6_MASK) #define PINT_PMCFG_CFG7_MASK (0xE0000000U) #define PINT_PMCFG_CFG7_SHIFT (29U) /*! CFG7 - Specifies the match contribution condition for bit slice 7. * 0b000..Constant HIGH. This bit slice always contributes to a product term match. * 0b001..Sticky rising edge. Match occurs if a rising edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b010..Sticky falling edge. Match occurs if a falling edge on the specified input has occurred since the last * time the edge detection for this bit slice was cleared. This bit is only cleared when the PMCFG or the * PMSRC registers are written to. * 0b011..Sticky rising or falling edge. Match occurs if either a rising or falling edge on the specified input * has occurred since the last time the edge detection for this bit slice was cleared. This bit is only * cleared when the PMCFG or the PMSRC registers are written to. * 0b100..High level. Match (for this bit slice) occurs when there is a high level on the input specified for this bit slice in the PMSRC register. * 0b101..Low level. Match occurs when there is a low level on the specified input. * 0b110..Constant 0. This bit slice never contributes to a match (should be used to disable any unused bit slices). * 0b111..Event. Non-sticky rising or falling edge. Match occurs on an event - i.e. when either a rising or * falling edge is first detected on the specified input (this is a non-sticky version of value 0x3) . This bit * is cleared after one clock cycle. */ #define PINT_PMCFG_CFG7(x) (((uint32_t)(((uint32_t)(x)) << PINT_PMCFG_CFG7_SHIFT)) & PINT_PMCFG_CFG7_MASK) /*! @} */ /*! * @} */ /* end of group PINT_Register_Masks */ /* PINT - Peripheral instance base addresses */ /** Peripheral PINT base address */ #define PINT_BASE (0xA0004000u) /** Peripheral PINT base pointer */ #define PINT ((PINT_Type *)PINT_BASE) /** Array initializer of PINT peripheral base addresses */ #define PINT_BASE_ADDRS { PINT_BASE } /** Array initializer of PINT peripheral base pointers */ #define PINT_BASE_PTRS { PINT } /** Interrupt vectors for the PINT peripheral type */ #define PINT_IRQS { PIN_INT0_IRQn, PIN_INT1_IRQn, PIN_INT2_IRQn, PIN_INT3_IRQn, PIN_INT4_IRQn, PIN_INT5_IRQn, PIN_INT6_IRQn, PIN_INT7_IRQn } /*! * @} */ /* end of group PINT_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- PMU Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup PMU_Peripheral_Access_Layer PMU Peripheral Access Layer * @{ */ /** PMU - Register Layout Typedef */ typedef struct { __IO uint32_t PCON; /**< Power control register, offset: 0x0 */ __IO uint32_t GPREG[4]; /**< General purpose register N, array offset: 0x4, array step: 0x4 */ __IO uint32_t DPDCTRL; /**< Deep power-down control register. Also includes bits for general purpose storage., offset: 0x14 */ } PMU_Type; /* ---------------------------------------------------------------------------- -- PMU Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup PMU_Register_Masks PMU Register Masks * @{ */ /*! @name PCON - Power control register */ /*! @{ */ #define PMU_PCON_PM_MASK (0x7U) #define PMU_PCON_PM_SHIFT (0U) /*! PM - Power mode * 0b000..Default. The part is in active or sleep mode. * 0b001..Deep-sleep mode. ARM WFI will enter Deep-sleep mode. * 0b010..Power-down mode. ARM WFI will enter Power-down mode. * 0b011..Deep power-down mode. ARM WFI will enter Deep-power down mode (ARM Cortex-M0+ core powered-down). */ #define PMU_PCON_PM(x) (((uint32_t)(((uint32_t)(x)) << PMU_PCON_PM_SHIFT)) & PMU_PCON_PM_MASK) #define PMU_PCON_NODPD_MASK (0x8U) #define PMU_PCON_NODPD_SHIFT (3U) /*! NODPD - A 1 in this bit prevents entry to Deep power-down mode when 0x3 is written to the PM * field above, the SLEEPDEEP bit is set, and a WFI is executed. This bit is cleared only by * power-on reset, so writing a one to this bit locks the part in a mode in which Deep power-down mode * is blocked. */ #define PMU_PCON_NODPD(x) (((uint32_t)(((uint32_t)(x)) << PMU_PCON_NODPD_SHIFT)) & PMU_PCON_NODPD_MASK) #define PMU_PCON_SLEEPFLAG_MASK (0x100U) #define PMU_PCON_SLEEPFLAG_SHIFT (8U) /*! SLEEPFLAG - Sleep mode flag * 0b0..Active mode. Read: No power-down mode entered. Part is in Active mode. Write: No effect. * 0b1..Low power mode. Read: Sleep, Deep-sleep or Power-down mode entered. Write: Writing a 1 clears the SLEEPFLAG bit to 0. */ #define PMU_PCON_SLEEPFLAG(x) (((uint32_t)(((uint32_t)(x)) << PMU_PCON_SLEEPFLAG_SHIFT)) & PMU_PCON_SLEEPFLAG_MASK) #define PMU_PCON_DPDFLAG_MASK (0x800U) #define PMU_PCON_DPDFLAG_SHIFT (11U) /*! DPDFLAG - Deep power-down flag * 0b0..Not Deep power-down. Read: Deep power-down mode not entered. Write: No effect. * 0b1..Deep power-down. Read: Deep power-down mode entered. Write: Clear the Deep power-down flag. */ #define PMU_PCON_DPDFLAG(x) (((uint32_t)(((uint32_t)(x)) << PMU_PCON_DPDFLAG_SHIFT)) & PMU_PCON_DPDFLAG_MASK) /*! @} */ /*! @name GPREG - General purpose register N */ /*! @{ */ #define PMU_GPREG_GPDATA_MASK (0xFFFFFFFFU) #define PMU_GPREG_GPDATA_SHIFT (0U) /*! GPDATA - Data retained during Deep power-down mode. */ #define PMU_GPREG_GPDATA(x) (((uint32_t)(((uint32_t)(x)) << PMU_GPREG_GPDATA_SHIFT)) & PMU_GPREG_GPDATA_MASK) /*! @} */ /* The count of PMU_GPREG */ #define PMU_GPREG_COUNT (4U) /*! @name DPDCTRL - Deep power-down control register. Also includes bits for general purpose storage. */ /*! @{ */ #define PMU_DPDCTRL_WAKEUPHYS_MASK (0x1U) #define PMU_DPDCTRL_WAKEUPHYS_SHIFT (0U) /*! WAKEUPHYS - WAKEUP pin hysteresis enable * 0b0..Disabled. Hysteresis for WAKEUP pin disabled. * 0b1..Enabled. Hysteresis for WAKEUP pin enabled. */ #define PMU_DPDCTRL_WAKEUPHYS(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_WAKEUPHYS_SHIFT)) & PMU_DPDCTRL_WAKEUPHYS_MASK) #define PMU_DPDCTRL_WAKEPAD_DISABLE_MASK (0x2U) #define PMU_DPDCTRL_WAKEPAD_DISABLE_SHIFT (1U) /*! WAKEPAD_DISABLE - WAKEUP pin disable. Setting this bit disables the wake-up pin, so it can be * used for other purposes. Remark: Never set this bit if you intend to use a pin to wake up the * part from Deep power-down mode. You can only disable the wake-up pin if the self wake-up timer * is enabled and configured. Remark: Setting this bit is not necessary if Deep power-down mode is * not used. * 0b0..Enabled. The wake-up function is enabled on pin PIO0_4. * 0b1..Disabled. Setting this bit disables the wake-up function on pin PIO0_4. */ #define PMU_DPDCTRL_WAKEPAD_DISABLE(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_WAKEPAD_DISABLE_SHIFT)) & PMU_DPDCTRL_WAKEPAD_DISABLE_MASK) #define PMU_DPDCTRL_LPOSCEN_MASK (0x4U) #define PMU_DPDCTRL_LPOSCEN_SHIFT (2U) /*! LPOSCEN - Enable the low-power oscillator for use with the 10 kHz self wake-up timer clock. You * must set this bit if the CLKSEL bit in the self wake-up timer CTRL bit is set. Do not enable * the low-power oscillator if the self wake-up timer is clocked by the divided IRC or the * external clock input. * 0b0..Disabled. * 0b1..Enabled. */ #define PMU_DPDCTRL_LPOSCEN(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_LPOSCEN_SHIFT)) & PMU_DPDCTRL_LPOSCEN_MASK) #define PMU_DPDCTRL_LPOSCDPDEN_MASK (0x8U) #define PMU_DPDCTRL_LPOSCDPDEN_SHIFT (3U) /*! LPOSCDPDEN - causes the low-power oscillator to remain running during Deep power-down mode * provided that bit 2 in this register is set as well. You must set this bit for the self wake-up * timer to be able to wake up the part from Deep power-down mode. Remark: Do not set this bit * unless you use the self wake-up timer with the low-power oscillator clock source to wake up from * Deep power-down mode. * 0b0..Disabled. * 0b1..Enabled. */ #define PMU_DPDCTRL_LPOSCDPDEN(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_LPOSCDPDEN_SHIFT)) & PMU_DPDCTRL_LPOSCDPDEN_MASK) #define PMU_DPDCTRL_WAKEUPCLKHYS_MASK (0x10U) #define PMU_DPDCTRL_WAKEUPCLKHYS_SHIFT (4U) /*! WAKEUPCLKHYS - External clock input for the self wake-up timer WKTCLKIN hysteresis enable. * 0b0..Disabled. Hysteresis for WAKEUP clock pin disabled. * 0b1..Enabled. Hysteresis for WAKEUP clock pin enabled. */ #define PMU_DPDCTRL_WAKEUPCLKHYS(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_WAKEUPCLKHYS_SHIFT)) & PMU_DPDCTRL_WAKEUPCLKHYS_MASK) #define PMU_DPDCTRL_WAKECLKPAD_DISABLE_MASK (0x20U) #define PMU_DPDCTRL_WAKECLKPAD_DISABLE_SHIFT (5U) /*! WAKECLKPAD_DISABLE - Disable the external clock input for the self wake-up timer. Setting this * bit enables the self wake-up timer clock pin WKTCLKLIN. To minimize power consumption, * especially in deep power-down mode, disable this clock input when not using the external clock option * for the self wake-up timer. * 0b0..Disabled. Setting this bit disables external clock input on pin PIO0_28. * 0b1..Enabled. The external clock input for the self wake-up timer is enabled on pin PIO0_28. */ #define PMU_DPDCTRL_WAKECLKPAD_DISABLE(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_WAKECLKPAD_DISABLE_SHIFT)) & PMU_DPDCTRL_WAKECLKPAD_DISABLE_MASK) #define PMU_DPDCTRL_GPDATA_MASK (0xFFFFFFC0U) #define PMU_DPDCTRL_GPDATA_SHIFT (6U) /*! GPDATA - Data retained during Deep power-down mode. */ #define PMU_DPDCTRL_GPDATA(x) (((uint32_t)(((uint32_t)(x)) << PMU_DPDCTRL_GPDATA_SHIFT)) & PMU_DPDCTRL_GPDATA_MASK) /*! @} */ /*! * @} */ /* end of group PMU_Register_Masks */ /* PMU - Peripheral instance base addresses */ /** Peripheral PMU base address */ #define PMU_BASE (0x40020000u) /** Peripheral PMU base pointer */ #define PMU ((PMU_Type *)PMU_BASE) /** Array initializer of PMU peripheral base addresses */ #define PMU_BASE_ADDRS { PMU_BASE } /** Array initializer of PMU peripheral base pointers */ #define PMU_BASE_PTRS { PMU } /*! * @} */ /* end of group PMU_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- SCT Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup SCT_Peripheral_Access_Layer SCT Peripheral Access Layer * @{ */ /** SCT - Register Layout Typedef */ typedef struct { __IO uint32_t CONFIG; /**< SCT configuration register, offset: 0x0 */ union { /* offset: 0x4 */ struct { /* offset: 0x4 */ __IO uint16_t CTRLL; /**< SCT_CTRLL register, offset: 0x4 */ __IO uint16_t CTRLH; /**< SCT_CTRLH register, offset: 0x6 */ } CTRL_ACCESS16BIT; __IO uint32_t CTRL; /**< SCT control register, offset: 0x4 */ }; union { /* offset: 0x8 */ struct { /* offset: 0x8 */ __IO uint16_t LIMITL; /**< SCT_LIMITL register, offset: 0x8 */ __IO uint16_t LIMITH; /**< SCT_LIMITH register, offset: 0xA */ } LIMIT_ACCESS16BIT; __IO uint32_t LIMIT; /**< SCT limit event select register, offset: 0x8 */ }; union { /* offset: 0xC */ struct { /* offset: 0xC */ __IO uint16_t HALTL; /**< SCT_HALTL register, offset: 0xC */ __IO uint16_t HALTH; /**< SCT_HALTH register, offset: 0xE */ } HALT_ACCESS16BIT; __IO uint32_t HALT; /**< SCT halt event select register, offset: 0xC */ }; union { /* offset: 0x10 */ struct { /* offset: 0x10 */ __IO uint16_t STOPL; /**< SCT_STOPL register, offset: 0x10 */ __IO uint16_t STOPH; /**< SCT_STOPH register, offset: 0x12 */ } STOP_ACCESS16BIT; __IO uint32_t STOP; /**< SCT stop event select register, offset: 0x10 */ }; union { /* offset: 0x14 */ struct { /* offset: 0x14 */ __IO uint16_t STARTL; /**< SCT_STARTL register, offset: 0x14 */ __IO uint16_t STARTH; /**< SCT_STARTH register, offset: 0x16 */ } START_ACCESS16BIT; __IO uint32_t START; /**< SCT start event select register, offset: 0x14 */ }; uint8_t RESERVED_0[40]; union { /* offset: 0x40 */ struct { /* offset: 0x40 */ __IO uint16_t COUNTL; /**< SCT_COUNTL register, offset: 0x40 */ __IO uint16_t COUNTH; /**< SCT_COUNTH register, offset: 0x42 */ } COUNT_ACCESS16BIT; __IO uint32_t COUNT; /**< SCT counter register, offset: 0x40 */ }; union { /* offset: 0x44 */ struct { /* offset: 0x44 */ __IO uint16_t STATEL; /**< SCT_STATEL register, offset: 0x44 */ __IO uint16_t STATEH; /**< SCT_STATEH register, offset: 0x46 */ } STATE_ACCESS16BIT; __IO uint32_t STATE; /**< SCT state register, offset: 0x44 */ }; __I uint32_t INPUT; /**< SCT input register, offset: 0x48 */ union { /* offset: 0x4C */ struct { /* offset: 0x4C */ __IO uint16_t REGMODEL; /**< SCT_REGMODEL register, offset: 0x4C */ __IO uint16_t REGMODEH; /**< SCT_REGMODEH register, offset: 0x4E */ } REGMODE_ACCESS16BIT; __IO uint32_t REGMODE; /**< SCT match/capture mode register, offset: 0x4C */ }; __IO uint32_t OUTPUT; /**< SCT output register, offset: 0x50 */ __IO uint32_t OUTPUTDIRCTRL; /**< SCT output counter direction control register, offset: 0x54 */ __IO uint32_t RES; /**< SCT conflict resolution register, offset: 0x58 */ __IO uint32_t DMAREQ0; /**< SCT DMA request 0 register, offset: 0x5C */ __IO uint32_t DMAREQ1; /**< SCT DMA request 1 register, offset: 0x60 */ uint8_t RESERVED_1[140]; __IO uint32_t EVEN; /**< SCT event interrupt enable register, offset: 0xF0 */ __IO uint32_t EVFLAG; /**< SCT event flag register, offset: 0xF4 */ __IO uint32_t CONEN; /**< SCT conflict interrupt enable register, offset: 0xF8 */ __IO uint32_t CONFLAG; /**< SCT conflict flag register, offset: 0xFC */ union { /* offset: 0x100 */ union { /* offset: 0x100, array step: 0x4 */ struct { /* offset: 0x100, array step: 0x4 */ __IO uint16_t CAPL; /**< SCT_CAPL register, array offset: 0x100, array step: 0x4 */ __IO uint16_t CAPH; /**< SCT_CAPH register, array offset: 0x102, array step: 0x4 */ } CAP_ACCESS16BIT[8]; __IO uint32_t CAP[8]; /**< SCT capture register of capture channel, array offset: 0x100, array step: 0x4 */ }; union { /* offset: 0x100, array step: 0x4 */ struct { /* offset: 0x100, array step: 0x4 */ __IO uint16_t MATCHL; /**< SCT_MATCHL register, array offset: 0x100, array step: 0x4 */ __IO uint16_t MATCHH; /**< SCT_MATCHH register, array offset: 0x102, array step: 0x4 */ } MATCH_ACCESS16BIT[8]; __IO uint32_t MATCH[8]; /**< SCT match value register of match channels, array offset: 0x100, array step: 0x4 */ }; }; uint8_t RESERVED_2[224]; union { /* offset: 0x200 */ union { /* offset: 0x200, array step: 0x4 */ struct { /* offset: 0x200, array step: 0x4 */ __IO uint16_t CAPCTRLL; /**< SCT_CAPCTRLL register, array offset: 0x200, array step: 0x4 */ __IO uint16_t CAPCTRLH; /**< SCT_CAPCTRLH register, array offset: 0x202, array step: 0x4 */ } CAPCTRL_ACCESS16BIT[8]; __IO uint32_t CAPCTRL[8]; /**< SCT capture control register, array offset: 0x200, array step: 0x4 */ }; union { /* offset: 0x200, array step: 0x4 */ struct { /* offset: 0x200, array step: 0x4 */ __IO uint16_t MATCHRELL; /**< SCT_MATCHRELL register, array offset: 0x200, array step: 0x4 */ __IO uint16_t MATCHRELH; /**< SCT_MATCHRELH register, array offset: 0x202, array step: 0x4 */ } MATCHREL_ACCESS16BIT[8]; __IO uint32_t MATCHREL[8]; /**< SCT match reload value register, array offset: 0x200, array step: 0x4 */ }; }; uint8_t RESERVED_3[224]; struct { /* offset: 0x300, array step: 0x8 */ __IO uint32_t STATE; /**< SCT event state register 0, array offset: 0x300, array step: 0x8 */ __IO uint32_t CTRL; /**< SCT event control register 0, array offset: 0x304, array step: 0x8 */ } EV[8]; uint8_t RESERVED_4[448]; struct { /* offset: 0x500, array step: 0x8 */ __IO uint32_t SET; /**< SCT output 0 set register, array offset: 0x500, array step: 0x8 */ __IO uint32_t CLR; /**< SCT output 0 clear register, array offset: 0x504, array step: 0x8 */ } OUT[6]; } SCT_Type; /* ---------------------------------------------------------------------------- -- SCT Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup SCT_Register_Masks SCT Register Masks * @{ */ /*! @name CONFIG - SCT configuration register */ /*! @{ */ #define SCT_CONFIG_UNIFY_MASK (0x1U) #define SCT_CONFIG_UNIFY_SHIFT (0U) /*! UNIFY - SCT operation * 0b0..The SCT operates as two 16-bit counters named COUNTER_L and COUNTER_H. * 0b1..The SCT operates as a unified 32-bit counter. */ #define SCT_CONFIG_UNIFY(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_UNIFY_SHIFT)) & SCT_CONFIG_UNIFY_MASK) #define SCT_CONFIG_CLKMODE_MASK (0x6U) #define SCT_CONFIG_CLKMODE_SHIFT (1U) /*! CLKMODE - SCT clock mode * 0b00..System Clock Mode. The system clock clocks the entire SCT module including the counter(s) and counter prescalers. * 0b01..Sampled System Clock Mode. The system clock clocks the SCT module, but the counter and prescalers are * only enabled to count when the designated edge is detected on the input selected by the CKSEL field. The * minimum pulse width on the selected clock-gate input is 1 bus clock period. This mode is the * high-performance, sampled-clock mode. * 0b10..SCT Input Clock Mode. The input/edge selected by the CKSEL field clocks the SCT module, including the * counters and prescalers, after first being synchronized to the system clock. The minimum pulse width on the * clock input is 1 bus clock period. This mode is the low-power, sampled-clock mode. * 0b11..Asynchronous Mode. The entire SCT module is clocked directly by the input/edge selected by the CKSEL * field. In this mode, the SCT outputs are switched synchronously to the SCT input clock - not the system * clock. The input clock rate must be at least half the system clock rate and can be the same or faster than * the system clock. */ #define SCT_CONFIG_CLKMODE(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_CLKMODE_SHIFT)) & SCT_CONFIG_CLKMODE_MASK) #define SCT_CONFIG_CKSEL_MASK (0x78U) #define SCT_CONFIG_CKSEL_SHIFT (3U) /*! CKSEL - SCT clock select. The specific functionality of the designated input/edge is dependent * on the CLKMODE bit selection in this register. * 0b0000..Rising edges on input 0. * 0b0001..Falling edges on input 0. * 0b0010..Rising edges on input 1. * 0b0011..Falling edges on input 1. * 0b0100..Rising edges on input 2. * 0b0101..Falling edges on input 2. * 0b0110..Rising edges on input 3. * 0b0111..Falling edges on input 3. */ #define SCT_CONFIG_CKSEL(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_CKSEL_SHIFT)) & SCT_CONFIG_CKSEL_MASK) #define SCT_CONFIG_NORELOAD_L_MASK (0x80U) #define SCT_CONFIG_NORELOAD_L_SHIFT (7U) /*! NORELOAD_L - A 1 in this bit prevents the lower match registers from being reloaded from their * respective reload registers. Setting this bit eliminates the need to write to the reload * registers MATCHREL if the match values are fixed. Software can write to set or clear this bit at any * time. This bit applies to both the higher and lower registers when the UNIFY bit is set. */ #define SCT_CONFIG_NORELOAD_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_NORELOAD_L_SHIFT)) & SCT_CONFIG_NORELOAD_L_MASK) #define SCT_CONFIG_NORELOAD_H_MASK (0x100U) #define SCT_CONFIG_NORELOAD_H_SHIFT (8U) /*! NORELOAD_H - A 1 in this bit prevents the higher match registers from being reloaded from their * respective reload registers. Setting this bit eliminates the need to write to the reload * registers MATCHREL if the match values are fixed. Software can write to set or clear this bit at * any time. This bit is not used when the UNIFY bit is set. */ #define SCT_CONFIG_NORELOAD_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_NORELOAD_H_SHIFT)) & SCT_CONFIG_NORELOAD_H_MASK) #define SCT_CONFIG_INSYNC_MASK (0x1E00U) #define SCT_CONFIG_INSYNC_SHIFT (9U) /*! INSYNC - Synchronization for input N (bit 9 = input 0, bit 10 = input 1,, bit 12 = input 3); all * other bits are reserved. A 1 in one of these bits subjects the corresponding input to * synchronization to the SCT clock, before it is used to create an event. If an input is known to * already be synchronous to the SCT clock, this bit may be set to 0 for faster input response. (Note: * The SCT clock is the system clock for CKMODEs 0-2. It is the selected, asynchronous SCT input * clock for CKMODE3). Note that the INSYNC field only affects inputs used for event generation. * It does not apply to the clock input specified in the CKSEL field. */ #define SCT_CONFIG_INSYNC(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_INSYNC_SHIFT)) & SCT_CONFIG_INSYNC_MASK) #define SCT_CONFIG_AUTOLIMIT_L_MASK (0x20000U) #define SCT_CONFIG_AUTOLIMIT_L_SHIFT (17U) /*! AUTOLIMIT_L - A one in this bit causes a match on match register 0 to be treated as a de-facto * LIMIT condition without the need to define an associated event. As with any LIMIT event, this * automatic limit causes the counter to be cleared to zero in unidirectional mode or to change * the direction of count in bi-directional mode. Software can write to set or clear this bit at * any time. This bit applies to both the higher and lower registers when the UNIFY bit is set. */ #define SCT_CONFIG_AUTOLIMIT_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_AUTOLIMIT_L_SHIFT)) & SCT_CONFIG_AUTOLIMIT_L_MASK) #define SCT_CONFIG_AUTOLIMIT_H_MASK (0x40000U) #define SCT_CONFIG_AUTOLIMIT_H_SHIFT (18U) /*! AUTOLIMIT_H - A one in this bit will cause a match on match register 0 to be treated as a * de-facto LIMIT condition without the need to define an associated event. As with any LIMIT event, * this automatic limit causes the counter to be cleared to zero in unidirectional mode or to * change the direction of count in bi-directional mode. Software can write to set or clear this bit * at any time. This bit is not used when the UNIFY bit is set. */ #define SCT_CONFIG_AUTOLIMIT_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFIG_AUTOLIMIT_H_SHIFT)) & SCT_CONFIG_AUTOLIMIT_H_MASK) /*! @} */ /*! @name CTRLL - SCT_CTRLL register */ /*! @{ */ #define SCT_CTRLL_DOWN_L_MASK (0x1U) #define SCT_CTRLL_DOWN_L_SHIFT (0U) /*! DOWN_L - This bit is 1 when the L or unified counter is counting down. Hardware sets this bit * when the counter is counting up, counter limit occurs, and BIDIR = 1.Hardware clears this bit * when the counter is counting down and a limit condition occurs or when the counter reaches 0. */ #define SCT_CTRLL_DOWN_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_DOWN_L_SHIFT)) & SCT_CTRLL_DOWN_L_MASK) #define SCT_CTRLL_STOP_L_MASK (0x2U) #define SCT_CTRLL_STOP_L_SHIFT (1U) /*! STOP_L - When this bit is 1 and HALT is 0, the L or unified counter does not run, but I/O events * related to the counter can occur. If a designated start event occurs, this bit is cleared and * counting resumes. */ #define SCT_CTRLL_STOP_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_STOP_L_SHIFT)) & SCT_CTRLL_STOP_L_MASK) #define SCT_CTRLL_HALT_L_MASK (0x4U) #define SCT_CTRLL_HALT_L_SHIFT (2U) /*! HALT_L - When this bit is 1, the L or unified counter does not run and no events can occur. A * reset sets this bit. When the HALT_L bit is one, the STOP_L bit is cleared. It is possible to * remove the halt condition while keeping the SCT in the stop condition (not running) with a * single write to this register to simultaneously clear the HALT bit and set the STOP bit. Once set, * only software can clear this bit to restore counter operation. This bit is set on reset. */ #define SCT_CTRLL_HALT_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_HALT_L_SHIFT)) & SCT_CTRLL_HALT_L_MASK) #define SCT_CTRLL_CLRCTR_L_MASK (0x8U) #define SCT_CTRLL_CLRCTR_L_SHIFT (3U) /*! CLRCTR_L - Writing a 1 to this bit clears the L or unified counter. This bit always reads as 0. */ #define SCT_CTRLL_CLRCTR_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_CLRCTR_L_SHIFT)) & SCT_CTRLL_CLRCTR_L_MASK) #define SCT_CTRLL_BIDIR_L_MASK (0x10U) #define SCT_CTRLL_BIDIR_L_SHIFT (4U) /*! BIDIR_L - L or unified counter direction select * 0b0..Up. The counter counts up to a limit condition, then is cleared to zero. * 0b1..Up-down. The counter counts up to a limit, then counts down to a limit condition or to 0. */ #define SCT_CTRLL_BIDIR_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_BIDIR_L_SHIFT)) & SCT_CTRLL_BIDIR_L_MASK) #define SCT_CTRLL_PRE_L_MASK (0x1FE0U) #define SCT_CTRLL_PRE_L_SHIFT (5U) /*! PRE_L - Specifies the factor by which the SCT clock is prescaled to produce the L or unified * counter clock. The counter clock is clocked at the rate of the SCT clock divided by PRE_L+1. * Clear the counter (by writing a 1 to the CLRCTR bit) whenever changing the PRE value. */ #define SCT_CTRLL_PRE_L(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLL_PRE_L_SHIFT)) & SCT_CTRLL_PRE_L_MASK) /*! @} */ /*! @name CTRLH - SCT_CTRLH register */ /*! @{ */ #define SCT_CTRLH_DOWN_H_MASK (0x1U) #define SCT_CTRLH_DOWN_H_SHIFT (0U) /*! DOWN_H - This bit is 1 when the H counter is counting down. Hardware sets this bit when the * counter is counting, a counter limit condition occurs, and BIDIR is 1. Hardware clears this bit * when the counter is counting down and a limit condition occurs or when the counter reaches 0. */ #define SCT_CTRLH_DOWN_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_DOWN_H_SHIFT)) & SCT_CTRLH_DOWN_H_MASK) #define SCT_CTRLH_STOP_H_MASK (0x2U) #define SCT_CTRLH_STOP_H_SHIFT (1U) /*! STOP_H - When this bit is 1 and HALT is 0, the H counter does not, run but I/O events related to * the counter can occur. If such an event matches the mask in the Start register, this bit is * cleared and counting resumes. */ #define SCT_CTRLH_STOP_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_STOP_H_SHIFT)) & SCT_CTRLH_STOP_H_MASK) #define SCT_CTRLH_HALT_H_MASK (0x4U) #define SCT_CTRLH_HALT_H_SHIFT (2U) /*! HALT_H - When this bit is 1, the H counter does not run and no events can occur. A reset sets * this bit. When the HALT_H bit is one, the STOP_H bit is cleared. It is possible to remove the * halt condition while keeping the SCT in the stop condition (not running) with a single write to * this register to simultaneously clear the HALT bit and set the STOP bit. Once set, this bit * can only be cleared by software to restore counter operation. This bit is set on reset. */ #define SCT_CTRLH_HALT_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_HALT_H_SHIFT)) & SCT_CTRLH_HALT_H_MASK) #define SCT_CTRLH_CLRCTR_H_MASK (0x8U) #define SCT_CTRLH_CLRCTR_H_SHIFT (3U) /*! CLRCTR_H - Writing a 1 to this bit clears the H counter. This bit always reads as 0. */ #define SCT_CTRLH_CLRCTR_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_CLRCTR_H_SHIFT)) & SCT_CTRLH_CLRCTR_H_MASK) #define SCT_CTRLH_BIDIR_H_MASK (0x10U) #define SCT_CTRLH_BIDIR_H_SHIFT (4U) /*! BIDIR_H - Direction select * 0b0..The H counter counts up to its limit condition, then is cleared to zero. * 0b1..The H counter counts up to its limit, then counts down to a limit condition or to 0. */ #define SCT_CTRLH_BIDIR_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_BIDIR_H_SHIFT)) & SCT_CTRLH_BIDIR_H_MASK) #define SCT_CTRLH_PRE_H_MASK (0x1FE0U) #define SCT_CTRLH_PRE_H_SHIFT (5U) /*! PRE_H - Specifies the factor by which the SCT clock is prescaled to produce the H counter clock. * The counter clock is clocked at the rate of the SCT clock divided by PRELH+1. Clear the * counter (by writing a 1 to the CLRCTR bit) whenever changing the PRE value. */ #define SCT_CTRLH_PRE_H(x) (((uint16_t)(((uint16_t)(x)) << SCT_CTRLH_PRE_H_SHIFT)) & SCT_CTRLH_PRE_H_MASK) /*! @} */ /*! @name CTRL - SCT control register */ /*! @{ */ #define SCT_CTRL_DOWN_L_MASK (0x1U) #define SCT_CTRL_DOWN_L_SHIFT (0U) /*! DOWN_L - This bit is 1 when the L or unified counter is counting down. Hardware sets this bit * when the counter is counting up, counter limit occurs, and BIDIR = 1.Hardware clears this bit * when the counter is counting down and a limit condition occurs or when the counter reaches 0. */ #define SCT_CTRL_DOWN_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_DOWN_L_SHIFT)) & SCT_CTRL_DOWN_L_MASK) #define SCT_CTRL_STOP_L_MASK (0x2U) #define SCT_CTRL_STOP_L_SHIFT (1U) /*! STOP_L - When this bit is 1 and HALT is 0, the L or unified counter does not run, but I/O events * related to the counter can occur. If a designated start event occurs, this bit is cleared and * counting resumes. */ #define SCT_CTRL_STOP_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_STOP_L_SHIFT)) & SCT_CTRL_STOP_L_MASK) #define SCT_CTRL_HALT_L_MASK (0x4U) #define SCT_CTRL_HALT_L_SHIFT (2U) /*! HALT_L - When this bit is 1, the L or unified counter does not run and no events can occur. A * reset sets this bit. When the HALT_L bit is one, the STOP_L bit is cleared. It is possible to * remove the halt condition while keeping the SCT in the stop condition (not running) with a * single write to this register to simultaneously clear the HALT bit and set the STOP bit. Once set, * only software can clear this bit to restore counter operation. This bit is set on reset. */ #define SCT_CTRL_HALT_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_HALT_L_SHIFT)) & SCT_CTRL_HALT_L_MASK) #define SCT_CTRL_CLRCTR_L_MASK (0x8U) #define SCT_CTRL_CLRCTR_L_SHIFT (3U) /*! CLRCTR_L - Writing a 1 to this bit clears the L or unified counter. This bit always reads as 0. */ #define SCT_CTRL_CLRCTR_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_CLRCTR_L_SHIFT)) & SCT_CTRL_CLRCTR_L_MASK) #define SCT_CTRL_BIDIR_L_MASK (0x10U) #define SCT_CTRL_BIDIR_L_SHIFT (4U) /*! BIDIR_L - L or unified counter direction select * 0b0..Up. The counter counts up to a limit condition, then is cleared to zero. * 0b1..Up-down. The counter counts up to a limit, then counts down to a limit condition or to 0. */ #define SCT_CTRL_BIDIR_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_BIDIR_L_SHIFT)) & SCT_CTRL_BIDIR_L_MASK) #define SCT_CTRL_PRE_L_MASK (0x1FE0U) #define SCT_CTRL_PRE_L_SHIFT (5U) /*! PRE_L - Specifies the factor by which the SCT clock is prescaled to produce the L or unified * counter clock. The counter clock is clocked at the rate of the SCT clock divided by PRE_L+1. * Clear the counter (by writing a 1 to the CLRCTR bit) whenever changing the PRE value. */ #define SCT_CTRL_PRE_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_PRE_L_SHIFT)) & SCT_CTRL_PRE_L_MASK) #define SCT_CTRL_DOWN_H_MASK (0x10000U) #define SCT_CTRL_DOWN_H_SHIFT (16U) /*! DOWN_H - This bit is 1 when the H counter is counting down. Hardware sets this bit when the * counter is counting, a counter limit condition occurs, and BIDIR is 1. Hardware clears this bit * when the counter is counting down and a limit condition occurs or when the counter reaches 0. */ #define SCT_CTRL_DOWN_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_DOWN_H_SHIFT)) & SCT_CTRL_DOWN_H_MASK) #define SCT_CTRL_STOP_H_MASK (0x20000U) #define SCT_CTRL_STOP_H_SHIFT (17U) /*! STOP_H - When this bit is 1 and HALT is 0, the H counter does not, run but I/O events related to * the counter can occur. If such an event matches the mask in the Start register, this bit is * cleared and counting resumes. */ #define SCT_CTRL_STOP_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_STOP_H_SHIFT)) & SCT_CTRL_STOP_H_MASK) #define SCT_CTRL_HALT_H_MASK (0x40000U) #define SCT_CTRL_HALT_H_SHIFT (18U) /*! HALT_H - When this bit is 1, the H counter does not run and no events can occur. A reset sets * this bit. When the HALT_H bit is one, the STOP_H bit is cleared. It is possible to remove the * halt condition while keeping the SCT in the stop condition (not running) with a single write to * this register to simultaneously clear the HALT bit and set the STOP bit. Once set, this bit * can only be cleared by software to restore counter operation. This bit is set on reset. */ #define SCT_CTRL_HALT_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_HALT_H_SHIFT)) & SCT_CTRL_HALT_H_MASK) #define SCT_CTRL_CLRCTR_H_MASK (0x80000U) #define SCT_CTRL_CLRCTR_H_SHIFT (19U) /*! CLRCTR_H - Writing a 1 to this bit clears the H counter. This bit always reads as 0. */ #define SCT_CTRL_CLRCTR_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_CLRCTR_H_SHIFT)) & SCT_CTRL_CLRCTR_H_MASK) #define SCT_CTRL_BIDIR_H_MASK (0x100000U) #define SCT_CTRL_BIDIR_H_SHIFT (20U) /*! BIDIR_H - Direction select * 0b0..The H counter counts up to its limit condition, then is cleared to zero. * 0b1..The H counter counts up to its limit, then counts down to a limit condition or to 0. */ #define SCT_CTRL_BIDIR_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_BIDIR_H_SHIFT)) & SCT_CTRL_BIDIR_H_MASK) #define SCT_CTRL_PRE_H_MASK (0x1FE00000U) #define SCT_CTRL_PRE_H_SHIFT (21U) /*! PRE_H - Specifies the factor by which the SCT clock is prescaled to produce the H counter clock. * The counter clock is clocked at the rate of the SCT clock divided by PRELH+1. Clear the * counter (by writing a 1 to the CLRCTR bit) whenever changing the PRE value. */ #define SCT_CTRL_PRE_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CTRL_PRE_H_SHIFT)) & SCT_CTRL_PRE_H_MASK) /*! @} */ /*! @name LIMITL - SCT_LIMITL register */ /*! @{ */ #define SCT_LIMITL_LIMITL_MASK (0xFFFFU) #define SCT_LIMITL_LIMITL_SHIFT (0U) #define SCT_LIMITL_LIMITL(x) (((uint16_t)(((uint16_t)(x)) << SCT_LIMITL_LIMITL_SHIFT)) & SCT_LIMITL_LIMITL_MASK) /*! @} */ /*! @name LIMITH - SCT_LIMITH register */ /*! @{ */ #define SCT_LIMITH_LIMITH_MASK (0xFFFFU) #define SCT_LIMITH_LIMITH_SHIFT (0U) #define SCT_LIMITH_LIMITH(x) (((uint16_t)(((uint16_t)(x)) << SCT_LIMITH_LIMITH_SHIFT)) & SCT_LIMITH_LIMITH_MASK) /*! @} */ /*! @name LIMIT - SCT limit event select register */ /*! @{ */ #define SCT_LIMIT_LIMMSK_L_MASK (0xFFU) #define SCT_LIMIT_LIMMSK_L_SHIFT (0U) /*! LIMMSK_L - If bit n is one, event n is used as a counter limit for the L or unified counter * (event 0 = bit 0, event 1 = bit 1, etc.). The number of bits = number of events in this SCT. */ #define SCT_LIMIT_LIMMSK_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_LIMIT_LIMMSK_L_SHIFT)) & SCT_LIMIT_LIMMSK_L_MASK) #define SCT_LIMIT_LIMMSK_H_MASK (0xFF0000U) #define SCT_LIMIT_LIMMSK_H_SHIFT (16U) /*! LIMMSK_H - If bit n is one, event n is used as a counter limit for the H counter (event 0 = bit * 16, event 1 = bit 17, etc.). The number of bits = number of events in this SCT. */ #define SCT_LIMIT_LIMMSK_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_LIMIT_LIMMSK_H_SHIFT)) & SCT_LIMIT_LIMMSK_H_MASK) /*! @} */ /*! @name HALTL - SCT_HALTL register */ /*! @{ */ #define SCT_HALTL_HALTL_MASK (0xFFFFU) #define SCT_HALTL_HALTL_SHIFT (0U) #define SCT_HALTL_HALTL(x) (((uint16_t)(((uint16_t)(x)) << SCT_HALTL_HALTL_SHIFT)) & SCT_HALTL_HALTL_MASK) /*! @} */ /*! @name HALTH - SCT_HALTH register */ /*! @{ */ #define SCT_HALTH_HALTH_MASK (0xFFFFU) #define SCT_HALTH_HALTH_SHIFT (0U) #define SCT_HALTH_HALTH(x) (((uint16_t)(((uint16_t)(x)) << SCT_HALTH_HALTH_SHIFT)) & SCT_HALTH_HALTH_MASK) /*! @} */ /*! @name HALT - SCT halt event select register */ /*! @{ */ #define SCT_HALT_HALTMSK_L_MASK (0xFFU) #define SCT_HALT_HALTMSK_L_SHIFT (0U) /*! HALTMSK_L - If bit n is one, event n sets the HALT_L bit in the CTRL register (event 0 = bit 0, * event 1 = bit 1, etc.). The number of bits = number of events in this SCT. */ #define SCT_HALT_HALTMSK_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_HALT_HALTMSK_L_SHIFT)) & SCT_HALT_HALTMSK_L_MASK) #define SCT_HALT_HALTMSK_H_MASK (0xFF0000U) #define SCT_HALT_HALTMSK_H_SHIFT (16U) /*! HALTMSK_H - If bit n is one, event n sets the HALT_H bit in the CTRL register (event 0 = bit 16, * event 1 = bit 17, etc.). The number of bits = number of events in this SCT. */ #define SCT_HALT_HALTMSK_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_HALT_HALTMSK_H_SHIFT)) & SCT_HALT_HALTMSK_H_MASK) /*! @} */ /*! @name STOPL - SCT_STOPL register */ /*! @{ */ #define SCT_STOPL_STOPL_MASK (0xFFFFU) #define SCT_STOPL_STOPL_SHIFT (0U) #define SCT_STOPL_STOPL(x) (((uint16_t)(((uint16_t)(x)) << SCT_STOPL_STOPL_SHIFT)) & SCT_STOPL_STOPL_MASK) /*! @} */ /*! @name STOPH - SCT_STOPH register */ /*! @{ */ #define SCT_STOPH_STOPH_MASK (0xFFFFU) #define SCT_STOPH_STOPH_SHIFT (0U) #define SCT_STOPH_STOPH(x) (((uint16_t)(((uint16_t)(x)) << SCT_STOPH_STOPH_SHIFT)) & SCT_STOPH_STOPH_MASK) /*! @} */ /*! @name STOP - SCT stop event select register */ /*! @{ */ #define SCT_STOP_STOPMSK_L_MASK (0xFFU) #define SCT_STOP_STOPMSK_L_SHIFT (0U) /*! STOPMSK_L - If bit n is one, event n sets the STOP_L bit in the CTRL register (event 0 = bit 0, * event 1 = bit 1, etc.). The number of bits = number of events in this SCT. */ #define SCT_STOP_STOPMSK_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_STOP_STOPMSK_L_SHIFT)) & SCT_STOP_STOPMSK_L_MASK) #define SCT_STOP_STOPMSK_H_MASK (0xFF0000U) #define SCT_STOP_STOPMSK_H_SHIFT (16U) /*! STOPMSK_H - If bit n is one, event n sets the STOP_H bit in the CTRL register (event 0 = bit 16, * event 1 = bit 17, etc.). The number of bits = number of events in this SCT. */ #define SCT_STOP_STOPMSK_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_STOP_STOPMSK_H_SHIFT)) & SCT_STOP_STOPMSK_H_MASK) /*! @} */ /*! @name STARTL - SCT_STARTL register */ /*! @{ */ #define SCT_STARTL_STARTL_MASK (0xFFFFU) #define SCT_STARTL_STARTL_SHIFT (0U) #define SCT_STARTL_STARTL(x) (((uint16_t)(((uint16_t)(x)) << SCT_STARTL_STARTL_SHIFT)) & SCT_STARTL_STARTL_MASK) /*! @} */ /*! @name STARTH - SCT_STARTH register */ /*! @{ */ #define SCT_STARTH_STARTH_MASK (0xFFFFU) #define SCT_STARTH_STARTH_SHIFT (0U) #define SCT_STARTH_STARTH(x) (((uint16_t)(((uint16_t)(x)) << SCT_STARTH_STARTH_SHIFT)) & SCT_STARTH_STARTH_MASK) /*! @} */ /*! @name START - SCT start event select register */ /*! @{ */ #define SCT_START_STARTMSK_L_MASK (0xFFU) #define SCT_START_STARTMSK_L_SHIFT (0U) /*! STARTMSK_L - If bit n is one, event n clears the STOP_L bit in the CTRL register (event 0 = bit * 0, event 1 = bit 1, etc.). The number of bits = number of events in this SCT. */ #define SCT_START_STARTMSK_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_START_STARTMSK_L_SHIFT)) & SCT_START_STARTMSK_L_MASK) #define SCT_START_STARTMSK_H_MASK (0xFF0000U) #define SCT_START_STARTMSK_H_SHIFT (16U) /*! STARTMSK_H - If bit n is one, event n clears the STOP_H bit in the CTRL register (event 0 = bit * 16, event 1 = bit 17, etc.). The number of bits = number of events in this SCT. */ #define SCT_START_STARTMSK_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_START_STARTMSK_H_SHIFT)) & SCT_START_STARTMSK_H_MASK) /*! @} */ /*! @name COUNTL - SCT_COUNTL register */ /*! @{ */ #define SCT_COUNTL_COUNTL_MASK (0xFFFFU) #define SCT_COUNTL_COUNTL_SHIFT (0U) #define SCT_COUNTL_COUNTL(x) (((uint16_t)(((uint16_t)(x)) << SCT_COUNTL_COUNTL_SHIFT)) & SCT_COUNTL_COUNTL_MASK) /*! @} */ /*! @name COUNTH - SCT_COUNTH register */ /*! @{ */ #define SCT_COUNTH_COUNTH_MASK (0xFFFFU) #define SCT_COUNTH_COUNTH_SHIFT (0U) #define SCT_COUNTH_COUNTH(x) (((uint16_t)(((uint16_t)(x)) << SCT_COUNTH_COUNTH_SHIFT)) & SCT_COUNTH_COUNTH_MASK) /*! @} */ /*! @name COUNT - SCT counter register */ /*! @{ */ #define SCT_COUNT_CTR_L_MASK (0xFFFFU) #define SCT_COUNT_CTR_L_SHIFT (0U) /*! CTR_L - When UNIFY = 0, read or write the 16-bit L counter value. When UNIFY = 1, read or write * the lower 16 bits of the 32-bit unified counter. */ #define SCT_COUNT_CTR_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_COUNT_CTR_L_SHIFT)) & SCT_COUNT_CTR_L_MASK) #define SCT_COUNT_CTR_H_MASK (0xFFFF0000U) #define SCT_COUNT_CTR_H_SHIFT (16U) /*! CTR_H - When UNIFY = 0, read or write the 16-bit H counter value. When UNIFY = 1, read or write * the upper 16 bits of the 32-bit unified counter. */ #define SCT_COUNT_CTR_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_COUNT_CTR_H_SHIFT)) & SCT_COUNT_CTR_H_MASK) /*! @} */ /*! @name STATEL - SCT_STATEL register */ /*! @{ */ #define SCT_STATEL_STATEL_MASK (0xFFFFU) #define SCT_STATEL_STATEL_SHIFT (0U) #define SCT_STATEL_STATEL(x) (((uint16_t)(((uint16_t)(x)) << SCT_STATEL_STATEL_SHIFT)) & SCT_STATEL_STATEL_MASK) /*! @} */ /*! @name STATEH - SCT_STATEH register */ /*! @{ */ #define SCT_STATEH_STATEH_MASK (0xFFFFU) #define SCT_STATEH_STATEH_SHIFT (0U) #define SCT_STATEH_STATEH(x) (((uint16_t)(((uint16_t)(x)) << SCT_STATEH_STATEH_SHIFT)) & SCT_STATEH_STATEH_MASK) /*! @} */ /*! @name STATE - SCT state register */ /*! @{ */ #define SCT_STATE_STATE_L_MASK (0x1FU) #define SCT_STATE_STATE_L_SHIFT (0U) /*! STATE_L - State variable. */ #define SCT_STATE_STATE_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_STATE_STATE_L_SHIFT)) & SCT_STATE_STATE_L_MASK) #define SCT_STATE_STATE_H_MASK (0x1F0000U) #define SCT_STATE_STATE_H_SHIFT (16U) /*! STATE_H - State variable. */ #define SCT_STATE_STATE_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_STATE_STATE_H_SHIFT)) & SCT_STATE_STATE_H_MASK) /*! @} */ /*! @name INPUT - SCT input register */ /*! @{ */ #define SCT_INPUT_AIN0_MASK (0x1U) #define SCT_INPUT_AIN0_SHIFT (0U) /*! AIN0 - Input 0 state. Input 0 state on the last SCT clock edge. */ #define SCT_INPUT_AIN0(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_AIN0_SHIFT)) & SCT_INPUT_AIN0_MASK) #define SCT_INPUT_AIN1_MASK (0x2U) #define SCT_INPUT_AIN1_SHIFT (1U) /*! AIN1 - Input 1 state. Input 1 state on the last SCT clock edge. */ #define SCT_INPUT_AIN1(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_AIN1_SHIFT)) & SCT_INPUT_AIN1_MASK) #define SCT_INPUT_AIN2_MASK (0x4U) #define SCT_INPUT_AIN2_SHIFT (2U) /*! AIN2 - Input 2 state. Input 2 state on the last SCT clock edge. */ #define SCT_INPUT_AIN2(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_AIN2_SHIFT)) & SCT_INPUT_AIN2_MASK) #define SCT_INPUT_AIN3_MASK (0x8U) #define SCT_INPUT_AIN3_SHIFT (3U) /*! AIN3 - Input 3 state. Input 3 state on the last SCT clock edge. */ #define SCT_INPUT_AIN3(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_AIN3_SHIFT)) & SCT_INPUT_AIN3_MASK) #define SCT_INPUT_SIN0_MASK (0x10000U) #define SCT_INPUT_SIN0_SHIFT (16U) /*! SIN0 - Input 0 state. Input 0 state following the synchronization specified by INSYNC. */ #define SCT_INPUT_SIN0(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_SIN0_SHIFT)) & SCT_INPUT_SIN0_MASK) #define SCT_INPUT_SIN1_MASK (0x20000U) #define SCT_INPUT_SIN1_SHIFT (17U) /*! SIN1 - Input 1 state. Input 1 state following the synchronization specified by INSYNC. */ #define SCT_INPUT_SIN1(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_SIN1_SHIFT)) & SCT_INPUT_SIN1_MASK) #define SCT_INPUT_SIN2_MASK (0x40000U) #define SCT_INPUT_SIN2_SHIFT (18U) /*! SIN2 - Input 2 state. Input 2 state following the synchronization specified by INSYNC. */ #define SCT_INPUT_SIN2(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_SIN2_SHIFT)) & SCT_INPUT_SIN2_MASK) #define SCT_INPUT_SIN3_MASK (0x80000U) #define SCT_INPUT_SIN3_SHIFT (19U) /*! SIN3 - Input 3 state. Input 3 state following the synchronization specified by INSYNC. */ #define SCT_INPUT_SIN3(x) (((uint32_t)(((uint32_t)(x)) << SCT_INPUT_SIN3_SHIFT)) & SCT_INPUT_SIN3_MASK) /*! @} */ /*! @name REGMODEL - SCT_REGMODEL register */ /*! @{ */ #define SCT_REGMODEL_REGMODEL_MASK (0xFFFFU) #define SCT_REGMODEL_REGMODEL_SHIFT (0U) #define SCT_REGMODEL_REGMODEL(x) (((uint16_t)(((uint16_t)(x)) << SCT_REGMODEL_REGMODEL_SHIFT)) & SCT_REGMODEL_REGMODEL_MASK) /*! @} */ /*! @name REGMODEH - SCT_REGMODEH register */ /*! @{ */ #define SCT_REGMODEH_REGMODEH_MASK (0xFFFFU) #define SCT_REGMODEH_REGMODEH_SHIFT (0U) #define SCT_REGMODEH_REGMODEH(x) (((uint16_t)(((uint16_t)(x)) << SCT_REGMODEH_REGMODEH_SHIFT)) & SCT_REGMODEH_REGMODEH_MASK) /*! @} */ /*! @name REGMODE - SCT match/capture mode register */ /*! @{ */ #define SCT_REGMODE_REGMOD_L_MASK (0xFFU) #define SCT_REGMODE_REGMOD_L_SHIFT (0U) /*! REGMOD_L - Each bit controls one match/capture register (register 0 = bit 0, register 1 = bit 1, * etc.). The number of bits = number of match/captures in this SCT. 0 = register operates as * match register. 1 = register operates as capture register. */ #define SCT_REGMODE_REGMOD_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_REGMODE_REGMOD_L_SHIFT)) & SCT_REGMODE_REGMOD_L_MASK) #define SCT_REGMODE_REGMOD_H_MASK (0xFF0000U) #define SCT_REGMODE_REGMOD_H_SHIFT (16U) /*! REGMOD_H - Each bit controls one match/capture register (register 0 = bit 16, register 1 = bit * 17, etc.). The number of bits = number of match/captures in this SCT. 0 = register operates as * match registers. 1 = register operates as capture registers. */ #define SCT_REGMODE_REGMOD_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_REGMODE_REGMOD_H_SHIFT)) & SCT_REGMODE_REGMOD_H_MASK) /*! @} */ /*! @name OUTPUT - SCT output register */ /*! @{ */ #define SCT_OUTPUT_OUT_MASK (0x3FU) #define SCT_OUTPUT_OUT_SHIFT (0U) /*! OUT - Writing a 1 to bit n forces the corresponding output HIGH. Writing a 0 forces the * corresponding output LOW (output 0 = bit 0, output 1 = bit 1, etc.). The number of bits = number of * outputs in this SCT. */ #define SCT_OUTPUT_OUT(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUT_OUT_SHIFT)) & SCT_OUTPUT_OUT_MASK) /*! @} */ /*! @name OUTPUTDIRCTRL - SCT output counter direction control register */ /*! @{ */ #define SCT_OUTPUTDIRCTRL_SETCLR0_MASK (0x3U) #define SCT_OUTPUTDIRCTRL_SETCLR0_SHIFT (0U) /*! SETCLR0 - Set/clear operation on output 0. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR0(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR0_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR0_MASK) #define SCT_OUTPUTDIRCTRL_SETCLR1_MASK (0xCU) #define SCT_OUTPUTDIRCTRL_SETCLR1_SHIFT (2U) /*! SETCLR1 - Set/clear operation on output 1. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR1(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR1_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR1_MASK) #define SCT_OUTPUTDIRCTRL_SETCLR2_MASK (0x30U) #define SCT_OUTPUTDIRCTRL_SETCLR2_SHIFT (4U) /*! SETCLR2 - Set/clear operation on output 2. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR2(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR2_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR2_MASK) #define SCT_OUTPUTDIRCTRL_SETCLR3_MASK (0xC0U) #define SCT_OUTPUTDIRCTRL_SETCLR3_SHIFT (6U) /*! SETCLR3 - Set/clear operation on output 3. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR3(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR3_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR3_MASK) #define SCT_OUTPUTDIRCTRL_SETCLR4_MASK (0x300U) #define SCT_OUTPUTDIRCTRL_SETCLR4_SHIFT (8U) /*! SETCLR4 - Set/clear operation on output 4. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR4(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR4_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR4_MASK) #define SCT_OUTPUTDIRCTRL_SETCLR5_MASK (0xC00U) #define SCT_OUTPUTDIRCTRL_SETCLR5_SHIFT (10U) /*! SETCLR5 - Set/clear operation on output 5. Value 0x3 is reserved. Do not program this value. * 0b00..Set and clear do not depend on the direction of any counter. * 0b01..Set and clear are reversed when counter L or the unified counter is counting down. * 0b10..Set and clear are reversed when counter H is counting down. Do not use if UNIFY = 1. */ #define SCT_OUTPUTDIRCTRL_SETCLR5(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUTPUTDIRCTRL_SETCLR5_SHIFT)) & SCT_OUTPUTDIRCTRL_SETCLR5_MASK) /*! @} */ /*! @name RES - SCT conflict resolution register */ /*! @{ */ #define SCT_RES_O0RES_MASK (0x3U) #define SCT_RES_O0RES_SHIFT (0U) /*! O0RES - Effect of simultaneous set and clear on output 0. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR0 field in the OUTPUTDIRCTRL register). * 0b10..Clear output (or set based on the SETCLR0 field). * 0b11..Toggle output. */ #define SCT_RES_O0RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O0RES_SHIFT)) & SCT_RES_O0RES_MASK) #define SCT_RES_O1RES_MASK (0xCU) #define SCT_RES_O1RES_SHIFT (2U) /*! O1RES - Effect of simultaneous set and clear on output 1. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR1 field in the OUTPUTDIRCTRL register). * 0b10..Clear output (or set based on the SETCLR1 field). * 0b11..Toggle output. */ #define SCT_RES_O1RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O1RES_SHIFT)) & SCT_RES_O1RES_MASK) #define SCT_RES_O2RES_MASK (0x30U) #define SCT_RES_O2RES_SHIFT (4U) /*! O2RES - Effect of simultaneous set and clear on output 2. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR2 field in the OUTPUTDIRCTRL register). * 0b10..Clear output n (or set based on the SETCLR2 field). * 0b11..Toggle output. */ #define SCT_RES_O2RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O2RES_SHIFT)) & SCT_RES_O2RES_MASK) #define SCT_RES_O3RES_MASK (0xC0U) #define SCT_RES_O3RES_SHIFT (6U) /*! O3RES - Effect of simultaneous set and clear on output 3. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR3 field in the OUTPUTDIRCTRL register). * 0b10..Clear output (or set based on the SETCLR3 field). * 0b11..Toggle output. */ #define SCT_RES_O3RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O3RES_SHIFT)) & SCT_RES_O3RES_MASK) #define SCT_RES_O4RES_MASK (0x300U) #define SCT_RES_O4RES_SHIFT (8U) /*! O4RES - Effect of simultaneous set and clear on output 4. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR4 field in the OUTPUTDIRCTRL register). * 0b10..Clear output (or set based on the SETCLR4 field). * 0b11..Toggle output. */ #define SCT_RES_O4RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O4RES_SHIFT)) & SCT_RES_O4RES_MASK) #define SCT_RES_O5RES_MASK (0xC00U) #define SCT_RES_O5RES_SHIFT (10U) /*! O5RES - Effect of simultaneous set and clear on output 5. * 0b00..No change. * 0b01..Set output (or clear based on the SETCLR5 field in the OUTPUTDIRCTRL register). * 0b10..Clear output (or set based on the SETCLR5 field). * 0b11..Toggle output. */ #define SCT_RES_O5RES(x) (((uint32_t)(((uint32_t)(x)) << SCT_RES_O5RES_SHIFT)) & SCT_RES_O5RES_MASK) /*! @} */ /*! @name DMAREQ0 - SCT DMA request 0 register */ /*! @{ */ #define SCT_DMAREQ0_DEV_0_MASK (0x3FU) #define SCT_DMAREQ0_DEV_0_SHIFT (0U) /*! DEV_0 - If bit n is one, event n triggers DMA request 0 (event 0 = bit 0, event 1 = bit 1, * etc.). The number of bits = number of events in this SCT. */ #define SCT_DMAREQ0_DEV_0(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ0_DEV_0_SHIFT)) & SCT_DMAREQ0_DEV_0_MASK) #define SCT_DMAREQ0_DRL0_MASK (0x40000000U) #define SCT_DMAREQ0_DRL0_SHIFT (30U) /*! DRL0 - A 1 in this bit triggers DMA request 0 when it loads the MATCH_L/Unified registers from the RELOAD_L/Unified registers. */ #define SCT_DMAREQ0_DRL0(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ0_DRL0_SHIFT)) & SCT_DMAREQ0_DRL0_MASK) #define SCT_DMAREQ0_DRQ0_MASK (0x80000000U) #define SCT_DMAREQ0_DRQ0_SHIFT (31U) /*! DRQ0 - This read-only bit indicates the state of DMA Request 0. Note that if the related DMA * channel is enabled and properly set up, it is unlikely that software will see this flag, it will * be cleared rapidly by the DMA service. The flag remaining set could point to an issue with DMA * setup. */ #define SCT_DMAREQ0_DRQ0(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ0_DRQ0_SHIFT)) & SCT_DMAREQ0_DRQ0_MASK) /*! @} */ /*! @name DMAREQ1 - SCT DMA request 1 register */ /*! @{ */ #define SCT_DMAREQ1_DEV_1_MASK (0x3FU) #define SCT_DMAREQ1_DEV_1_SHIFT (0U) /*! DEV_1 - If bit n is one, event n triggers DMA request 1 (event 0 = bit 0, event 1 = bit 1, * etc.). The number of bits = number of events in this SCT. */ #define SCT_DMAREQ1_DEV_1(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ1_DEV_1_SHIFT)) & SCT_DMAREQ1_DEV_1_MASK) #define SCT_DMAREQ1_DRL1_MASK (0x40000000U) #define SCT_DMAREQ1_DRL1_SHIFT (30U) /*! DRL1 - A 1 in this bit triggers DMA request 1 when it loads the Match L/Unified registers from the Reload L/Unified registers. */ #define SCT_DMAREQ1_DRL1(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ1_DRL1_SHIFT)) & SCT_DMAREQ1_DRL1_MASK) #define SCT_DMAREQ1_DRQ1_MASK (0x80000000U) #define SCT_DMAREQ1_DRQ1_SHIFT (31U) /*! DRQ1 - This read-only bit indicates the state of DMA Request 1. Note that if the related DMA * channel is enabled and properly set up, it is unlikely that software will see this flag, it will * be cleared rapidly by the DMA service. The flag remaining set could point to an issue with DMA * setup. */ #define SCT_DMAREQ1_DRQ1(x) (((uint32_t)(((uint32_t)(x)) << SCT_DMAREQ1_DRQ1_SHIFT)) & SCT_DMAREQ1_DRQ1_MASK) /*! @} */ /*! @name EVEN - SCT event interrupt enable register */ /*! @{ */ #define SCT_EVEN_IEN_MASK (0xFFU) #define SCT_EVEN_IEN_SHIFT (0U) /*! IEN - The SCT requests an interrupt when bit n of this register and the event flag register are * both one (event 0 = bit 0, event 1 = bit 1, etc.). The number of bits = number of events in * this SCT. */ #define SCT_EVEN_IEN(x) (((uint32_t)(((uint32_t)(x)) << SCT_EVEN_IEN_SHIFT)) & SCT_EVEN_IEN_MASK) /*! @} */ /*! @name EVFLAG - SCT event flag register */ /*! @{ */ #define SCT_EVFLAG_FLAG_MASK (0xFFU) #define SCT_EVFLAG_FLAG_SHIFT (0U) /*! FLAG - Bit n is one if event n has occurred since reset or a 1 was last written to this bit * (event 0 = bit 0, event 1 = bit 1, etc.). The number of bits = number of events in this SCT. */ #define SCT_EVFLAG_FLAG(x) (((uint32_t)(((uint32_t)(x)) << SCT_EVFLAG_FLAG_SHIFT)) & SCT_EVFLAG_FLAG_MASK) /*! @} */ /*! @name CONEN - SCT conflict interrupt enable register */ /*! @{ */ #define SCT_CONEN_NCEN_MASK (0x3FU) #define SCT_CONEN_NCEN_SHIFT (0U) /*! NCEN - The SCT requests an interrupt when bit n of this register and the SCT conflict flag * register are both one (output 0 = bit 0, output 1 = bit 1, etc.). The number of bits = number of * outputs in this SCT. */ #define SCT_CONEN_NCEN(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONEN_NCEN_SHIFT)) & SCT_CONEN_NCEN_MASK) /*! @} */ /*! @name CONFLAG - SCT conflict flag register */ /*! @{ */ #define SCT_CONFLAG_NCFLAG_MASK (0x3FU) #define SCT_CONFLAG_NCFLAG_SHIFT (0U) /*! NCFLAG - Bit n is one if a no-change conflict event occurred on output n since reset or a 1 was * last written to this bit (output 0 = bit 0, output 1 = bit 1, etc.). The number of bits = * number of outputs in this SCT. */ #define SCT_CONFLAG_NCFLAG(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFLAG_NCFLAG_SHIFT)) & SCT_CONFLAG_NCFLAG_MASK) #define SCT_CONFLAG_BUSERRL_MASK (0x40000000U) #define SCT_CONFLAG_BUSERRL_SHIFT (30U) /*! BUSERRL - The most recent bus error from this SCT involved writing CTR L/Unified, STATE * L/Unified, MATCH L/Unified, or the Output register when the L/U counter was not halted. A word write * to certain L and H registers can be half successful and half unsuccessful. */ #define SCT_CONFLAG_BUSERRL(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFLAG_BUSERRL_SHIFT)) & SCT_CONFLAG_BUSERRL_MASK) #define SCT_CONFLAG_BUSERRH_MASK (0x80000000U) #define SCT_CONFLAG_BUSERRH_SHIFT (31U) /*! BUSERRH - The most recent bus error from this SCT involved writing CTR H, STATE H, MATCH H, or * the Output register when the H counter was not halted. */ #define SCT_CONFLAG_BUSERRH(x) (((uint32_t)(((uint32_t)(x)) << SCT_CONFLAG_BUSERRH_SHIFT)) & SCT_CONFLAG_BUSERRH_MASK) /*! @} */ /*! @name CAPL - SCT_CAPL register */ /*! @{ */ #define SCT_CAPL_CAPL_MASK (0xFFFFU) #define SCT_CAPL_CAPL_SHIFT (0U) #define SCT_CAPL_CAPL(x) (((uint16_t)(((uint16_t)(x)) << SCT_CAPL_CAPL_SHIFT)) & SCT_CAPL_CAPL_MASK) /*! @} */ /* The count of SCT_CAPL */ #define SCT_CAPL_COUNT (8U) /*! @name CAPH - SCT_CAPH register */ /*! @{ */ #define SCT_CAPH_CAPH_MASK (0xFFFFU) #define SCT_CAPH_CAPH_SHIFT (0U) #define SCT_CAPH_CAPH(x) (((uint16_t)(((uint16_t)(x)) << SCT_CAPH_CAPH_SHIFT)) & SCT_CAPH_CAPH_MASK) /*! @} */ /* The count of SCT_CAPH */ #define SCT_CAPH_COUNT (8U) /*! @name CAP - SCT capture register of capture channel */ /*! @{ */ #define SCT_CAP_CAPn_L_MASK (0xFFFFU) #define SCT_CAP_CAPn_L_SHIFT (0U) /*! CAPn_L - When UNIFY = 0, read the 16-bit counter value at which this register was last captured. * When UNIFY = 1, read the lower 16 bits of the 32-bit value at which this register was last * captured. */ #define SCT_CAP_CAPn_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CAP_CAPn_L_SHIFT)) & SCT_CAP_CAPn_L_MASK) #define SCT_CAP_CAPn_H_MASK (0xFFFF0000U) #define SCT_CAP_CAPn_H_SHIFT (16U) /*! CAPn_H - When UNIFY = 0, read the 16-bit counter value at which this register was last captured. * When UNIFY = 1, read the upper 16 bits of the 32-bit value at which this register was last * captured. */ #define SCT_CAP_CAPn_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CAP_CAPn_H_SHIFT)) & SCT_CAP_CAPn_H_MASK) /*! @} */ /* The count of SCT_CAP */ #define SCT_CAP_COUNT (8U) /*! @name MATCHL - SCT_MATCHL register */ /*! @{ */ #define SCT_MATCHL_MATCHL_MASK (0xFFFFU) #define SCT_MATCHL_MATCHL_SHIFT (0U) #define SCT_MATCHL_MATCHL(x) (((uint16_t)(((uint16_t)(x)) << SCT_MATCHL_MATCHL_SHIFT)) & SCT_MATCHL_MATCHL_MASK) /*! @} */ /* The count of SCT_MATCHL */ #define SCT_MATCHL_COUNT (8U) /*! @name MATCHH - SCT_MATCHH register */ /*! @{ */ #define SCT_MATCHH_MATCHH_MASK (0xFFFFU) #define SCT_MATCHH_MATCHH_SHIFT (0U) #define SCT_MATCHH_MATCHH(x) (((uint16_t)(((uint16_t)(x)) << SCT_MATCHH_MATCHH_SHIFT)) & SCT_MATCHH_MATCHH_MASK) /*! @} */ /* The count of SCT_MATCHH */ #define SCT_MATCHH_COUNT (8U) /*! @name MATCH - SCT match value register of match channels */ /*! @{ */ #define SCT_MATCH_MATCHn_L_MASK (0xFFFFU) #define SCT_MATCH_MATCHn_L_SHIFT (0U) /*! MATCHn_L - When UNIFY = 0, read or write the 16-bit value to be compared to the L counter. When * UNIFY = 1, read or write the lower 16 bits of the 32-bit value to be compared to the unified * counter. */ #define SCT_MATCH_MATCHn_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_MATCH_MATCHn_L_SHIFT)) & SCT_MATCH_MATCHn_L_MASK) #define SCT_MATCH_MATCHn_H_MASK (0xFFFF0000U) #define SCT_MATCH_MATCHn_H_SHIFT (16U) /*! MATCHn_H - When UNIFY = 0, read or write the 16-bit value to be compared to the H counter. When * UNIFY = 1, read or write the upper 16 bits of the 32-bit value to be compared to the unified * counter. */ #define SCT_MATCH_MATCHn_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_MATCH_MATCHn_H_SHIFT)) & SCT_MATCH_MATCHn_H_MASK) /*! @} */ /* The count of SCT_MATCH */ #define SCT_MATCH_COUNT (8U) /*! @name CAPCTRLL - SCT_CAPCTRLL register */ /*! @{ */ #define SCT_CAPCTRLL_CAPCTRLL_MASK (0xFFFFU) #define SCT_CAPCTRLL_CAPCTRLL_SHIFT (0U) #define SCT_CAPCTRLL_CAPCTRLL(x) (((uint16_t)(((uint16_t)(x)) << SCT_CAPCTRLL_CAPCTRLL_SHIFT)) & SCT_CAPCTRLL_CAPCTRLL_MASK) /*! @} */ /* The count of SCT_CAPCTRLL */ #define SCT_CAPCTRLL_COUNT (8U) /*! @name CAPCTRLH - SCT_CAPCTRLH register */ /*! @{ */ #define SCT_CAPCTRLH_CAPCTRLH_MASK (0xFFFFU) #define SCT_CAPCTRLH_CAPCTRLH_SHIFT (0U) #define SCT_CAPCTRLH_CAPCTRLH(x) (((uint16_t)(((uint16_t)(x)) << SCT_CAPCTRLH_CAPCTRLH_SHIFT)) & SCT_CAPCTRLH_CAPCTRLH_MASK) /*! @} */ /* The count of SCT_CAPCTRLH */ #define SCT_CAPCTRLH_COUNT (8U) /*! @name CAPCTRL - SCT capture control register */ /*! @{ */ #define SCT_CAPCTRL_CAPCONn_L_MASK (0xFFU) #define SCT_CAPCTRL_CAPCONn_L_SHIFT (0U) /*! CAPCONn_L - If bit m is one, event m causes the CAPn_L (UNIFY = 0) or the CAPn (UNIFY = 1) * register to be loaded (event 0 = bit 0, event 1 = bit 1, etc.). The number of bits = number of * match/captures in this SCT. */ #define SCT_CAPCTRL_CAPCONn_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_CAPCTRL_CAPCONn_L_SHIFT)) & SCT_CAPCTRL_CAPCONn_L_MASK) #define SCT_CAPCTRL_CAPCONn_H_MASK (0xFF0000U) #define SCT_CAPCTRL_CAPCONn_H_SHIFT (16U) /*! CAPCONn_H - If bit m is one, event m causes the CAPn_H (UNIFY = 0) register to be loaded (event * 0 = bit 16, event 1 = bit 17, etc.). The number of bits = number of match/captures in this SCT. */ #define SCT_CAPCTRL_CAPCONn_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_CAPCTRL_CAPCONn_H_SHIFT)) & SCT_CAPCTRL_CAPCONn_H_MASK) /*! @} */ /* The count of SCT_CAPCTRL */ #define SCT_CAPCTRL_COUNT (8U) /*! @name MATCHRELL - SCT_MATCHRELL register */ /*! @{ */ #define SCT_MATCHRELL_MATCHRELL_MASK (0xFFFFU) #define SCT_MATCHRELL_MATCHRELL_SHIFT (0U) #define SCT_MATCHRELL_MATCHRELL(x) (((uint16_t)(((uint16_t)(x)) << SCT_MATCHRELL_MATCHRELL_SHIFT)) & SCT_MATCHRELL_MATCHRELL_MASK) /*! @} */ /* The count of SCT_MATCHRELL */ #define SCT_MATCHRELL_COUNT (8U) /*! @name MATCHRELH - SCT_MATCHRELH register */ /*! @{ */ #define SCT_MATCHRELH_MATCHRELH_MASK (0xFFFFU) #define SCT_MATCHRELH_MATCHRELH_SHIFT (0U) #define SCT_MATCHRELH_MATCHRELH(x) (((uint16_t)(((uint16_t)(x)) << SCT_MATCHRELH_MATCHRELH_SHIFT)) & SCT_MATCHRELH_MATCHRELH_MASK) /*! @} */ /* The count of SCT_MATCHRELH */ #define SCT_MATCHRELH_COUNT (8U) /*! @name MATCHREL - SCT match reload value register */ /*! @{ */ #define SCT_MATCHREL_RELOADn_L_MASK (0xFFFFU) #define SCT_MATCHREL_RELOADn_L_SHIFT (0U) /*! RELOADn_L - When UNIFY = 0, specifies the 16-bit value to be loaded into the MATCHn_L register. * When UNIFY = 1, specifies the lower 16 bits of the 32-bit value to be loaded into the MATCHn * register. */ #define SCT_MATCHREL_RELOADn_L(x) (((uint32_t)(((uint32_t)(x)) << SCT_MATCHREL_RELOADn_L_SHIFT)) & SCT_MATCHREL_RELOADn_L_MASK) #define SCT_MATCHREL_RELOADn_H_MASK (0xFFFF0000U) #define SCT_MATCHREL_RELOADn_H_SHIFT (16U) /*! RELOADn_H - When UNIFY = 0, specifies the 16-bit to be loaded into the MATCHn_H register. When * UNIFY = 1, specifies the upper 16 bits of the 32-bit value to be loaded into the MATCHn * register. */ #define SCT_MATCHREL_RELOADn_H(x) (((uint32_t)(((uint32_t)(x)) << SCT_MATCHREL_RELOADn_H_SHIFT)) & SCT_MATCHREL_RELOADn_H_MASK) /*! @} */ /* The count of SCT_MATCHREL */ #define SCT_MATCHREL_COUNT (8U) /*! @name EV_STATE - SCT event state register 0 */ /*! @{ */ #define SCT_EV_STATE_STATEMSKn_MASK (0xFFU) #define SCT_EV_STATE_STATEMSKn_SHIFT (0U) /*! STATEMSKn - If bit m is one, event n happens in state m of the counter selected by the HEVENT * bit (n = event number, m = state number; state 0 = bit 0, state 1= bit 1, etc.). The number of * bits = number of states in this SCT. */ #define SCT_EV_STATE_STATEMSKn(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_STATE_STATEMSKn_SHIFT)) & SCT_EV_STATE_STATEMSKn_MASK) /*! @} */ /* The count of SCT_EV_STATE */ #define SCT_EV_STATE_COUNT (8U) /*! @name EV_CTRL - SCT event control register 0 */ /*! @{ */ #define SCT_EV_CTRL_MATCHSEL_MASK (0xFU) #define SCT_EV_CTRL_MATCHSEL_SHIFT (0U) /*! MATCHSEL - Selects the Match register associated with this event (if any). A match can occur * only when the counter selected by the HEVENT bit is running. */ #define SCT_EV_CTRL_MATCHSEL(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_MATCHSEL_SHIFT)) & SCT_EV_CTRL_MATCHSEL_MASK) #define SCT_EV_CTRL_HEVENT_MASK (0x10U) #define SCT_EV_CTRL_HEVENT_SHIFT (4U) /*! HEVENT - Select L/H counter. Do not set this bit if UNIFY = 1. * 0b0..Selects the L state and the L match register selected by MATCHSEL. * 0b1..Selects the H state and the H match register selected by MATCHSEL. */ #define SCT_EV_CTRL_HEVENT(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_HEVENT_SHIFT)) & SCT_EV_CTRL_HEVENT_MASK) #define SCT_EV_CTRL_OUTSEL_MASK (0x20U) #define SCT_EV_CTRL_OUTSEL_SHIFT (5U) /*! OUTSEL - Input/output select * 0b0..Selects the inputs selected by IOSEL. * 0b1..Selects the outputs selected by IOSEL. */ #define SCT_EV_CTRL_OUTSEL(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_OUTSEL_SHIFT)) & SCT_EV_CTRL_OUTSEL_MASK) #define SCT_EV_CTRL_IOSEL_MASK (0x3C0U) #define SCT_EV_CTRL_IOSEL_SHIFT (6U) /*! IOSEL - Selects the input or output signal number associated with this event (if any). Do not * select an input in this register if CKMODE is 1x. In this case the clock input is an implicit * ingredient of every event. */ #define SCT_EV_CTRL_IOSEL(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_IOSEL_SHIFT)) & SCT_EV_CTRL_IOSEL_MASK) #define SCT_EV_CTRL_IOCOND_MASK (0xC00U) #define SCT_EV_CTRL_IOCOND_SHIFT (10U) /*! IOCOND - Selects the I/O condition for event n. (The detection of edges on outputs lag the * conditions that switch the outputs by one SCT clock). In order to guarantee proper edge/state * detection, an input must have a minimum pulse width of at least one SCT clock period . * 0b00..LOW * 0b01..Rise * 0b10..Fall * 0b11..HIGH */ #define SCT_EV_CTRL_IOCOND(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_IOCOND_SHIFT)) & SCT_EV_CTRL_IOCOND_MASK) #define SCT_EV_CTRL_COMBMODE_MASK (0x3000U) #define SCT_EV_CTRL_COMBMODE_SHIFT (12U) /*! COMBMODE - Selects how the specified match and I/O condition are used and combined. * 0b00..OR. The event occurs when either the specified match or I/O condition occurs. * 0b01..MATCH. Uses the specified match only. * 0b10..IO. Uses the specified I/O condition only. * 0b11..AND. The event occurs when the specified match and I/O condition occur simultaneously. */ #define SCT_EV_CTRL_COMBMODE(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_COMBMODE_SHIFT)) & SCT_EV_CTRL_COMBMODE_MASK) #define SCT_EV_CTRL_STATELD_MASK (0x4000U) #define SCT_EV_CTRL_STATELD_SHIFT (14U) /*! STATELD - This bit controls how the STATEV value modifies the state selected by HEVENT when this * event is the highest-numbered event occurring for that state. * 0b0..STATEV value is added into STATE (the carry-out is ignored). * 0b1..STATEV value is loaded into STATE. */ #define SCT_EV_CTRL_STATELD(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_STATELD_SHIFT)) & SCT_EV_CTRL_STATELD_MASK) #define SCT_EV_CTRL_STATEV_MASK (0xF8000U) #define SCT_EV_CTRL_STATEV_SHIFT (15U) /*! STATEV - This value is loaded into or added to the state selected by HEVENT, depending on * STATELD, when this event is the highest-numbered event occurring for that state. If STATELD and * STATEV are both zero, there is no change to the STATE value. */ #define SCT_EV_CTRL_STATEV(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_STATEV_SHIFT)) & SCT_EV_CTRL_STATEV_MASK) #define SCT_EV_CTRL_MATCHMEM_MASK (0x100000U) #define SCT_EV_CTRL_MATCHMEM_SHIFT (20U) /*! MATCHMEM - If this bit is one and the COMBMODE field specifies a match component to the * triggering of this event, then a match is considered to be active whenever the counter value is * GREATER THAN OR EQUAL TO the value specified in the match register when counting up, LESS THEN OR * EQUAL TO the match value when counting down. If this bit is zero, a match is only be active * during the cycle when the counter is equal to the match value. */ #define SCT_EV_CTRL_MATCHMEM(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_MATCHMEM_SHIFT)) & SCT_EV_CTRL_MATCHMEM_MASK) #define SCT_EV_CTRL_DIRECTION_MASK (0x600000U) #define SCT_EV_CTRL_DIRECTION_SHIFT (21U) /*! DIRECTION - Direction qualifier for event generation. This field only applies when the counters * are operating in BIDIR mode. If BIDIR = 0, the SCT ignores this field. Value 0x3 is reserved. * 0b00..Direction independent. This event is triggered regardless of the count direction. * 0b01..Counting up. This event is triggered only during up-counting when BIDIR = 1. * 0b10..Counting down. This event is triggered only during down-counting when BIDIR = 1. */ #define SCT_EV_CTRL_DIRECTION(x) (((uint32_t)(((uint32_t)(x)) << SCT_EV_CTRL_DIRECTION_SHIFT)) & SCT_EV_CTRL_DIRECTION_MASK) /*! @} */ /* The count of SCT_EV_CTRL */ #define SCT_EV_CTRL_COUNT (8U) /*! @name OUT_SET - SCT output 0 set register */ /*! @{ */ #define SCT_OUT_SET_SET_MASK (0xFFU) #define SCT_OUT_SET_SET_SHIFT (0U) /*! SET - A 1 in bit m selects event m to set output n (or clear it if SETCLRn = 0x1 or 0x2) output * 0 = bit 0, output 1 = bit 1, etc. The number of bits = number of events in this SCT. When the * counter is used in bi-directional mode, it is possible to reverse the action specified by the * output set and clear registers when counting down, See the OUTPUTCTRL register. */ #define SCT_OUT_SET_SET(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUT_SET_SET_SHIFT)) & SCT_OUT_SET_SET_MASK) /*! @} */ /* The count of SCT_OUT_SET */ #define SCT_OUT_SET_COUNT (6U) /*! @name OUT_CLR - SCT output 0 clear register */ /*! @{ */ #define SCT_OUT_CLR_CLR_MASK (0xFFU) #define SCT_OUT_CLR_CLR_SHIFT (0U) /*! CLR - A 1 in bit m selects event m to clear output n (or set it if SETCLRn = 0x1 or 0x2) event 0 * = bit 0, event 1 = bit 1, etc. The number of bits = number of events in this SCT. When the * counter is used in bi-directional mode, it is possible to reverse the action specified by the * output set and clear registers when counting down, See the OUTPUTCTRL register. */ #define SCT_OUT_CLR_CLR(x) (((uint32_t)(((uint32_t)(x)) << SCT_OUT_CLR_CLR_SHIFT)) & SCT_OUT_CLR_CLR_MASK) /*! @} */ /* The count of SCT_OUT_CLR */ #define SCT_OUT_CLR_COUNT (6U) /*! * @} */ /* end of group SCT_Register_Masks */ /* SCT - Peripheral instance base addresses */ /** Peripheral SCT0 base address */ #define SCT0_BASE (0x50004000u) /** Peripheral SCT0 base pointer */ #define SCT0 ((SCT_Type *)SCT0_BASE) /** Array initializer of SCT peripheral base addresses */ #define SCT_BASE_ADDRS { SCT0_BASE } /** Array initializer of SCT peripheral base pointers */ #define SCT_BASE_PTRS { SCT0 } /** Interrupt vectors for the SCT peripheral type */ #define SCT_IRQS { SCT0_IRQn } /*! * @} */ /* end of group SCT_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- SPI Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup SPI_Peripheral_Access_Layer SPI Peripheral Access Layer * @{ */ /** SPI - Register Layout Typedef */ typedef struct { __IO uint32_t CFG; /**< SPI Configuration register, offset: 0x0 */ __IO uint32_t DLY; /**< SPI Delay register, offset: 0x4 */ __IO uint32_t STAT; /**< SPI Status. Some status flags can be cleared by writing a 1 to that bit position, offset: 0x8 */ __IO uint32_t INTENSET; /**< SPI Interrupt Enable read and Set. A complete value may be read from this register. Writing a 1 to any implemented bit position causes that bit to be set., offset: 0xC */ __O uint32_t INTENCLR; /**< SPI Interrupt Enable Clear. Writing a 1 to any implemented bit position causes the corresponding bit in INTENSET to be cleared., offset: 0x10 */ __I uint32_t RXDAT; /**< SPI Receive Data, offset: 0x14 */ __IO uint32_t TXDATCTL; /**< SPI Transmit Data with Control, offset: 0x18 */ __IO uint32_t TXDAT; /**< SPI Transmit Data., offset: 0x1C */ __IO uint32_t TXCTL; /**< SPI Transmit Control, offset: 0x20 */ __IO uint32_t DIV; /**< SPI clock Divider, offset: 0x24 */ __I uint32_t INTSTAT; /**< SPI Interrupt Status, offset: 0x28 */ } SPI_Type; /* ---------------------------------------------------------------------------- -- SPI Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup SPI_Register_Masks SPI Register Masks * @{ */ /*! @name CFG - SPI Configuration register */ /*! @{ */ #define SPI_CFG_ENABLE_MASK (0x1U) #define SPI_CFG_ENABLE_SHIFT (0U) /*! ENABLE - SPI enable. * 0b0..Disabled. The SPI is disabled and the internal state machine and counters are reset. * 0b1..Enabled. The SPI is enabled for operation. */ #define SPI_CFG_ENABLE(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_ENABLE_SHIFT)) & SPI_CFG_ENABLE_MASK) #define SPI_CFG_MASTER_MASK (0x4U) #define SPI_CFG_MASTER_SHIFT (2U) /*! MASTER - Master mode select. * 0b0..Slave mode. The SPI will operate in slave mode. SCK, MOSI, and the SSEL signals are inputs, MISO is an output. * 0b1..Master mode. The SPI will operate in master mode. SCK, MOSI, and the SSEL signals are outputs, MISO is an input. */ #define SPI_CFG_MASTER(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_MASTER_SHIFT)) & SPI_CFG_MASTER_MASK) #define SPI_CFG_LSBF_MASK (0x8U) #define SPI_CFG_LSBF_SHIFT (3U) /*! LSBF - LSB First mode enable. * 0b0..Standard. Data is transmitted and received in standard MSB first order. * 0b1..Reverse. Data is transmitted and received in reverse order (LSB first). */ #define SPI_CFG_LSBF(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_LSBF_SHIFT)) & SPI_CFG_LSBF_MASK) #define SPI_CFG_CPHA_MASK (0x10U) #define SPI_CFG_CPHA_SHIFT (4U) /*! CPHA - Clock Phase select. * 0b0..Change. The SPI captures serial data on the first clock transition of the transfer (when the clock * changes away from the rest state). Data is changed on the following edge. * 0b1..Capture. The SPI changes serial data on the first clock transition of the transfer (when the clock * changes away from the rest state). Data is captured on the following edge. */ #define SPI_CFG_CPHA(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_CPHA_SHIFT)) & SPI_CFG_CPHA_MASK) #define SPI_CFG_CPOL_MASK (0x20U) #define SPI_CFG_CPOL_SHIFT (5U) /*! CPOL - Clock Polarity select. * 0b0..Low. The rest state of the clock (between transfers) is low. * 0b1..High. The rest state of the clock (between transfers) is high. */ #define SPI_CFG_CPOL(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_CPOL_SHIFT)) & SPI_CFG_CPOL_MASK) #define SPI_CFG_LOOP_MASK (0x80U) #define SPI_CFG_LOOP_SHIFT (7U) /*! LOOP - Loopback mode enable. Loopback mode applies only to Master mode, and connects transmit * and receive data connected together to allow simple software testing. * 0b0..Disabled. * 0b1..Enabled. */ #define SPI_CFG_LOOP(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_LOOP_SHIFT)) & SPI_CFG_LOOP_MASK) #define SPI_CFG_SPOL0_MASK (0x100U) #define SPI_CFG_SPOL0_SHIFT (8U) /*! SPOL0 - SSEL0 Polarity select. * 0b0..Low. The SSEL0 pin is active low. * 0b1..High. The SSEL0 pin is active high. */ #define SPI_CFG_SPOL0(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_SPOL0_SHIFT)) & SPI_CFG_SPOL0_MASK) #define SPI_CFG_SPOL1_MASK (0x200U) #define SPI_CFG_SPOL1_SHIFT (9U) /*! SPOL1 - SSEL1 Polarity select. * 0b0..Low. The SSEL1 pin is active low. * 0b1..High. The SSEL1 pin is active high. */ #define SPI_CFG_SPOL1(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_SPOL1_SHIFT)) & SPI_CFG_SPOL1_MASK) #define SPI_CFG_SPOL2_MASK (0x400U) #define SPI_CFG_SPOL2_SHIFT (10U) /*! SPOL2 - SSEL2 Polarity select. * 0b0..Low. The SSEL2 pin is active low. * 0b1..High. The SSEL2 pin is active high. */ #define SPI_CFG_SPOL2(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_SPOL2_SHIFT)) & SPI_CFG_SPOL2_MASK) #define SPI_CFG_SPOL3_MASK (0x800U) #define SPI_CFG_SPOL3_SHIFT (11U) /*! SPOL3 - SSEL3 Polarity select. * 0b0..Low. The SSEL3 pin is active low. * 0b1..High. The SSEL3 pin is active high. */ #define SPI_CFG_SPOL3(x) (((uint32_t)(((uint32_t)(x)) << SPI_CFG_SPOL3_SHIFT)) & SPI_CFG_SPOL3_MASK) /*! @} */ /*! @name DLY - SPI Delay register */ /*! @{ */ #define SPI_DLY_PRE_DELAY_MASK (0xFU) #define SPI_DLY_PRE_DELAY_SHIFT (0U) /*! PRE_DELAY - Controls the amount of time between SSEL assertion and the beginning of a data * transfer. There is always one SPI clock time between SSEL assertion and the first clock edge. This * is not considered part of the pre-delay. 0x0 = No additional time is inserted. 0x1 = 1 SPI * clock time is inserted. 0x2 = 2 SPI clock times are inserted. 0xF = 15 SPI clock times are * inserted. */ #define SPI_DLY_PRE_DELAY(x) (((uint32_t)(((uint32_t)(x)) << SPI_DLY_PRE_DELAY_SHIFT)) & SPI_DLY_PRE_DELAY_MASK) #define SPI_DLY_POST_DELAY_MASK (0xF0U) #define SPI_DLY_POST_DELAY_SHIFT (4U) /*! POST_DELAY - Controls the amount of time between the end of a data transfer and SSEL * deassertion. 0x0 = No additional time is inserted. 0x1 = 1 SPI clock time is inserted. 0x2 = 2 SPI clock * times are inserted. 0xF = 15 SPI clock times are inserted. */ #define SPI_DLY_POST_DELAY(x) (((uint32_t)(((uint32_t)(x)) << SPI_DLY_POST_DELAY_SHIFT)) & SPI_DLY_POST_DELAY_MASK) #define SPI_DLY_FRAME_DELAY_MASK (0xF00U) #define SPI_DLY_FRAME_DELAY_SHIFT (8U) /*! FRAME_DELAY - If the EOF flag is set, controls the minimum amount of time between the current * frame and the next frame (or SSEL deassertion if EOT). 0x0 = No additional time is inserted. 0x1 * = 1 SPI clock time is inserted. 0x2 = 2 SPI clock times are inserted. 0xF = 15 SPI clock * times are inserted. */ #define SPI_DLY_FRAME_DELAY(x) (((uint32_t)(((uint32_t)(x)) << SPI_DLY_FRAME_DELAY_SHIFT)) & SPI_DLY_FRAME_DELAY_MASK) #define SPI_DLY_TRANSFER_DELAY_MASK (0xF000U) #define SPI_DLY_TRANSFER_DELAY_SHIFT (12U) /*! TRANSFER_DELAY - Controls the minimum amount of time that the SSEL is deasserted between * transfers. 0x0 = The minimum time that SSEL is deasserted is 1 SPI clock time. (Zero added time.) 0x1 * = The minimum time that SSEL is deasserted is 2 SPI clock times. 0x2 = The minimum time that * SSEL is deasserted is 3 SPI clock times. 0xF = The minimum time that SSEL is deasserted is 16 * SPI clock times. */ #define SPI_DLY_TRANSFER_DELAY(x) (((uint32_t)(((uint32_t)(x)) << SPI_DLY_TRANSFER_DELAY_SHIFT)) & SPI_DLY_TRANSFER_DELAY_MASK) /*! @} */ /*! @name STAT - SPI Status. Some status flags can be cleared by writing a 1 to that bit position */ /*! @{ */ #define SPI_STAT_RXRDY_MASK (0x1U) #define SPI_STAT_RXRDY_SHIFT (0U) /*! RXRDY - Receiver Ready flag. When 1, indicates that data is available to be read from the * receiver buffer. Cleared after a read of the RXDAT register. */ #define SPI_STAT_RXRDY(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_RXRDY_SHIFT)) & SPI_STAT_RXRDY_MASK) #define SPI_STAT_TXRDY_MASK (0x2U) #define SPI_STAT_TXRDY_SHIFT (1U) /*! TXRDY - Transmitter Ready flag. When 1, this bit indicates that data may be written to the * transmit buffer. Previous data may still be in the process of being transmitted. Cleared when data * is written to TXDAT or TXDATCTL until the data is moved to the transmit shift register. */ #define SPI_STAT_TXRDY(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_TXRDY_SHIFT)) & SPI_STAT_TXRDY_MASK) #define SPI_STAT_RXOV_MASK (0x4U) #define SPI_STAT_RXOV_SHIFT (2U) /*! RXOV - Receiver Overrun interrupt flag. This flag applies only to slave mode (Master = 0). This * flag is set when the beginning of a received character is detected while the receiver buffer * is still in use. If this occurs, the receiver buffer contents are preserved, and the incoming * data is lost. Data received by the SPI should be considered undefined if RxOv is set. */ #define SPI_STAT_RXOV(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_RXOV_SHIFT)) & SPI_STAT_RXOV_MASK) #define SPI_STAT_TXUR_MASK (0x8U) #define SPI_STAT_TXUR_SHIFT (3U) /*! TXUR - Transmitter Underrun interrupt flag. This flag applies only to slave mode (Master = 0). * In this case, the transmitter must begin sending new data on the next input clock if the * transmitter is idle. If that data is not available in the transmitter holding register at that * point, there is no data to transmit and the TXUR flag is set. Data transmitted by the SPI should be * considered undefined if TXUR is set. */ #define SPI_STAT_TXUR(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_TXUR_SHIFT)) & SPI_STAT_TXUR_MASK) #define SPI_STAT_SSA_MASK (0x10U) #define SPI_STAT_SSA_SHIFT (4U) /*! SSA - Slave Select Assert. This flag is set whenever any slave select transitions from * deasserted to asserted, in both master and slave modes. This allows determining when the SPI * transmit/receive functions become busy, and allows waking up the device from reduced power modes when a * slave mode access begins. This flag is cleared by software. */ #define SPI_STAT_SSA(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_SSA_SHIFT)) & SPI_STAT_SSA_MASK) #define SPI_STAT_SSD_MASK (0x20U) #define SPI_STAT_SSD_SHIFT (5U) /*! SSD - Slave Select Deassert. This flag is set whenever any asserted slave selects transition to * deasserted, in both master and slave modes. This allows determining when the SPI * transmit/receive functions become idle. This flag is cleared by software. */ #define SPI_STAT_SSD(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_SSD_SHIFT)) & SPI_STAT_SSD_MASK) #define SPI_STAT_STALLED_MASK (0x40U) #define SPI_STAT_STALLED_SHIFT (6U) /*! STALLED - Stalled status flag. This indicates whether the SPI is currently in a stall condition. */ #define SPI_STAT_STALLED(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_STALLED_SHIFT)) & SPI_STAT_STALLED_MASK) #define SPI_STAT_ENDTRANSFER_MASK (0x80U) #define SPI_STAT_ENDTRANSFER_SHIFT (7U) /*! ENDTRANSFER - End Transfer control bit. Software can set this bit to force an end to the current * transfer when the transmitter finishes any activity already in progress, as if the EOT flag * had been set prior to the last transmission. This capability is included to support cases where * it is not known when transmit data is written that it will be the end of a transfer. The bit * is cleared when the transmitter becomes idle as the transfer comes to an end. Forcing an end * of transfer in this manner causes any specified FRAME_DELAY and TRANSFER_DELAY to be inserted. */ #define SPI_STAT_ENDTRANSFER(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_ENDTRANSFER_SHIFT)) & SPI_STAT_ENDTRANSFER_MASK) #define SPI_STAT_MSTIDLE_MASK (0x100U) #define SPI_STAT_MSTIDLE_SHIFT (8U) /*! MSTIDLE - Master idle status flag. This bit is 1 whenever the SPI master function is fully idle. * This means that the transmit holding register is empty and the transmitter is not in the * process of sending data. */ #define SPI_STAT_MSTIDLE(x) (((uint32_t)(((uint32_t)(x)) << SPI_STAT_MSTIDLE_SHIFT)) & SPI_STAT_MSTIDLE_MASK) /*! @} */ /*! @name INTENSET - SPI Interrupt Enable read and Set. A complete value may be read from this register. Writing a 1 to any implemented bit position causes that bit to be set. */ /*! @{ */ #define SPI_INTENSET_RXRDYEN_MASK (0x1U) #define SPI_INTENSET_RXRDYEN_SHIFT (0U) /*! RXRDYEN - Determines whether an interrupt occurs when receiver data is available. * 0b0..No interrupt will be generated when receiver data is available. * 0b1..An interrupt will be generated when receiver data is available in the RXDAT register. */ #define SPI_INTENSET_RXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_RXRDYEN_SHIFT)) & SPI_INTENSET_RXRDYEN_MASK) #define SPI_INTENSET_TXRDYEN_MASK (0x2U) #define SPI_INTENSET_TXRDYEN_SHIFT (1U) /*! TXRDYEN - Determines whether an interrupt occurs when the transmitter holding register is available. * 0b0..No interrupt will be generated when the transmitter holding register is available. * 0b1..An interrupt will be generated when data may be written to TXDAT. */ #define SPI_INTENSET_TXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_TXRDYEN_SHIFT)) & SPI_INTENSET_TXRDYEN_MASK) #define SPI_INTENSET_RXOVEN_MASK (0x4U) #define SPI_INTENSET_RXOVEN_SHIFT (2U) /*! RXOVEN - Determines whether an interrupt occurs when a receiver overrun occurs. This happens in * slave mode when there is a need for the receiver to move newly received data to the RXDAT * register when it is already in use. The interface prevents receiver overrun in Master mode by not * allowing a new transmission to begin when a receiver overrun would otherwise occur. * 0b0..No interrupt will be generated when a receiver overrun occurs. * 0b1..An interrupt will be generated if a receiver overrun occurs. */ #define SPI_INTENSET_RXOVEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_RXOVEN_SHIFT)) & SPI_INTENSET_RXOVEN_MASK) #define SPI_INTENSET_TXUREN_MASK (0x8U) #define SPI_INTENSET_TXUREN_SHIFT (3U) /*! TXUREN - Determines whether an interrupt occurs when a transmitter underrun occurs. This happens * in slave mode when there is a need to transmit data when none is available. * 0b0..No interrupt will be generated when the transmitter underruns. * 0b1..An interrupt will be generated if the transmitter underruns. */ #define SPI_INTENSET_TXUREN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_TXUREN_SHIFT)) & SPI_INTENSET_TXUREN_MASK) #define SPI_INTENSET_SSAEN_MASK (0x10U) #define SPI_INTENSET_SSAEN_SHIFT (4U) /*! SSAEN - Determines whether an interrupt occurs when the Slave Select is asserted. * 0b0..No interrupt will be generated when any Slave Select transitions from deasserted to asserted. * 0b1..An interrupt will be generated when any Slave Select transitions from deasserted to asserted. */ #define SPI_INTENSET_SSAEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_SSAEN_SHIFT)) & SPI_INTENSET_SSAEN_MASK) #define SPI_INTENSET_SSDEN_MASK (0x20U) #define SPI_INTENSET_SSDEN_SHIFT (5U) /*! SSDEN - Determines whether an interrupt occurs when the Slave Select is deasserted. * 0b0..No interrupt will be generated when all asserted Slave Selects transition to deasserted. * 0b1..An interrupt will be generated when all asserted Slave Selects transition to deasserted. */ #define SPI_INTENSET_SSDEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_SSDEN_SHIFT)) & SPI_INTENSET_SSDEN_MASK) #define SPI_INTENSET_MSTIDLEEN_MASK (0x100U) #define SPI_INTENSET_MSTIDLEEN_SHIFT (8U) /*! MSTIDLEEN - Determines whether an interrupt occurs when the MSTIDLE enable * 0b0..No interrupt will be generated when MSTIDLE enabled. * 0b1..An interrupt will be generated when MSTIDLE enabled. */ #define SPI_INTENSET_MSTIDLEEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENSET_MSTIDLEEN_SHIFT)) & SPI_INTENSET_MSTIDLEEN_MASK) /*! @} */ /*! @name INTENCLR - SPI Interrupt Enable Clear. Writing a 1 to any implemented bit position causes the corresponding bit in INTENSET to be cleared. */ /*! @{ */ #define SPI_INTENCLR_RXRDYEN_MASK (0x1U) #define SPI_INTENCLR_RXRDYEN_SHIFT (0U) /*! RXRDYEN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_RXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_RXRDYEN_SHIFT)) & SPI_INTENCLR_RXRDYEN_MASK) #define SPI_INTENCLR_TXRDYEN_MASK (0x2U) #define SPI_INTENCLR_TXRDYEN_SHIFT (1U) /*! TXRDYEN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_TXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_TXRDYEN_SHIFT)) & SPI_INTENCLR_TXRDYEN_MASK) #define SPI_INTENCLR_RXOVEN_MASK (0x4U) #define SPI_INTENCLR_RXOVEN_SHIFT (2U) /*! RXOVEN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_RXOVEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_RXOVEN_SHIFT)) & SPI_INTENCLR_RXOVEN_MASK) #define SPI_INTENCLR_TXUREN_MASK (0x8U) #define SPI_INTENCLR_TXUREN_SHIFT (3U) /*! TXUREN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_TXUREN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_TXUREN_SHIFT)) & SPI_INTENCLR_TXUREN_MASK) #define SPI_INTENCLR_SSAEN_MASK (0x10U) #define SPI_INTENCLR_SSAEN_SHIFT (4U) /*! SSAEN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_SSAEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_SSAEN_SHIFT)) & SPI_INTENCLR_SSAEN_MASK) #define SPI_INTENCLR_SSDEN_MASK (0x20U) #define SPI_INTENCLR_SSDEN_SHIFT (5U) /*! SSDEN - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_SSDEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_SSDEN_SHIFT)) & SPI_INTENCLR_SSDEN_MASK) #define SPI_INTENCLR_MSTIDLE_MASK (0x100U) #define SPI_INTENCLR_MSTIDLE_SHIFT (8U) /*! MSTIDLE - Writing 1 clears the corresponding bits in the INTENSET register. */ #define SPI_INTENCLR_MSTIDLE(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTENCLR_MSTIDLE_SHIFT)) & SPI_INTENCLR_MSTIDLE_MASK) /*! @} */ /*! @name RXDAT - SPI Receive Data */ /*! @{ */ #define SPI_RXDAT_RXDAT_MASK (0xFFFFU) #define SPI_RXDAT_RXDAT_SHIFT (0U) /*! RXDAT - Receiver Data. This contains the next piece of received data. The number of bits that * are used depends on the LEN setting in TXCTL / TXDATCTL. */ #define SPI_RXDAT_RXDAT(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_RXDAT_SHIFT)) & SPI_RXDAT_RXDAT_MASK) #define SPI_RXDAT_RXSSEL0_N_MASK (0x10000U) #define SPI_RXDAT_RXSSEL0_N_SHIFT (16U) /*! RXSSEL0_N - Slave Select for receive. This field allows the state of the SSEL0 pin to be saved * along with received data. The value will reflect the SSEL0 pin for both master and slave * operation. A zero indicates that a slave select is active. The actual polarity of each slave select * pin is configured by the related SPOL bit in CFG. */ #define SPI_RXDAT_RXSSEL0_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_RXSSEL0_N_SHIFT)) & SPI_RXDAT_RXSSEL0_N_MASK) #define SPI_RXDAT_RXSSEL1_N_MASK (0x20000U) #define SPI_RXDAT_RXSSEL1_N_SHIFT (17U) /*! RXSSEL1_N - Slave Select for receive. This field allows the state of the SSEL1 pin to be saved * along with received data. The value will reflect the SSEL1 pin for both master and slave * operation. A zero indicates that a slave select is active. The actual polarity of each slave select * pin is configured by the related SPOL bit in CFG. */ #define SPI_RXDAT_RXSSEL1_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_RXSSEL1_N_SHIFT)) & SPI_RXDAT_RXSSEL1_N_MASK) #define SPI_RXDAT_RXSSEL2_N_MASK (0x40000U) #define SPI_RXDAT_RXSSEL2_N_SHIFT (18U) /*! RXSSEL2_N - Slave Select for receive. This field allows the state of the SSEL2 pin to be saved * along with received data. The value will reflect the SSEL2 pin for both master and slave * operation. A zero indicates that a slave select is active. The actual polarity of each slave select * pin is configured by the related SPOL bit in CFG. */ #define SPI_RXDAT_RXSSEL2_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_RXSSEL2_N_SHIFT)) & SPI_RXDAT_RXSSEL2_N_MASK) #define SPI_RXDAT_RXSSEL3_N_MASK (0x80000U) #define SPI_RXDAT_RXSSEL3_N_SHIFT (19U) /*! RXSSEL3_N - Slave Select for receive. This field allows the state of the SSEL3 pin to be saved * along with received data. The value will reflect the SSEL3 pin for both master and slave * operation. A zero indicates that a slave select is active. The actual polarity of each slave select * pin is configured by the related SPOL bit in CFG. */ #define SPI_RXDAT_RXSSEL3_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_RXSSEL3_N_SHIFT)) & SPI_RXDAT_RXSSEL3_N_MASK) #define SPI_RXDAT_SOT_MASK (0x100000U) #define SPI_RXDAT_SOT_SHIFT (20U) /*! SOT - Start of Transfer flag. This flag will be 1 if this is the first data after the SSELs went * from deasserted to asserted (i.e., any previous transfer has ended). This information can be * used to identify the first piece of data in cases where the transfer length is greater than 16 * bit. */ #define SPI_RXDAT_SOT(x) (((uint32_t)(((uint32_t)(x)) << SPI_RXDAT_SOT_SHIFT)) & SPI_RXDAT_SOT_MASK) /*! @} */ /*! @name TXDATCTL - SPI Transmit Data with Control */ /*! @{ */ #define SPI_TXDATCTL_TXDAT_MASK (0xFFFFU) #define SPI_TXDATCTL_TXDAT_SHIFT (0U) /*! TXDAT - Transmit Data. This field provides from 1 to 16 bits of data to be transmitted. */ #define SPI_TXDATCTL_TXDAT(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_TXDAT_SHIFT)) & SPI_TXDATCTL_TXDAT_MASK) #define SPI_TXDATCTL_TXSSEL0_N_MASK (0x10000U) #define SPI_TXDATCTL_TXSSEL0_N_SHIFT (16U) /*! TXSSEL0_N - Transmit Slave Select. This field asserts SSEL0 in master mode. The output on the * pin is active LOW by default. Remark: The active state of the SSEL0 pin is configured by bits in * the CFG register. * 0b0..SSEL0 asserted. * 0b1..SSEL0 not asserted. */ #define SPI_TXDATCTL_TXSSEL0_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_TXSSEL0_N_SHIFT)) & SPI_TXDATCTL_TXSSEL0_N_MASK) #define SPI_TXDATCTL_TXSSEL1_N_MASK (0x20000U) #define SPI_TXDATCTL_TXSSEL1_N_SHIFT (17U) /*! TXSSEL1_N - Transmit Slave Select. This field asserts SSEL1 in master mode. The output on the * pin is active LOW by default. Remark: The active state of the SSEL1 pin is configured by bits in * the CFG register. * 0b0..SSEL1 asserted. * 0b1..SSEL1 not asserted. */ #define SPI_TXDATCTL_TXSSEL1_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_TXSSEL1_N_SHIFT)) & SPI_TXDATCTL_TXSSEL1_N_MASK) #define SPI_TXDATCTL_TXSSEL2_N_MASK (0x40000U) #define SPI_TXDATCTL_TXSSEL2_N_SHIFT (18U) /*! TXSSEL2_N - Transmit Slave Select. This field asserts SSEL2 in master mode. The output on the * pin is active LOW by default. Remark: The active state of the SSEL2 pin is configured by bits in * the CFG register. * 0b0..SSEL2 asserted. * 0b1..SSEL2 not asserted. */ #define SPI_TXDATCTL_TXSSEL2_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_TXSSEL2_N_SHIFT)) & SPI_TXDATCTL_TXSSEL2_N_MASK) #define SPI_TXDATCTL_TXSSEL3_N_MASK (0x80000U) #define SPI_TXDATCTL_TXSSEL3_N_SHIFT (19U) /*! TXSSEL3_N - Transmit Slave Select. This field asserts SSEL3 in master mode. The output on the * pin is active LOW by default. Remark: The active state of the SSEL3 pin is configured by bits in * the CFG register. * 0b0..SSEL3 asserted. * 0b1..SSEL3 not asserted. */ #define SPI_TXDATCTL_TXSSEL3_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_TXSSEL3_N_SHIFT)) & SPI_TXDATCTL_TXSSEL3_N_MASK) #define SPI_TXDATCTL_EOT_MASK (0x100000U) #define SPI_TXDATCTL_EOT_SHIFT (20U) /*! EOT - End of Transfer. The asserted SSEL will be deasserted at the end of a transfer, and remain * so for at least the time specified by the Transfer_delay value in the DLY register. * 0b0..This piece of data is not treated as the end of a transfer. SSEL will not be deasserted at the end of this data. * 0b1..This piece of data is treated as the end of a transfer. SSEL will be deasserted at the end of this piece of data. */ #define SPI_TXDATCTL_EOT(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_EOT_SHIFT)) & SPI_TXDATCTL_EOT_MASK) #define SPI_TXDATCTL_EOF_MASK (0x200000U) #define SPI_TXDATCTL_EOF_SHIFT (21U) /*! EOF - End of Frame. Between frames, a delay may be inserted, as defined by the FRAME_DELAY value * in the DLY register. The end of a frame may not be particularly meaningful if the FRAME_DELAY * value = 0. This control can be used as part of the support for frame lengths greater than 16 * bits. * 0b0..This piece of data transmitted is not treated as the end of a frame. * 0b1..This piece of data is treated as the end of a frame, causing the FRAME_DELAY time to be inserted before subsequent data is transmitted. */ #define SPI_TXDATCTL_EOF(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_EOF_SHIFT)) & SPI_TXDATCTL_EOF_MASK) #define SPI_TXDATCTL_RXIGNORE_MASK (0x400000U) #define SPI_TXDATCTL_RXIGNORE_SHIFT (22U) /*! RXIGNORE - Receive Ignore. This allows data to be transmitted using the SPI without the need to * read unneeded data from the receiver.Setting this bit simplifies the transmit process and can * be used with the DMA. * 0b0..Received data must be read in order to allow transmission to progress. In slave mode, an overrun error * will occur if received data is not read before new data is received. * 0b1..Received data is ignored, allowing transmission without reading unneeded received data. No receiver flags are generated. */ #define SPI_TXDATCTL_RXIGNORE(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_RXIGNORE_SHIFT)) & SPI_TXDATCTL_RXIGNORE_MASK) #define SPI_TXDATCTL_LEN_MASK (0xF000000U) #define SPI_TXDATCTL_LEN_SHIFT (24U) /*! LEN - Data Length. Specifies the data length from 1 to 16 bits. Note that transfer lengths * greater than 16 bits are supported by implementing multiple sequential transmits. 0x0 = Data * transfer is 1 bit in length. 0x1 = Data transfer is 2 bits in length. 0x2 = Data transfer is 3 bits * in length. ... 0xF = Data transfer is 16 bits in length. * 0b0000.. * 0b0001..Data transfer is 1 bit in length. * 0b0010..Data transfer is 2 bit in length. * 0b0011..Data transfer is 3 bit in length. * 0b0100..Data transfer is 4 bit in length. * 0b0101..Data transfer is 5 bit in length. * 0b0110..Data transfer is 6 bit in length. * 0b0111..Data transfer is 7 bit in length. * 0b1000..Data transfer is 8 bit in length. * 0b1001..Data transfer is 9 bit in length. * 0b1010..Data transfer is 10 bit in length. * 0b1011..Data transfer is 11 bit in length. * 0b1100..Data transfer is 12 bit in length. * 0b1101..Data transfer is 13 bit in length. * 0b1110..Data transfer is 14 bit in length. * 0b1111..Data transfer is 15 bit in length. */ #define SPI_TXDATCTL_LEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDATCTL_LEN_SHIFT)) & SPI_TXDATCTL_LEN_MASK) /*! @} */ /*! @name TXDAT - SPI Transmit Data. */ /*! @{ */ #define SPI_TXDAT_DATA_MASK (0xFFFFU) #define SPI_TXDAT_DATA_SHIFT (0U) /*! DATA - Transmit Data. This field provides from 4 to 16 bits of data to be transmitted. */ #define SPI_TXDAT_DATA(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXDAT_DATA_SHIFT)) & SPI_TXDAT_DATA_MASK) /*! @} */ /*! @name TXCTL - SPI Transmit Control */ /*! @{ */ #define SPI_TXCTL_TXSSEL0_N_MASK (0x10000U) #define SPI_TXCTL_TXSSEL0_N_SHIFT (16U) /*! TXSSEL0_N - Transmit Slave Select 0. */ #define SPI_TXCTL_TXSSEL0_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_TXSSEL0_N_SHIFT)) & SPI_TXCTL_TXSSEL0_N_MASK) #define SPI_TXCTL_TXSSEL1_N_MASK (0x20000U) #define SPI_TXCTL_TXSSEL1_N_SHIFT (17U) /*! TXSSEL1_N - Transmit Slave Select 1. */ #define SPI_TXCTL_TXSSEL1_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_TXSSEL1_N_SHIFT)) & SPI_TXCTL_TXSSEL1_N_MASK) #define SPI_TXCTL_TXSSEL2_N_MASK (0x40000U) #define SPI_TXCTL_TXSSEL2_N_SHIFT (18U) /*! TXSSEL2_N - Transmit Slave Select 2. */ #define SPI_TXCTL_TXSSEL2_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_TXSSEL2_N_SHIFT)) & SPI_TXCTL_TXSSEL2_N_MASK) #define SPI_TXCTL_TXSSEL3_N_MASK (0x80000U) #define SPI_TXCTL_TXSSEL3_N_SHIFT (19U) /*! TXSSEL3_N - Transmit Slave Select 3. */ #define SPI_TXCTL_TXSSEL3_N(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_TXSSEL3_N_SHIFT)) & SPI_TXCTL_TXSSEL3_N_MASK) #define SPI_TXCTL_EOT_MASK (0x100000U) #define SPI_TXCTL_EOT_SHIFT (20U) /*! EOT - End of Transfer. */ #define SPI_TXCTL_EOT(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_EOT_SHIFT)) & SPI_TXCTL_EOT_MASK) #define SPI_TXCTL_EOF_MASK (0x200000U) #define SPI_TXCTL_EOF_SHIFT (21U) /*! EOF - End of Frame. */ #define SPI_TXCTL_EOF(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_EOF_SHIFT)) & SPI_TXCTL_EOF_MASK) #define SPI_TXCTL_RXIGNORE_MASK (0x400000U) #define SPI_TXCTL_RXIGNORE_SHIFT (22U) /*! RXIGNORE - Receive Ignore. */ #define SPI_TXCTL_RXIGNORE(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_RXIGNORE_SHIFT)) & SPI_TXCTL_RXIGNORE_MASK) #define SPI_TXCTL_LEN_MASK (0xF000000U) #define SPI_TXCTL_LEN_SHIFT (24U) /*! LEN - Data transfer Length. */ #define SPI_TXCTL_LEN(x) (((uint32_t)(((uint32_t)(x)) << SPI_TXCTL_LEN_SHIFT)) & SPI_TXCTL_LEN_MASK) /*! @} */ /*! @name DIV - SPI clock Divider */ /*! @{ */ #define SPI_DIV_DIVVAL_MASK (0xFFFFU) #define SPI_DIV_DIVVAL_SHIFT (0U) /*! DIVVAL - Rate divider value. Specifies how the Flexcomm clock (FCLK) is divided to produce the * SPI clock rate in master mode. DIVVAL is -1 encoded such that the value 0 results in FCLK/1, * the value 1 results in FCLK/2, up to the maximum possible divide value of 0xFFFF, which results * in FCLK/65536. */ #define SPI_DIV_DIVVAL(x) (((uint32_t)(((uint32_t)(x)) << SPI_DIV_DIVVAL_SHIFT)) & SPI_DIV_DIVVAL_MASK) /*! @} */ /*! @name INTSTAT - SPI Interrupt Status */ /*! @{ */ #define SPI_INTSTAT_RXRDY_MASK (0x1U) #define SPI_INTSTAT_RXRDY_SHIFT (0U) /*! RXRDY - Receiver Ready flag. */ #define SPI_INTSTAT_RXRDY(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_RXRDY_SHIFT)) & SPI_INTSTAT_RXRDY_MASK) #define SPI_INTSTAT_TXRDY_MASK (0x2U) #define SPI_INTSTAT_TXRDY_SHIFT (1U) /*! TXRDY - Transmitter Ready flag. */ #define SPI_INTSTAT_TXRDY(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_TXRDY_SHIFT)) & SPI_INTSTAT_TXRDY_MASK) #define SPI_INTSTAT_RXOV_MASK (0x4U) #define SPI_INTSTAT_RXOV_SHIFT (2U) /*! RXOV - Receiver Overrun interrupt flag. */ #define SPI_INTSTAT_RXOV(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_RXOV_SHIFT)) & SPI_INTSTAT_RXOV_MASK) #define SPI_INTSTAT_TXUR_MASK (0x8U) #define SPI_INTSTAT_TXUR_SHIFT (3U) /*! TXUR - Transmitter Underrun interrupt flag. */ #define SPI_INTSTAT_TXUR(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_TXUR_SHIFT)) & SPI_INTSTAT_TXUR_MASK) #define SPI_INTSTAT_SSA_MASK (0x10U) #define SPI_INTSTAT_SSA_SHIFT (4U) /*! SSA - Slave Select Assert. */ #define SPI_INTSTAT_SSA(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_SSA_SHIFT)) & SPI_INTSTAT_SSA_MASK) #define SPI_INTSTAT_SSD_MASK (0x20U) #define SPI_INTSTAT_SSD_SHIFT (5U) /*! SSD - Slave Select Deassert. */ #define SPI_INTSTAT_SSD(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_SSD_SHIFT)) & SPI_INTSTAT_SSD_MASK) #define SPI_INTSTAT_MSTIDLE_MASK (0x100U) #define SPI_INTSTAT_MSTIDLE_SHIFT (8U) /*! MSTIDLE - Master Idle status flag. */ #define SPI_INTSTAT_MSTIDLE(x) (((uint32_t)(((uint32_t)(x)) << SPI_INTSTAT_MSTIDLE_SHIFT)) & SPI_INTSTAT_MSTIDLE_MASK) /*! @} */ /*! * @} */ /* end of group SPI_Register_Masks */ /* SPI - Peripheral instance base addresses */ /** Peripheral SPI0 base address */ #define SPI0_BASE (0x40058000u) /** Peripheral SPI0 base pointer */ #define SPI0 ((SPI_Type *)SPI0_BASE) /** Peripheral SPI1 base address */ #define SPI1_BASE (0x4005C000u) /** Peripheral SPI1 base pointer */ #define SPI1 ((SPI_Type *)SPI1_BASE) /** Array initializer of SPI peripheral base addresses */ #define SPI_BASE_ADDRS { SPI0_BASE, SPI1_BASE } /** Array initializer of SPI peripheral base pointers */ #define SPI_BASE_PTRS { SPI0, SPI1 } /** Interrupt vectors for the SPI peripheral type */ #define SPI_IRQS { SPI0_IRQn, SPI1_IRQn } /*! * @} */ /* end of group SPI_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- SWM Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup SWM_Peripheral_Access_Layer SWM Peripheral Access Layer * @{ */ /** SWM - Register Layout Typedef */ typedef struct { union { /* offset: 0x0 */ struct { /* offset: 0x0 */ __IO uint32_t PINASSIGN0; /**< Pin assign register 0. Assign movable functions U0_TXD, U0_RXD, U0_RTS, U0_CTS., offset: 0x0 */ __IO uint32_t PINASSIGN1; /**< Pin assign register 1. Assign movable functions U0_SCLK., offset: 0x4 */ uint8_t RESERVED_0[4]; __IO uint32_t PINASSIGN3; /**< Pin assign register 3. Assign movable function U2_RTS, U2_CTS, U2_SCLK, SPI0_SCK., offset: 0xC */ __IO uint32_t PINASSIGN4; /**< Pin assign register 4. Assign movable functions SPI0_MOSI, SPI0_MISO, SPI0_SSEL0, SPI0_SSEL1., offset: 0x10 */ __IO uint32_t PINASSIGN5; /**< Pin assign register 5. Assign movable functions SPI0_SSEL2, SPI0_SSEL3, SPI1_SCK, SPI1_MOSI, offset: 0x14 */ __IO uint32_t PINASSIGN6; /**< Pin assign register 6. Assign movable functions SPI1_MISO, SPI1_SSEL0, SPI1_SSEL1, SCT0_IN0., offset: 0x18 */ __IO uint32_t PINASSIGN7; /**< Pin assign register 7. Assign movable functions SCT_IN1, SCT_IN2, SCT_IN3, SCT_OUT0., offset: 0x1C */ __IO uint32_t PINASSIGN8; /**< Pin assign register 8. Assign movable functions SCT_OUT1, SCT_OUT2, SCT_OUT3, SCT_OUT4., offset: 0x20 */ __IO uint32_t PINASSIGN9; /**< Pin assign register 9. Assign movable functions SCT_OUT5., offset: 0x24 */ __IO uint32_t PINASSIGN10; /**< Pin assign register 10. Assign movable functions, I2C2_SCL, I2C3_SDA, I2C3_SCL, ADC_PINTRIG0., offset: 0x28 */ __IO uint32_t PINASSIGN11; /**< Pin assign register 11. Assign movable functions ADC_PINTRIG1, CLKOUT, GPIO_INT_BMAT, offset: 0x2C */ } PINASSIGN; __IO uint32_t PINASSIGN_DATA[12]; /**< Pin assign register, array offset: 0x0, array step: 0x4 */ }; uint8_t RESERVED_0[400]; __IO uint32_t PINENABLE0; /**< Pin enable register 0. Enables fixed-pin functions ACMP_I0, ACMP_I1, SWCLK, SWDIO, XTALIN, XTALOUT, RESET, CLKIN, VDDCMP and so on., offset: 0x1C0 */ } SWM_Type; /* ---------------------------------------------------------------------------- -- SWM Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup SWM_Register_Masks SWM Register Masks * @{ */ /*! @name PINASSIGN0 - Pin assign register 0. Assign movable functions U0_TXD, U0_RXD, U0_RTS, U0_CTS. */ /*! @{ */ #define SWM_PINASSIGN0_U0_TXD_O_MASK (0xFFU) #define SWM_PINASSIGN0_U0_TXD_O_SHIFT (0U) /*! U0_TXD_O - U0_TXD function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0(= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN0_U0_TXD_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN0_U0_TXD_O_SHIFT)) & SWM_PINASSIGN0_U0_TXD_O_MASK) #define SWM_PINASSIGN0_U0_RXD_I_MASK (0xFF00U) #define SWM_PINASSIGN0_U0_RXD_I_SHIFT (8U) /*! U0_RXD_I - U0_RXD function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0(= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN0_U0_RXD_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN0_U0_RXD_I_SHIFT)) & SWM_PINASSIGN0_U0_RXD_I_MASK) #define SWM_PINASSIGN0_U0_RTS_O_MASK (0xFF0000U) #define SWM_PINASSIGN0_U0_RTS_O_SHIFT (16U) /*! U0_RTS_O - U0_RTS function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0(= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN0_U0_RTS_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN0_U0_RTS_O_SHIFT)) & SWM_PINASSIGN0_U0_RTS_O_MASK) #define SWM_PINASSIGN0_U0_CTS_I_MASK (0xFF000000U) #define SWM_PINASSIGN0_U0_CTS_I_SHIFT (24U) /*! U0_CTS_I - U0_CTS function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0(= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN0_U0_CTS_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN0_U0_CTS_I_SHIFT)) & SWM_PINASSIGN0_U0_CTS_I_MASK) /*! @} */ /*! @name PINASSIGN1 - Pin assign register 1. Assign movable functions U0_SCLK. */ /*! @{ */ #define SWM_PINASSIGN1_U0_SCLK_IO_MASK (0xFFU) #define SWM_PINASSIGN1_U0_SCLK_IO_SHIFT (0U) /*! U0_SCLK_IO - U0_SCLK function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN1_U0_SCLK_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN1_U0_SCLK_IO_SHIFT)) & SWM_PINASSIGN1_U0_SCLK_IO_MASK) /*! @} */ /*! @name PINASSIGN3 - Pin assign register 3. Assign movable function U2_RTS, U2_CTS, U2_SCLK, SPI0_SCK. */ /*! @{ */ #define SWM_PINASSIGN3_SPI0_SCK_IO_MASK (0xFF000000U) #define SWM_PINASSIGN3_SPI0_SCK_IO_SHIFT (24U) /*! SPI0_SCK_IO - SPI0_SCK function assignment. The value is the pin number to be assigned to this * function. The following pins are available:PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN3_SPI0_SCK_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN3_SPI0_SCK_IO_SHIFT)) & SWM_PINASSIGN3_SPI0_SCK_IO_MASK) /*! @} */ /*! @name PINASSIGN4 - Pin assign register 4. Assign movable functions SPI0_MOSI, SPI0_MISO, SPI0_SSEL0, SPI0_SSEL1. */ /*! @{ */ #define SWM_PINASSIGN4_SPI0_MOSI_IO_MASK (0xFFU) #define SWM_PINASSIGN4_SPI0_MOSI_IO_SHIFT (0U) /*! SPI0_MOSI_IO - SPI0_MOSI function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN4_SPI0_MOSI_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN4_SPI0_MOSI_IO_SHIFT)) & SWM_PINASSIGN4_SPI0_MOSI_IO_MASK) #define SWM_PINASSIGN4_SPI0_MISO_IO_MASK (0xFF00U) #define SWM_PINASSIGN4_SPI0_MISO_IO_SHIFT (8U) /*! SPI0_MISO_IO - SPI0_MISIO function assignment. The value is the pin number to be assigned to * this function. The following pins are available:PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN4_SPI0_MISO_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN4_SPI0_MISO_IO_SHIFT)) & SWM_PINASSIGN4_SPI0_MISO_IO_MASK) #define SWM_PINASSIGN4_SPI0_SSEL0_IO_MASK (0xFF0000U) #define SWM_PINASSIGN4_SPI0_SSEL0_IO_SHIFT (16U) /*! SPI0_SSEL0_IO - SPI0_SSEL0 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN4_SPI0_SSEL0_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN4_SPI0_SSEL0_IO_SHIFT)) & SWM_PINASSIGN4_SPI0_SSEL0_IO_MASK) #define SWM_PINASSIGN4_SPI0_SSEL1_IO_MASK (0xFF000000U) #define SWM_PINASSIGN4_SPI0_SSEL1_IO_SHIFT (24U) /*! SPI0_SSEL1_IO - SPI0_SSEL1 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN4_SPI0_SSEL1_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN4_SPI0_SSEL1_IO_SHIFT)) & SWM_PINASSIGN4_SPI0_SSEL1_IO_MASK) /*! @} */ /*! @name PINASSIGN5 - Pin assign register 5. Assign movable functions SPI0_SSEL2, SPI0_SSEL3, SPI1_SCK, SPI1_MOSI */ /*! @{ */ #define SWM_PINASSIGN5_SPI0_SSEL2_IO_MASK (0xFFU) #define SWM_PINASSIGN5_SPI0_SSEL2_IO_SHIFT (0U) /*! SPI0_SSEL2_IO - SPI0_SSEL2 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN5_SPI0_SSEL2_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN5_SPI0_SSEL2_IO_SHIFT)) & SWM_PINASSIGN5_SPI0_SSEL2_IO_MASK) #define SWM_PINASSIGN5_SPI0_SSEL3_IO_MASK (0xFF00U) #define SWM_PINASSIGN5_SPI0_SSEL3_IO_SHIFT (8U) /*! SPI0_SSEL3_IO - SPI0_SSEL3 function assignment. The value is the pin number to be assigned to * this function. The following pins are available:PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN5_SPI0_SSEL3_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN5_SPI0_SSEL3_IO_SHIFT)) & SWM_PINASSIGN5_SPI0_SSEL3_IO_MASK) #define SWM_PINASSIGN5_SPI1_SCK_IO_MASK (0xFF0000U) #define SWM_PINASSIGN5_SPI1_SCK_IO_SHIFT (16U) /*! SPI1_SCK_IO - SPI1_SCK function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN5_SPI1_SCK_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN5_SPI1_SCK_IO_SHIFT)) & SWM_PINASSIGN5_SPI1_SCK_IO_MASK) #define SWM_PINASSIGN5_SPI1_MOSI_IO_MASK (0xFF000000U) #define SWM_PINASSIGN5_SPI1_MOSI_IO_SHIFT (24U) /*! SPI1_MOSI_IO - SPI1_MOSI function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN5_SPI1_MOSI_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN5_SPI1_MOSI_IO_SHIFT)) & SWM_PINASSIGN5_SPI1_MOSI_IO_MASK) /*! @} */ /*! @name PINASSIGN6 - Pin assign register 6. Assign movable functions SPI1_MISO, SPI1_SSEL0, SPI1_SSEL1, SCT0_IN0. */ /*! @{ */ #define SWM_PINASSIGN6_SPI1_MISO_IO_MASK (0xFFU) #define SWM_PINASSIGN6_SPI1_MISO_IO_SHIFT (0U) /*! SPI1_MISO_IO - SPI1_MISO function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN6_SPI1_MISO_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN6_SPI1_MISO_IO_SHIFT)) & SWM_PINASSIGN6_SPI1_MISO_IO_MASK) #define SWM_PINASSIGN6_SPI1_SSEL0_IO_MASK (0xFF00U) #define SWM_PINASSIGN6_SPI1_SSEL0_IO_SHIFT (8U) /*! SPI1_SSEL0_IO - SPI1_SSEL0 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN6_SPI1_SSEL0_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN6_SPI1_SSEL0_IO_SHIFT)) & SWM_PINASSIGN6_SPI1_SSEL0_IO_MASK) #define SWM_PINASSIGN6_SPI1_SSEL1_IO_MASK (0xFF0000U) #define SWM_PINASSIGN6_SPI1_SSEL1_IO_SHIFT (16U) /*! SPI1_SSEL1_IO - SPI1_SSEL1 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN6_SPI1_SSEL1_IO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN6_SPI1_SSEL1_IO_SHIFT)) & SWM_PINASSIGN6_SPI1_SSEL1_IO_MASK) #define SWM_PINASSIGN6_SCT_PIN0_I_MASK (0xFF000000U) #define SWM_PINASSIGN6_SCT_PIN0_I_SHIFT (24U) /*! SCT_PIN0_I - SCT_PIN0 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN6_SCT_PIN0_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN6_SCT_PIN0_I_SHIFT)) & SWM_PINASSIGN6_SCT_PIN0_I_MASK) /*! @} */ /*! @name PINASSIGN7 - Pin assign register 7. Assign movable functions SCT_IN1, SCT_IN2, SCT_IN3, SCT_OUT0. */ /*! @{ */ #define SWM_PINASSIGN7_SCT_PIN1_I_MASK (0xFFU) #define SWM_PINASSIGN7_SCT_PIN1_I_SHIFT (0U) /*! SCT_PIN1_I - SCT_PIN1 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN7_SCT_PIN1_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN7_SCT_PIN1_I_SHIFT)) & SWM_PINASSIGN7_SCT_PIN1_I_MASK) #define SWM_PINASSIGN7_SCT_PIN2_I_MASK (0xFF00U) #define SWM_PINASSIGN7_SCT_PIN2_I_SHIFT (8U) /*! SCT_PIN2_I - SCT_PIN2 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN7_SCT_PIN2_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN7_SCT_PIN2_I_SHIFT)) & SWM_PINASSIGN7_SCT_PIN2_I_MASK) #define SWM_PINASSIGN7_SCT_PIN3_I_MASK (0xFF0000U) #define SWM_PINASSIGN7_SCT_PIN3_I_SHIFT (16U) /*! SCT_PIN3_I - SCT_PIN3 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN7_SCT_PIN3_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN7_SCT_PIN3_I_SHIFT)) & SWM_PINASSIGN7_SCT_PIN3_I_MASK) #define SWM_PINASSIGN7_SCT_OUT0_O_MASK (0xFF000000U) #define SWM_PINASSIGN7_SCT_OUT0_O_SHIFT (24U) /*! SCT_OUT0_O - SCT_OUT0 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN7_SCT_OUT0_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN7_SCT_OUT0_O_SHIFT)) & SWM_PINASSIGN7_SCT_OUT0_O_MASK) /*! @} */ /*! @name PINASSIGN8 - Pin assign register 8. Assign movable functions SCT_OUT1, SCT_OUT2, SCT_OUT3, SCT_OUT4. */ /*! @{ */ #define SWM_PINASSIGN8_SCT_OUT1_O_MASK (0xFFU) #define SWM_PINASSIGN8_SCT_OUT1_O_SHIFT (0U) /*! SCT_OUT1_O - SCT_OUT1 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN8_SCT_OUT1_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN8_SCT_OUT1_O_SHIFT)) & SWM_PINASSIGN8_SCT_OUT1_O_MASK) #define SWM_PINASSIGN8_SCT_OUT2_O_MASK (0xFF00U) #define SWM_PINASSIGN8_SCT_OUT2_O_SHIFT (8U) /*! SCT_OUT2_O - SCT_OUT2 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN8_SCT_OUT2_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN8_SCT_OUT2_O_SHIFT)) & SWM_PINASSIGN8_SCT_OUT2_O_MASK) #define SWM_PINASSIGN8_SCT_OUT3_O_MASK (0xFF0000U) #define SWM_PINASSIGN8_SCT_OUT3_O_SHIFT (16U) /*! SCT_OUT3_O - SCT_OUT3 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN8_SCT_OUT3_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN8_SCT_OUT3_O_SHIFT)) & SWM_PINASSIGN8_SCT_OUT3_O_MASK) #define SWM_PINASSIGN8_SCT_OUT4_O_MASK (0xFF000000U) #define SWM_PINASSIGN8_SCT_OUT4_O_SHIFT (24U) /*! SCT_OUT4_O - SCT_OUT4 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN8_SCT_OUT4_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN8_SCT_OUT4_O_SHIFT)) & SWM_PINASSIGN8_SCT_OUT4_O_MASK) /*! @} */ /*! @name PINASSIGN9 - Pin assign register 9. Assign movable functions SCT_OUT5. */ /*! @{ */ #define SWM_PINASSIGN9_SCT_OUT5_O_MASK (0xFFU) #define SWM_PINASSIGN9_SCT_OUT5_O_SHIFT (0U) /*! SCT_OUT5_O - SCT_OUT5 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN9_SCT_OUT5_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN9_SCT_OUT5_O_SHIFT)) & SWM_PINASSIGN9_SCT_OUT5_O_MASK) /*! @} */ /*! @name PINASSIGN10 - Pin assign register 10. Assign movable functions, I2C2_SCL, I2C3_SDA, I2C3_SCL, ADC_PINTRIG0. */ /*! @{ */ #define SWM_PINASSIGN10_ADC_PINTRIG0_I_MASK (0xFF000000U) #define SWM_PINASSIGN10_ADC_PINTRIG0_I_SHIFT (24U) /*! ADC_PINTRIG0_I - ADC_PINTRIG0 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN10_ADC_PINTRIG0_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN10_ADC_PINTRIG0_I_SHIFT)) & SWM_PINASSIGN10_ADC_PINTRIG0_I_MASK) /*! @} */ /*! @name PINASSIGN11 - Pin assign register 11. Assign movable functions ADC_PINTRIG1, CLKOUT, GPIO_INT_BMAT */ /*! @{ */ #define SWM_PINASSIGN11_ADC_PINTRIG1_I_MASK (0xFFU) #define SWM_PINASSIGN11_ADC_PINTRIG1_I_SHIFT (0U) /*! ADC_PINTRIG1_I - ADC_PINTRIG1 function assignment. The value is the pin number to be assigned to * this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN11_ADC_PINTRIG1_I(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN11_ADC_PINTRIG1_I_SHIFT)) & SWM_PINASSIGN11_ADC_PINTRIG1_I_MASK) #define SWM_PINASSIGN11_CLKOUT_O_MASK (0xFF0000U) #define SWM_PINASSIGN11_CLKOUT_O_SHIFT (16U) /*! CLKOUT_O - CLKOUT function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN11_CLKOUT_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN11_CLKOUT_O_SHIFT)) & SWM_PINASSIGN11_CLKOUT_O_MASK) #define SWM_PINASSIGN11_GPIO_INT_BMAT_O_MASK (0xFF000000U) #define SWM_PINASSIGN11_GPIO_INT_BMAT_O_SHIFT (24U) /*! GPIO_INT_BMAT_O - GPIO_INT_BMAT function assignment. The value is the pin number to be assigned * to this function. The following pins are available: PIO0_0 (= 0) to PIO0_28 (= 0x1C). */ #define SWM_PINASSIGN11_GPIO_INT_BMAT_O(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN11_GPIO_INT_BMAT_O_SHIFT)) & SWM_PINASSIGN11_GPIO_INT_BMAT_O_MASK) /*! @} */ /*! @name PINASSIGN_DATA - Pin assign register */ /*! @{ */ #define SWM_PINASSIGN_DATA_T0_MAT3_MASK (0xFFU) #define SWM_PINASSIGN_DATA_T0_MAT3_SHIFT (0U) /*! T0_MAT3 - T0_MAT3 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_31 (= 0x1F) and from PIO1_0 (=0x20) * to PIO1_21(=0x35). */ #define SWM_PINASSIGN_DATA_T0_MAT3(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN_DATA_T0_MAT3_SHIFT)) & SWM_PINASSIGN_DATA_T0_MAT3_MASK) #define SWM_PINASSIGN_DATA_T0_CAP0_MASK (0xFF00U) #define SWM_PINASSIGN_DATA_T0_CAP0_SHIFT (8U) /*! T0_CAP0 - T0_CAP0 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_31 (= 0x1F) and from PIO1_0 (=0x20) * to PIO1_21(=0x35). */ #define SWM_PINASSIGN_DATA_T0_CAP0(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN_DATA_T0_CAP0_SHIFT)) & SWM_PINASSIGN_DATA_T0_CAP0_MASK) #define SWM_PINASSIGN_DATA_T0_CAP1_MASK (0xFF0000U) #define SWM_PINASSIGN_DATA_T0_CAP1_SHIFT (16U) /*! T0_CAP1 - T0_CAP1 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_31 (= 0x1F) and from PIO1_0 (=0x20) * to PIO1_21(=0x35). */ #define SWM_PINASSIGN_DATA_T0_CAP1(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN_DATA_T0_CAP1_SHIFT)) & SWM_PINASSIGN_DATA_T0_CAP1_MASK) #define SWM_PINASSIGN_DATA_T0_CAP2_MASK (0xFF000000U) #define SWM_PINASSIGN_DATA_T0_CAP2_SHIFT (24U) /*! T0_CAP2 - T0_CAP2 function assignment. The value is the pin number to be assigned to this * function. The following pins are available: PIO0_0 (= 0) to PIO0_31 (= 0x1F) and from PIO1_0 (=0x20) * to PIO1_21(=0x35). */ #define SWM_PINASSIGN_DATA_T0_CAP2(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINASSIGN_DATA_T0_CAP2_SHIFT)) & SWM_PINASSIGN_DATA_T0_CAP2_MASK) /*! @} */ /* The count of SWM_PINASSIGN_DATA */ #define SWM_PINASSIGN_DATA_COUNT (12U) /*! @name PINENABLE0 - Pin enable register 0. Enables fixed-pin functions ACMP_I0, ACMP_I1, SWCLK, SWDIO, XTALIN, XTALOUT, RESET, CLKIN, VDDCMP and so on. */ /*! @{ */ #define SWM_PINENABLE0_SWCLK_MASK (0x10U) #define SWM_PINENABLE0_SWCLK_SHIFT (4U) /*! SWCLK - SWCLK function select. * 0b0..SWCLK enabled on pin PIO0_3. * 0b1..SWCLK disabled. */ #define SWM_PINENABLE0_SWCLK(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_SWCLK_SHIFT)) & SWM_PINENABLE0_SWCLK_MASK) #define SWM_PINENABLE0_SWDIO_MASK (0x20U) #define SWM_PINENABLE0_SWDIO_SHIFT (5U) /*! SWDIO - SWDIO function select. * 0b0..SWDIO enabled on pin PIO0_2. * 0b1..SWDIO disabled. */ #define SWM_PINENABLE0_SWDIO(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_SWDIO_SHIFT)) & SWM_PINENABLE0_SWDIO_MASK) #define SWM_PINENABLE0_XTALIN_MASK (0x40U) #define SWM_PINENABLE0_XTALIN_SHIFT (6U) /*! XTALIN - XTALIN function select. * 0b0..XTALIN enabled on pin PIO0_8. * 0b1..XTALIN disabled. */ #define SWM_PINENABLE0_XTALIN(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_XTALIN_SHIFT)) & SWM_PINENABLE0_XTALIN_MASK) #define SWM_PINENABLE0_XTALOUT_MASK (0x80U) #define SWM_PINENABLE0_XTALOUT_SHIFT (7U) /*! XTALOUT - XTALOUT function select. * 0b0..XTALOUT enabled on pin PIO0_9. * 0b1..XTALOUT disabled. */ #define SWM_PINENABLE0_XTALOUT(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_XTALOUT_SHIFT)) & SWM_PINENABLE0_XTALOUT_MASK) #define SWM_PINENABLE0_RESETN_MASK (0x100U) #define SWM_PINENABLE0_RESETN_SHIFT (8U) /*! RESETN - RESETN function select. * 0b0..RESETN enabled on pin PIO0_5. * 0b1..RESETN disabled. */ #define SWM_PINENABLE0_RESETN(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_RESETN_SHIFT)) & SWM_PINENABLE0_RESETN_MASK) #define SWM_PINENABLE0_CLKIN_MASK (0x200U) #define SWM_PINENABLE0_CLKIN_SHIFT (9U) /*! CLKIN - CLKIN function select. * 0b0..CLKIN enabled on pin PIO0_1. * 0b1..CLKIN disabled. */ #define SWM_PINENABLE0_CLKIN(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_CLKIN_SHIFT)) & SWM_PINENABLE0_CLKIN_MASK) #define SWM_PINENABLE0_I2C0_SDA_MASK (0x800U) #define SWM_PINENABLE0_I2C0_SDA_SHIFT (11U) /*! I2C0_SDA - I2C0_SDA function select. * 0b0..I2C0_SDA enabled on pin PIO0_11. * 0b1..I2C0_SDA disabled. */ #define SWM_PINENABLE0_I2C0_SDA(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_I2C0_SDA_SHIFT)) & SWM_PINENABLE0_I2C0_SDA_MASK) #define SWM_PINENABLE0_I2C0_SCL_MASK (0x1000U) #define SWM_PINENABLE0_I2C0_SCL_SHIFT (12U) /*! I2C0_SCL - I2C0_SCL function select. * 0b0..I2C0_SCL enabled on pin PIO0_10. * 0b1..I2C0_SCL disabled. */ #define SWM_PINENABLE0_I2C0_SCL(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_I2C0_SCL_SHIFT)) & SWM_PINENABLE0_I2C0_SCL_MASK) #define SWM_PINENABLE0_ADC_0_MASK (0x2000U) #define SWM_PINENABLE0_ADC_0_SHIFT (13U) /*! ADC_0 - ADC_0 function select. * 0b0..ADC_0 enabled on pin PIO0_7. * 0b1..ADC_0 disabled. */ #define SWM_PINENABLE0_ADC_0(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_0_SHIFT)) & SWM_PINENABLE0_ADC_0_MASK) #define SWM_PINENABLE0_ADC_1_MASK (0x4000U) #define SWM_PINENABLE0_ADC_1_SHIFT (14U) /*! ADC_1 - ADC_1 function select. * 0b0..ADC_1 enabled on pin PIO0_6. * 0b1..ADC_1 disabled. */ #define SWM_PINENABLE0_ADC_1(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_1_SHIFT)) & SWM_PINENABLE0_ADC_1_MASK) #define SWM_PINENABLE0_ADC_2_MASK (0x8000U) #define SWM_PINENABLE0_ADC_2_SHIFT (15U) /*! ADC_2 - ADC_2 function select. * 0b0..ADC_2 enabled on pin PIO0_14. * 0b1..ADC_2 disabled. */ #define SWM_PINENABLE0_ADC_2(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_2_SHIFT)) & SWM_PINENABLE0_ADC_2_MASK) #define SWM_PINENABLE0_ADC_3_MASK (0x10000U) #define SWM_PINENABLE0_ADC_3_SHIFT (16U) /*! ADC_3 - ADC_3 function select. * 0b0..ADC_3 enabled on pin PIO0_23. * 0b1..ADC_3 disabled. */ #define SWM_PINENABLE0_ADC_3(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_3_SHIFT)) & SWM_PINENABLE0_ADC_3_MASK) #define SWM_PINENABLE0_ADC_4_MASK (0x20000U) #define SWM_PINENABLE0_ADC_4_SHIFT (17U) /*! ADC_4 - ADC_4 function select. * 0b0..ADC_4 enabled on pin PIO0_22. * 0b1..ADC_4 disabled. */ #define SWM_PINENABLE0_ADC_4(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_4_SHIFT)) & SWM_PINENABLE0_ADC_4_MASK) #define SWM_PINENABLE0_ADC_5_MASK (0x40000U) #define SWM_PINENABLE0_ADC_5_SHIFT (18U) /*! ADC_5 - ADC_5 function select. * 0b0..ADC_5 enabled on pin PIO0_21. * 0b1..ADC_5 disabled. */ #define SWM_PINENABLE0_ADC_5(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_5_SHIFT)) & SWM_PINENABLE0_ADC_5_MASK) #define SWM_PINENABLE0_ADC_6_MASK (0x80000U) #define SWM_PINENABLE0_ADC_6_SHIFT (19U) /*! ADC_6 - ADC_6 function select. * 0b0..ADC_6 enabled on pin PIO0_20. * 0b1..ADC_6 disabled. */ #define SWM_PINENABLE0_ADC_6(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_6_SHIFT)) & SWM_PINENABLE0_ADC_6_MASK) #define SWM_PINENABLE0_ADC_7_MASK (0x100000U) #define SWM_PINENABLE0_ADC_7_SHIFT (20U) /*! ADC_7 - ADC_7 function select. * 0b0..ADC_7 enabled on pin PIO0_19. * 0b1..ADC_7 disabled. */ #define SWM_PINENABLE0_ADC_7(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_7_SHIFT)) & SWM_PINENABLE0_ADC_7_MASK) #define SWM_PINENABLE0_ADC_8_MASK (0x200000U) #define SWM_PINENABLE0_ADC_8_SHIFT (21U) /*! ADC_8 - ADC_8 function select. * 0b0..ADC_8 enabled on pin PIO0_18. * 0b1..ADC_8 disabled. */ #define SWM_PINENABLE0_ADC_8(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_8_SHIFT)) & SWM_PINENABLE0_ADC_8_MASK) #define SWM_PINENABLE0_ADC_9_MASK (0x400000U) #define SWM_PINENABLE0_ADC_9_SHIFT (22U) /*! ADC_9 - ADC_9 function select. * 0b0..ADC_9 enabled on pin PIO0_17. * 0b1..ADC_9 disabled. */ #define SWM_PINENABLE0_ADC_9(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_9_SHIFT)) & SWM_PINENABLE0_ADC_9_MASK) #define SWM_PINENABLE0_ADC_10_MASK (0x800000U) #define SWM_PINENABLE0_ADC_10_SHIFT (23U) /*! ADC_10 - ADC_10 function select. * 0b0..ADC_10 enabled on pin PIO0_13. * 0b1..ADC_10 disabled. */ #define SWM_PINENABLE0_ADC_10(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_10_SHIFT)) & SWM_PINENABLE0_ADC_10_MASK) #define SWM_PINENABLE0_ADC_11_MASK (0x1000000U) #define SWM_PINENABLE0_ADC_11_SHIFT (24U) /*! ADC_11 - ADC_11 function select. * 0b0..ADC_11 enabled on pin PIO0_4. * 0b1..ADC_11 disabled. */ #define SWM_PINENABLE0_ADC_11(x) (((uint32_t)(((uint32_t)(x)) << SWM_PINENABLE0_ADC_11_SHIFT)) & SWM_PINENABLE0_ADC_11_MASK) /*! @} */ /*! * @} */ /* end of group SWM_Register_Masks */ /* SWM - Peripheral instance base addresses */ /** Peripheral SWM0 base address */ #define SWM0_BASE (0x4000C000u) /** Peripheral SWM0 base pointer */ #define SWM0 ((SWM_Type *)SWM0_BASE) /** Array initializer of SWM peripheral base addresses */ #define SWM_BASE_ADDRS { SWM0_BASE } /** Array initializer of SWM peripheral base pointers */ #define SWM_BASE_PTRS { SWM0 } /*! * @} */ /* end of group SWM_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- SYSCON Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup SYSCON_Peripheral_Access_Layer SYSCON Peripheral Access Layer * @{ */ /** SYSCON - Register Layout Typedef */ typedef struct { __IO uint32_t SYSMEMREMAP; /**< System Remap register, offset: 0x0 */ __IO uint32_t PRESETCTRL; /**< Peripheral reset control register, offset: 0x4 */ __IO uint32_t SYSPLLCTRL; /**< PLL control, offset: 0x8 */ __I uint32_t SYSPLLSTAT; /**< PLL status, offset: 0xC */ uint8_t RESERVED_0[16]; __IO uint32_t SYSOSCCTRL; /**< system oscillator control, offset: 0x20 */ __IO uint32_t WDTOSCCTRL; /**< Watchdog oscillator control, offset: 0x24 */ __IO uint32_t IRCCTRL; /**< IRC control, offset: 0x28 */ uint8_t RESERVED_1[4]; __IO uint32_t SYSRSTSTAT; /**< System reset status register, offset: 0x30 */ uint8_t RESERVED_2[12]; __IO uint32_t SYSPLLCLKSEL; /**< System PLL clock source select register, offset: 0x40 */ __IO uint32_t SYSPLLCLKUEN; /**< System PLL clock source update enable register, offset: 0x44 */ uint8_t RESERVED_3[40]; __IO uint32_t MAINCLKSEL; /**< Main clock source select, offset: 0x70 */ __IO uint32_t MAINCLKUEN; /**< Main clock source update enable, offset: 0x74 */ __IO uint32_t SYSAHBCLKDIV; /**< System clock divider, offset: 0x78 */ uint8_t RESERVED_4[4]; __IO uint32_t SYSAHBCLKCTRL; /**< System clock control, offset: 0x80 */ uint8_t RESERVED_5[16]; __IO uint32_t UARTCLKDIV; /**< USART clock divider, offset: 0x94 */ uint8_t RESERVED_6[72]; __IO uint32_t CLKOUTSEL; /**< CLKOUT clock source select, offset: 0xE0 */ __IO uint32_t CLKOUTUEN; /**< CLKOUT clock source update enable, offset: 0xE4 */ __IO uint32_t CLKOUTDIV; /**< PLL control, offset: 0xE8 */ uint8_t RESERVED_7[4]; __IO uint32_t UARTFRGDIV; /**< USART1 to USART4 common fractional generator divider value, offset: 0xF0 */ __IO uint32_t UARTFRGMULT; /**< USART common fractional generator divider value, offset: 0xF4 */ uint8_t RESERVED_8[4]; __IO uint32_t EXTTRACECMD; /**< External trace buffer command register, offset: 0xFC */ __I uint32_t PIOPORCAP0; /**< POR captured PIO status 0, offset: 0x100 */ uint8_t RESERVED_9[48]; __IO uint32_t IOCONCLKDIV6; /**< Peripheral clock 6 to the IOCON block for programmable glitch filter, offset: 0x134 */ __IO uint32_t IOCONCLKDIV5; /**< Peripheral clock 6 to the IOCON block for programmable glitch filter, offset: 0x138 */ __IO uint32_t IOCONCLKDIV4; /**< Peripheral clock 4 to the IOCON block for programmable glitch filter, offset: 0x13C */ __IO uint32_t IOCONCLKDIV3; /**< Peripheral clock 3 to the IOCON block for programmable glitch filter, offset: 0x140 */ __IO uint32_t IOCONCLKDIV2; /**< Peripheral clock 2 to the IOCON block for programmable glitch filter, offset: 0x144 */ __IO uint32_t IOCONCLKDIV1; /**< Peripheral clock 1 to the IOCON block for programmable glitch filter, offset: 0x148 */ __IO uint32_t IOCONCLKDIV0; /**< Peripheral clock 0 to the IOCON block for programmable glitch filter, offset: 0x14C */ __IO uint32_t BODCTRL; /**< BOD control register, offset: 0x150 */ __IO uint32_t SYSTCKCAL; /**< System tick timer calibration register, offset: 0x154 */ uint8_t RESERVED_10[24]; __IO uint32_t IRQLATENCY; /**< IRQ latency register, offset: 0x170 */ __IO uint32_t NMISRC; /**< NMI source selection register, offset: 0x174 */ __IO uint32_t PINTSEL[8]; /**< Pin interrupt select registers N, array offset: 0x178, array step: 0x4 */ uint8_t RESERVED_11[108]; __IO uint32_t STARTERP0; /**< Start logic 0 pin wake-up enable register 0, offset: 0x204 */ uint8_t RESERVED_12[12]; __IO uint32_t STARTERP1; /**< Start logic 1 interrupt wake-up enable register, offset: 0x214 */ uint8_t RESERVED_13[24]; __IO uint32_t PDSLEEPCFG; /**< Deep-sleep configuration register, offset: 0x230 */ __IO uint32_t PDAWAKECFG; /**< Wake-up configuration register, offset: 0x234 */ __IO uint32_t PDRUNCFG; /**< Power configuration register, offset: 0x238 */ uint8_t RESERVED_14[444]; __I uint32_t DEVICE_ID; /**< Part ID register, offset: 0x3F8 */ } SYSCON_Type; /* ---------------------------------------------------------------------------- -- SYSCON Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup SYSCON_Register_Masks SYSCON Register Masks * @{ */ /*! @name SYSMEMREMAP - System Remap register */ /*! @{ */ #define SYSCON_SYSMEMREMAP_MAP_MASK (0x3U) #define SYSCON_SYSMEMREMAP_MAP_SHIFT (0U) /*! MAP - System memory remap. Value 0x3 is reserved. * 0b00..Boot Loader Mode. Interrupt vectors are re-mapped to Boot ROM. * 0b01..User RAM Mode. Interrupt vectors are re-mapped to Static RAM. * 0b10..User Flash Mode. Interrupt vectors are not re-mapped and reside in Flash. */ #define SYSCON_SYSMEMREMAP_MAP(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSMEMREMAP_MAP_SHIFT)) & SYSCON_SYSMEMREMAP_MAP_MASK) /*! @} */ /*! @name PRESETCTRL - Peripheral reset control register */ /*! @{ */ #define SYSCON_PRESETCTRL_SPI0_RST_N_MASK (0x1U) #define SYSCON_PRESETCTRL_SPI0_RST_N_SHIFT (0U) /*! SPI0_RST_N - SPI0 reset control. * 0b0..Assert the SPI0 reset. * 0b1..Clear the SPI0 reset. */ #define SYSCON_PRESETCTRL_SPI0_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_SPI0_RST_N_SHIFT)) & SYSCON_PRESETCTRL_SPI0_RST_N_MASK) #define SYSCON_PRESETCTRL_SPI1_RST_N_MASK (0x2U) #define SYSCON_PRESETCTRL_SPI1_RST_N_SHIFT (1U) /*! SPI1_RST_N - SPI1 reset control. * 0b0..Assert the SPI1 reset. * 0b1..Clear the SPI1 reset. */ #define SYSCON_PRESETCTRL_SPI1_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_SPI1_RST_N_SHIFT)) & SYSCON_PRESETCTRL_SPI1_RST_N_MASK) #define SYSCON_PRESETCTRL_UARTFRG_RST_N_MASK (0x4U) #define SYSCON_PRESETCTRL_UARTFRG_RST_N_SHIFT (2U) /*! UARTFRG_RST_N - USART fractional baud rate generator(UARTFRG) reset control. * 0b0..Assert the UARTFRG reset. * 0b1..Clear the UARTFRG reset. */ #define SYSCON_PRESETCTRL_UARTFRG_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_UARTFRG_RST_N_SHIFT)) & SYSCON_PRESETCTRL_UARTFRG_RST_N_MASK) #define SYSCON_PRESETCTRL_UART0_RST_N_MASK (0x8U) #define SYSCON_PRESETCTRL_UART0_RST_N_SHIFT (3U) /*! UART0_RST_N - USART0 reset control. * 0b0..Assert the USART0 reset. * 0b1..Clear the USART0 reset. */ #define SYSCON_PRESETCTRL_UART0_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_UART0_RST_N_SHIFT)) & SYSCON_PRESETCTRL_UART0_RST_N_MASK) #define SYSCON_PRESETCTRL_UART1_RST_N_MASK (0x10U) #define SYSCON_PRESETCTRL_UART1_RST_N_SHIFT (4U) /*! UART1_RST_N - USART1 reset control. * 0b0..Assert the USART1 reset. * 0b1..Clear the USART1 reset. */ #define SYSCON_PRESETCTRL_UART1_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_UART1_RST_N_SHIFT)) & SYSCON_PRESETCTRL_UART1_RST_N_MASK) #define SYSCON_PRESETCTRL_UART2_RST_N_MASK (0x20U) #define SYSCON_PRESETCTRL_UART2_RST_N_SHIFT (5U) /*! UART2_RST_N - USART2 reset control. * 0b0..Assert the USART2 reset. * 0b1..Clear the USART2 reset. */ #define SYSCON_PRESETCTRL_UART2_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_UART2_RST_N_SHIFT)) & SYSCON_PRESETCTRL_UART2_RST_N_MASK) #define SYSCON_PRESETCTRL_I2C0_RST_N_MASK (0x40U) #define SYSCON_PRESETCTRL_I2C0_RST_N_SHIFT (6U) /*! I2C0_RST_N - I2C0 reset control. * 0b0..Assert the I2C0 reset. * 0b1..Clear the I2C0 reset. */ #define SYSCON_PRESETCTRL_I2C0_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_I2C0_RST_N_SHIFT)) & SYSCON_PRESETCTRL_I2C0_RST_N_MASK) #define SYSCON_PRESETCTRL_MRT_RST_N_MASK (0x80U) #define SYSCON_PRESETCTRL_MRT_RST_N_SHIFT (7U) /*! MRT_RST_N - Multi-rate timer (MRT) reset control. * 0b0..Assert the MRT reset. * 0b1..Clear the MRT reset. */ #define SYSCON_PRESETCTRL_MRT_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_MRT_RST_N_SHIFT)) & SYSCON_PRESETCTRL_MRT_RST_N_MASK) #define SYSCON_PRESETCTRL_SCT_RST_N_MASK (0x100U) #define SYSCON_PRESETCTRL_SCT_RST_N_SHIFT (8U) /*! SCT_RST_N - SCT reset control. * 0b0..Assert the SCT reset. * 0b1..Clear the SCT reset. */ #define SYSCON_PRESETCTRL_SCT_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_SCT_RST_N_SHIFT)) & SYSCON_PRESETCTRL_SCT_RST_N_MASK) #define SYSCON_PRESETCTRL_WKT_RST_N_MASK (0x200U) #define SYSCON_PRESETCTRL_WKT_RST_N_SHIFT (9U) /*! WKT_RST_N - Self-wake-up timer (WKT) reset control. * 0b0..Assert the WKT reset. * 0b1..Clear the WKT reset. */ #define SYSCON_PRESETCTRL_WKT_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_WKT_RST_N_SHIFT)) & SYSCON_PRESETCTRL_WKT_RST_N_MASK) #define SYSCON_PRESETCTRL_GPIO_RST_N_MASK (0x400U) #define SYSCON_PRESETCTRL_GPIO_RST_N_SHIFT (10U) /*! GPIO_RST_N - GPIO and GPIO pin interrupt reset control. * 0b0..Assert the GPIO reset. * 0b1..Clear the GPIO reset. */ #define SYSCON_PRESETCTRL_GPIO_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_GPIO_RST_N_SHIFT)) & SYSCON_PRESETCTRL_GPIO_RST_N_MASK) #define SYSCON_PRESETCTRL_FLASH_RST_N_MASK (0x800U) #define SYSCON_PRESETCTRL_FLASH_RST_N_SHIFT (11U) /*! FLASH_RST_N - Flash controller reset control. * 0b0..Assert the flash controller reset. * 0b1..Clear the flash controller reset. */ #define SYSCON_PRESETCTRL_FLASH_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_FLASH_RST_N_SHIFT)) & SYSCON_PRESETCTRL_FLASH_RST_N_MASK) #define SYSCON_PRESETCTRL_ACMP_RST_N_MASK (0x1000U) #define SYSCON_PRESETCTRL_ACMP_RST_N_SHIFT (12U) /*! ACMP_RST_N - Analog comparator reset control. * 0b0..Assert the analog comparator reset. * 0b1..Clear the analog comparator controller reset. */ #define SYSCON_PRESETCTRL_ACMP_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_ACMP_RST_N_SHIFT)) & SYSCON_PRESETCTRL_ACMP_RST_N_MASK) #define SYSCON_PRESETCTRL_I2C1_RST_N_MASK (0x4000U) #define SYSCON_PRESETCTRL_I2C1_RST_N_SHIFT (14U) /*! I2C1_RST_N - I2C1 reset control. * 0b0..Assert the I2C1 reset. * 0b1..Clear the I2C1 reset. */ #define SYSCON_PRESETCTRL_I2C1_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_I2C1_RST_N_SHIFT)) & SYSCON_PRESETCTRL_I2C1_RST_N_MASK) #define SYSCON_PRESETCTRL_I2C2_RST_N_MASK (0x8000U) #define SYSCON_PRESETCTRL_I2C2_RST_N_SHIFT (15U) /*! I2C2_RST_N - I2C2 reset control. * 0b0..Assert the I2C2 reset. * 0b1..Clear the I2C2 reset. */ #define SYSCON_PRESETCTRL_I2C2_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_I2C2_RST_N_SHIFT)) & SYSCON_PRESETCTRL_I2C2_RST_N_MASK) #define SYSCON_PRESETCTRL_I2C3_RST_N_MASK (0x10000U) #define SYSCON_PRESETCTRL_I2C3_RST_N_SHIFT (16U) /*! I2C3_RST_N - I2C3 reset control. * 0b0..Assert the I2C3 reset. * 0b1..Clear the I2C3 reset. */ #define SYSCON_PRESETCTRL_I2C3_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_I2C3_RST_N_SHIFT)) & SYSCON_PRESETCTRL_I2C3_RST_N_MASK) #define SYSCON_PRESETCTRL_ADC_RST_N_MASK (0x1000000U) #define SYSCON_PRESETCTRL_ADC_RST_N_SHIFT (24U) /*! ADC_RST_N - ADC reset control. * 0b0..Assert the ADC reset. * 0b1..Clear the ADC reset. */ #define SYSCON_PRESETCTRL_ADC_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_ADC_RST_N_SHIFT)) & SYSCON_PRESETCTRL_ADC_RST_N_MASK) #define SYSCON_PRESETCTRL_DMA_RST_N_MASK (0x20000000U) #define SYSCON_PRESETCTRL_DMA_RST_N_SHIFT (29U) /*! DMA_RST_N - DMA reset control. * 0b0..Assert the DMA reset. * 0b1..Clear the DMA reset. */ #define SYSCON_PRESETCTRL_DMA_RST_N(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PRESETCTRL_DMA_RST_N_SHIFT)) & SYSCON_PRESETCTRL_DMA_RST_N_MASK) /*! @} */ /*! @name SYSPLLCTRL - PLL control */ /*! @{ */ #define SYSCON_SYSPLLCTRL_MSEL_MASK (0x1FU) #define SYSCON_SYSPLLCTRL_MSEL_SHIFT (0U) /*! MSEL - Feedback divider value. The division value M is the programmed MSEL value + 1. 00000: * Division ratio M = 1 to 11111: Division ratio M = 32 */ #define SYSCON_SYSPLLCTRL_MSEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSPLLCTRL_MSEL_SHIFT)) & SYSCON_SYSPLLCTRL_MSEL_MASK) #define SYSCON_SYSPLLCTRL_PSEL_MASK (0x60U) #define SYSCON_SYSPLLCTRL_PSEL_SHIFT (5U) /*! PSEL - Post divider ratio P. The division ratio is 2 x P. * 0b00..P = 1 * 0b01..P = 2 * 0b10..P = 4 * 0b11..P = 8 */ #define SYSCON_SYSPLLCTRL_PSEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSPLLCTRL_PSEL_SHIFT)) & SYSCON_SYSPLLCTRL_PSEL_MASK) /*! @} */ /*! @name SYSPLLSTAT - PLL status */ /*! @{ */ #define SYSCON_SYSPLLSTAT_LOCK_MASK (0x1U) #define SYSCON_SYSPLLSTAT_LOCK_SHIFT (0U) /*! LOCK - PLL0 lock indicator */ #define SYSCON_SYSPLLSTAT_LOCK(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSPLLSTAT_LOCK_SHIFT)) & SYSCON_SYSPLLSTAT_LOCK_MASK) /*! @} */ /*! @name SYSOSCCTRL - system oscillator control */ /*! @{ */ #define SYSCON_SYSOSCCTRL_BYPASS_MASK (0x1U) #define SYSCON_SYSOSCCTRL_BYPASS_SHIFT (0U) /*! BYPASS - Bypass system oscillator */ #define SYSCON_SYSOSCCTRL_BYPASS(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSOSCCTRL_BYPASS_SHIFT)) & SYSCON_SYSOSCCTRL_BYPASS_MASK) #define SYSCON_SYSOSCCTRL_FREQ_RANGE_MASK (0x2U) #define SYSCON_SYSOSCCTRL_FREQ_RANGE_SHIFT (1U) /*! FREQ_RANGE - oscillator low / high transconductance selection input (Active High) 1-20MHz '0' : 15-50MHz '1' */ #define SYSCON_SYSOSCCTRL_FREQ_RANGE(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSOSCCTRL_FREQ_RANGE_SHIFT)) & SYSCON_SYSOSCCTRL_FREQ_RANGE_MASK) /*! @} */ /*! @name WDTOSCCTRL - Watchdog oscillator control */ /*! @{ */ #define SYSCON_WDTOSCCTRL_DIVSEL_MASK (0x1FU) #define SYSCON_WDTOSCCTRL_DIVSEL_SHIFT (0U) /*! DIVSEL - Select divider for Fclkana. wdt_osc_clk = Fclkana/ (2 x (1 + DIVSEL)) 00000: 2 x (1 + * DIVSEL) = 2 00001: 2 x (1 + DIVSEL) = 4 to 11111: 2 x (1 + DIVSEL) = 64 */ #define SYSCON_WDTOSCCTRL_DIVSEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_WDTOSCCTRL_DIVSEL_SHIFT)) & SYSCON_WDTOSCCTRL_DIVSEL_MASK) #define SYSCON_WDTOSCCTRL_FREQSEL_MASK (0x1E0U) #define SYSCON_WDTOSCCTRL_FREQSEL_SHIFT (5U) /*! FREQSEL - Frequency select. Selects the frequency of the oscillator. 0x00 = invalid setting when * watchdog oscillator is running 0x1 = 0.6 MHz 0x2 = 1.05 MHz 0x3 = 1.4 MHz 0x4 = 1.75 MHz 0x5 * = 2.1 MHz 0x6 = 2.4 MHz 0x7 = 2.7 MHz 0x8 = 3.0 MHz 0x9 = 3.25 MHz 0xA = 3.5 MHz 0xB = 3.75 * MHz 0xC = 4.0 MHz 0xD = 4.2 MHz 0xE = 4.4 MHz 0xF = 4.6 MHz */ #define SYSCON_WDTOSCCTRL_FREQSEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_WDTOSCCTRL_FREQSEL_SHIFT)) & SYSCON_WDTOSCCTRL_FREQSEL_MASK) /*! @} */ /*! @name IRCCTRL - IRC control */ /*! @{ */ #define SYSCON_IRCCTRL_TRIM_MASK (0xFFU) #define SYSCON_IRCCTRL_TRIM_SHIFT (0U) /*! TRIM - Trim value */ #define SYSCON_IRCCTRL_TRIM(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IRCCTRL_TRIM_SHIFT)) & SYSCON_IRCCTRL_TRIM_MASK) /*! @} */ /*! @name SYSRSTSTAT - System reset status register */ /*! @{ */ #define SYSCON_SYSRSTSTAT_POR_MASK (0x1U) #define SYSCON_SYSRSTSTAT_POR_SHIFT (0U) /*! POR - POR reset status. * 0b0..No POR detected. * 0b1..POR detected. Writing a one clears this reset. */ #define SYSCON_SYSRSTSTAT_POR(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSRSTSTAT_POR_SHIFT)) & SYSCON_SYSRSTSTAT_POR_MASK) #define SYSCON_SYSRSTSTAT_EXTRST_MASK (0x2U) #define SYSCON_SYSRSTSTAT_EXTRST_SHIFT (1U) /*! EXTRST - Status of the external RESET pin. External reset status. * 0b0..No reset event detected. * 0b1..Reset detected. Writing a one clears this reset. */ #define SYSCON_SYSRSTSTAT_EXTRST(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSRSTSTAT_EXTRST_SHIFT)) & SYSCON_SYSRSTSTAT_EXTRST_MASK) #define SYSCON_SYSRSTSTAT_WDT_MASK (0x4U) #define SYSCON_SYSRSTSTAT_WDT_SHIFT (2U) /*! WDT - Status of the Watchdog reset. * 0b0..No WDT reset detected. * 0b1..WDT reset detected. Writing a one clears this reset. */ #define SYSCON_SYSRSTSTAT_WDT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSRSTSTAT_WDT_SHIFT)) & SYSCON_SYSRSTSTAT_WDT_MASK) #define SYSCON_SYSRSTSTAT_BOD_MASK (0x8U) #define SYSCON_SYSRSTSTAT_BOD_SHIFT (3U) /*! BOD - Status of the Brown-out detect reset. * 0b0..No BOD reset detected. * 0b1..BOD reset detected. Writing a one clears this reset. */ #define SYSCON_SYSRSTSTAT_BOD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSRSTSTAT_BOD_SHIFT)) & SYSCON_SYSRSTSTAT_BOD_MASK) #define SYSCON_SYSRSTSTAT_SYSRST_MASK (0x10U) #define SYSCON_SYSRSTSTAT_SYSRST_SHIFT (4U) /*! SYSRST - Status of the software system reset. * 0b0..No System reset detected. * 0b1..System reset detected. Writing a one clears this reset. */ #define SYSCON_SYSRSTSTAT_SYSRST(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSRSTSTAT_SYSRST_SHIFT)) & SYSCON_SYSRSTSTAT_SYSRST_MASK) /*! @} */ /*! @name SYSPLLCLKSEL - System PLL clock source select register */ /*! @{ */ #define SYSCON_SYSPLLCLKSEL_SEL_MASK (0x3U) #define SYSCON_SYSPLLCLKSEL_SEL_SHIFT (0U) /*! SEL - System PLL clock source * 0b00..IRC * 0b01..Crystal Oscillator (SYSOSC) * 0b10..Reserved * 0b11..CLKIN. External clock input. */ #define SYSCON_SYSPLLCLKSEL_SEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSPLLCLKSEL_SEL_SHIFT)) & SYSCON_SYSPLLCLKSEL_SEL_MASK) /*! @} */ /*! @name SYSPLLCLKUEN - System PLL clock source update enable register */ /*! @{ */ #define SYSCON_SYSPLLCLKUEN_ENA_MASK (0x1U) #define SYSCON_SYSPLLCLKUEN_ENA_SHIFT (0U) /*! ENA - Enable system PLL clock source update * 0b0..no change * 0b1..update clock source */ #define SYSCON_SYSPLLCLKUEN_ENA(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSPLLCLKUEN_ENA_SHIFT)) & SYSCON_SYSPLLCLKUEN_ENA_MASK) /*! @} */ /*! @name MAINCLKSEL - Main clock source select */ /*! @{ */ #define SYSCON_MAINCLKSEL_SEL_MASK (0x3U) #define SYSCON_MAINCLKSEL_SEL_SHIFT (0U) /*! SEL - Clock source for main clock. * 0b00..IRC Oscillator. * 0b01..PLL input. * 0b10..Watchdog oscillator. * 0b11..PLL output. */ #define SYSCON_MAINCLKSEL_SEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_MAINCLKSEL_SEL_SHIFT)) & SYSCON_MAINCLKSEL_SEL_MASK) /*! @} */ /*! @name MAINCLKUEN - Main clock source update enable */ /*! @{ */ #define SYSCON_MAINCLKUEN_ENA_MASK (0x1U) #define SYSCON_MAINCLKUEN_ENA_SHIFT (0U) /*! ENA - Enable main clock source update. * 0b0..No change. * 0b1..Update clock source. */ #define SYSCON_MAINCLKUEN_ENA(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_MAINCLKUEN_ENA_SHIFT)) & SYSCON_MAINCLKUEN_ENA_MASK) /*! @} */ /*! @name SYSAHBCLKDIV - System clock divider */ /*! @{ */ #define SYSCON_SYSAHBCLKDIV_DIV_MASK (0xFFU) #define SYSCON_SYSAHBCLKDIV_DIV_SHIFT (0U) /*! DIV - System AHB clock divider values 0: System clock disabled. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_SYSAHBCLKDIV_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKDIV_DIV_SHIFT)) & SYSCON_SYSAHBCLKDIV_DIV_MASK) /*! @} */ /*! @name SYSAHBCLKCTRL - System clock control */ /*! @{ */ #define SYSCON_SYSAHBCLKCTRL_SYS_MASK (0x1U) #define SYSCON_SYSAHBCLKCTRL_SYS_SHIFT (0U) /*! SYS - Enables the clock for the AHB, the APB bridge, the Cortex-M0+ core clocks, SYSCON, and the * PMU. This bit is read only and always reads as 1. */ #define SYSCON_SYSAHBCLKCTRL_SYS(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_SYS_SHIFT)) & SYSCON_SYSAHBCLKCTRL_SYS_MASK) #define SYSCON_SYSAHBCLKCTRL_ROM_MASK (0x2U) #define SYSCON_SYSAHBCLKCTRL_ROM_SHIFT (1U) /*! ROM - Enables clock for ROM. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_ROM(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_ROM_SHIFT)) & SYSCON_SYSAHBCLKCTRL_ROM_MASK) #define SYSCON_SYSAHBCLKCTRL_RAM0_1_MASK (0x4U) #define SYSCON_SYSAHBCLKCTRL_RAM0_1_SHIFT (2U) /*! RAM0_1 - Enables clock for SRAM0 and SRAM1. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_RAM0_1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_RAM0_1_SHIFT)) & SYSCON_SYSAHBCLKCTRL_RAM0_1_MASK) #define SYSCON_SYSAHBCLKCTRL_FLASHREG_MASK (0x8U) #define SYSCON_SYSAHBCLKCTRL_FLASHREG_SHIFT (3U) /*! FLASHREG - Enables clock for flash register interface. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_FLASHREG(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_FLASHREG_SHIFT)) & SYSCON_SYSAHBCLKCTRL_FLASHREG_MASK) #define SYSCON_SYSAHBCLKCTRL_FLASH_MASK (0x10U) #define SYSCON_SYSAHBCLKCTRL_FLASH_SHIFT (4U) /*! FLASH - Enables clock for flash. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_FLASH(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_FLASH_SHIFT)) & SYSCON_SYSAHBCLKCTRL_FLASH_MASK) #define SYSCON_SYSAHBCLKCTRL_I2C0_MASK (0x20U) #define SYSCON_SYSAHBCLKCTRL_I2C0_SHIFT (5U) /*! I2C0 - Enables clock for I2C0. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_I2C0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_I2C0_SHIFT)) & SYSCON_SYSAHBCLKCTRL_I2C0_MASK) #define SYSCON_SYSAHBCLKCTRL_GPIO_MASK (0x40U) #define SYSCON_SYSAHBCLKCTRL_GPIO_SHIFT (6U) /*! GPIO - Enables clock for GPIO port registers and GPIO pin interrupt registers. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_GPIO(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_GPIO_SHIFT)) & SYSCON_SYSAHBCLKCTRL_GPIO_MASK) #define SYSCON_SYSAHBCLKCTRL_SWM_MASK (0x80U) #define SYSCON_SYSAHBCLKCTRL_SWM_SHIFT (7U) /*! SWM - Enables clock for switch matrix. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_SWM(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_SWM_SHIFT)) & SYSCON_SYSAHBCLKCTRL_SWM_MASK) #define SYSCON_SYSAHBCLKCTRL_SCT_MASK (0x100U) #define SYSCON_SYSAHBCLKCTRL_SCT_SHIFT (8U) /*! SCT - Enables clock for state configurable timer SCTimer/PWM. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_SCT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_SCT_SHIFT)) & SYSCON_SYSAHBCLKCTRL_SCT_MASK) #define SYSCON_SYSAHBCLKCTRL_WKT_MASK (0x200U) #define SYSCON_SYSAHBCLKCTRL_WKT_SHIFT (9U) /*! WKT - Enables clock for self-wake-up timer. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_WKT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_WKT_SHIFT)) & SYSCON_SYSAHBCLKCTRL_WKT_MASK) #define SYSCON_SYSAHBCLKCTRL_MRT_MASK (0x400U) #define SYSCON_SYSAHBCLKCTRL_MRT_SHIFT (10U) /*! MRT - Enables clock for multi-rate timer. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_MRT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_MRT_SHIFT)) & SYSCON_SYSAHBCLKCTRL_MRT_MASK) #define SYSCON_SYSAHBCLKCTRL_SPI0_MASK (0x800U) #define SYSCON_SYSAHBCLKCTRL_SPI0_SHIFT (11U) /*! SPI0 - Enables clock for SPI0. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_SPI0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_SPI0_SHIFT)) & SYSCON_SYSAHBCLKCTRL_SPI0_MASK) #define SYSCON_SYSAHBCLKCTRL_SPI1_MASK (0x1000U) #define SYSCON_SYSAHBCLKCTRL_SPI1_SHIFT (12U) /*! SPI1 - Enables clock for SPI1. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_SPI1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_SPI1_SHIFT)) & SYSCON_SYSAHBCLKCTRL_SPI1_MASK) #define SYSCON_SYSAHBCLKCTRL_CRC_MASK (0x2000U) #define SYSCON_SYSAHBCLKCTRL_CRC_SHIFT (13U) /*! CRC - Enables clock for CRC. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_CRC(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_CRC_SHIFT)) & SYSCON_SYSAHBCLKCTRL_CRC_MASK) #define SYSCON_SYSAHBCLKCTRL_UART0_MASK (0x4000U) #define SYSCON_SYSAHBCLKCTRL_UART0_SHIFT (14U) /*! UART0 - Enables clock for USART0. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_UART0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_UART0_SHIFT)) & SYSCON_SYSAHBCLKCTRL_UART0_MASK) #define SYSCON_SYSAHBCLKCTRL_WWDT_MASK (0x20000U) #define SYSCON_SYSAHBCLKCTRL_WWDT_SHIFT (17U) /*! WWDT - Enables clock for WWDT. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_WWDT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_WWDT_SHIFT)) & SYSCON_SYSAHBCLKCTRL_WWDT_MASK) #define SYSCON_SYSAHBCLKCTRL_IOCON_MASK (0x40000U) #define SYSCON_SYSAHBCLKCTRL_IOCON_SHIFT (18U) /*! IOCON - Enables clock for IOCON block. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_IOCON(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_IOCON_SHIFT)) & SYSCON_SYSAHBCLKCTRL_IOCON_MASK) #define SYSCON_SYSAHBCLKCTRL_ADC_MASK (0x1000000U) #define SYSCON_SYSAHBCLKCTRL_ADC_SHIFT (24U) /*! ADC - Enables clock to ADC. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_ADC(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_ADC_SHIFT)) & SYSCON_SYSAHBCLKCTRL_ADC_MASK) #define SYSCON_SYSAHBCLKCTRL_MTB_MASK (0x4000000U) #define SYSCON_SYSAHBCLKCTRL_MTB_SHIFT (26U) /*! MTB - Enables clock to micro-trace buffer control registers.Turn on this clock when using the * micro-trace buffer for debug purposes. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_MTB(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_MTB_SHIFT)) & SYSCON_SYSAHBCLKCTRL_MTB_MASK) #define SYSCON_SYSAHBCLKCTRL_DMA_MASK (0x20000000U) #define SYSCON_SYSAHBCLKCTRL_DMA_SHIFT (29U) /*! DMA - Enables clock to DMA. * 0b0..Disable. * 0b1..Enable. */ #define SYSCON_SYSAHBCLKCTRL_DMA(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSAHBCLKCTRL_DMA_SHIFT)) & SYSCON_SYSAHBCLKCTRL_DMA_MASK) /*! @} */ /*! @name UARTCLKDIV - USART clock divider */ /*! @{ */ #define SYSCON_UARTCLKDIV_DIV_MASK (0xFFU) #define SYSCON_UARTCLKDIV_DIV_SHIFT (0U) /*! DIV - USART fractional baud rate generator clock divider values. 0: Clock disabled. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_UARTCLKDIV_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_UARTCLKDIV_DIV_SHIFT)) & SYSCON_UARTCLKDIV_DIV_MASK) /*! @} */ /*! @name CLKOUTSEL - CLKOUT clock source select */ /*! @{ */ #define SYSCON_CLKOUTSEL_SEL_MASK (0x3U) #define SYSCON_CLKOUTSEL_SEL_SHIFT (0U) /*! SEL - CLKOUT clock source. * 0b00..IRC oscillator * 0b01..Crystal oscillator (SYSOSC) * 0b10..Watchdog oscillator * 0b11..Main clock */ #define SYSCON_CLKOUTSEL_SEL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_CLKOUTSEL_SEL_SHIFT)) & SYSCON_CLKOUTSEL_SEL_MASK) /*! @} */ /*! @name CLKOUTUEN - CLKOUT clock source update enable */ /*! @{ */ #define SYSCON_CLKOUTUEN_ENA_MASK (0x1U) #define SYSCON_CLKOUTUEN_ENA_SHIFT (0U) /*! ENA - Enable CLKOUT clock source update. * 0b0..No change * 0b1..Update clock source */ #define SYSCON_CLKOUTUEN_ENA(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_CLKOUTUEN_ENA_SHIFT)) & SYSCON_CLKOUTUEN_ENA_MASK) /*! @} */ /*! @name CLKOUTDIV - PLL control */ /*! @{ */ #define SYSCON_CLKOUTDIV_DIV_MASK (0xFFU) #define SYSCON_CLKOUTDIV_DIV_SHIFT (0U) /*! DIV - CLKOUT clock divider values. 0: Disable CLKOUT clock divider 1: Divide by 1 to 255: Divide by 255 */ #define SYSCON_CLKOUTDIV_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_CLKOUTDIV_DIV_SHIFT)) & SYSCON_CLKOUTDIV_DIV_MASK) /*! @} */ /*! @name UARTFRGDIV - USART1 to USART4 common fractional generator divider value */ /*! @{ */ #define SYSCON_UARTFRGDIV_DIV_MASK (0xFFU) #define SYSCON_UARTFRGDIV_DIV_SHIFT (0U) /*! DIV - Denominator of the fractional divider. DIV is equal to the programmed value +1. Always set * to 0xFF to use with the fractional baud rate generator. */ #define SYSCON_UARTFRGDIV_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_UARTFRGDIV_DIV_SHIFT)) & SYSCON_UARTFRGDIV_DIV_MASK) /*! @} */ /*! @name UARTFRGMULT - USART common fractional generator divider value */ /*! @{ */ #define SYSCON_UARTFRGMULT_MULT_MASK (0xFFU) #define SYSCON_UARTFRGMULT_MULT_SHIFT (0U) /*! MULT - Numerator of the fractional divider. MULT is equal to the programmed value. */ #define SYSCON_UARTFRGMULT_MULT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_UARTFRGMULT_MULT_SHIFT)) & SYSCON_UARTFRGMULT_MULT_MASK) /*! @} */ /*! @name EXTTRACECMD - External trace buffer command register */ /*! @{ */ #define SYSCON_EXTTRACECMD_START_MASK (0x1U) #define SYSCON_EXTTRACECMD_START_SHIFT (0U) /*! START - Trace start command. Writing a one to this bit sets the TSTART signal to the MTB to HIGH * and starts tracing if the TSTARTEN bit in the MTB master register is set to one as well. */ #define SYSCON_EXTTRACECMD_START(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_EXTTRACECMD_START_SHIFT)) & SYSCON_EXTTRACECMD_START_MASK) #define SYSCON_EXTTRACECMD_STOP_MASK (0x2U) #define SYSCON_EXTTRACECMD_STOP_SHIFT (1U) /*! STOP - Trace stop command. Writing a one to this bit sets the TSTOP signal in the MTB to HIGH * and stops tracing if the TSTOPEN bit in the MTB master register is set to one as well. */ #define SYSCON_EXTTRACECMD_STOP(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_EXTTRACECMD_STOP_SHIFT)) & SYSCON_EXTTRACECMD_STOP_MASK) /*! @} */ /*! @name PIOPORCAP0 - POR captured PIO status 0 */ /*! @{ */ #define SYSCON_PIOPORCAP0_PIOSTAT_MASK (0x3FFFFU) #define SYSCON_PIOPORCAP0_PIOSTAT_SHIFT (0U) /*! PIOSTAT - State of PIO0_17 through PIO0_0 at power-on reset */ #define SYSCON_PIOPORCAP0_PIOSTAT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PIOPORCAP0_PIOSTAT_SHIFT)) & SYSCON_PIOPORCAP0_PIOSTAT_MASK) /*! @} */ /*! @name IOCONCLKDIV6 - Peripheral clock 6 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV6_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV6_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV6_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV6_DIV_SHIFT)) & SYSCON_IOCONCLKDIV6_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV5 - Peripheral clock 6 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV5_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV5_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV5_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV5_DIV_SHIFT)) & SYSCON_IOCONCLKDIV5_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV4 - Peripheral clock 4 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV4_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV4_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV4_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV4_DIV_SHIFT)) & SYSCON_IOCONCLKDIV4_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV3 - Peripheral clock 3 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV3_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV3_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV3_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV3_DIV_SHIFT)) & SYSCON_IOCONCLKDIV3_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV2 - Peripheral clock 2 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV2_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV2_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV2_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV2_DIV_SHIFT)) & SYSCON_IOCONCLKDIV2_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV1 - Peripheral clock 1 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV1_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV1_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV1_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV1_DIV_SHIFT)) & SYSCON_IOCONCLKDIV1_DIV_MASK) /*! @} */ /*! @name IOCONCLKDIV0 - Peripheral clock 0 to the IOCON block for programmable glitch filter */ /*! @{ */ #define SYSCON_IOCONCLKDIV0_DIV_MASK (0xFFU) #define SYSCON_IOCONCLKDIV0_DIV_SHIFT (0U) /*! DIV - IOCON glitch filter clock divider values 0: Disable IOCONFILTR_PCLK. 1: Divide by 1. to 255: Divide by 255. */ #define SYSCON_IOCONCLKDIV0_DIV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IOCONCLKDIV0_DIV_SHIFT)) & SYSCON_IOCONCLKDIV0_DIV_MASK) /*! @} */ /*! @name BODCTRL - BOD control register */ /*! @{ */ #define SYSCON_BODCTRL_BODRSTLEV_MASK (0x3U) #define SYSCON_BODCTRL_BODRSTLEV_SHIFT (0U) /*! BODRSTLEV - BOD reset level * 0b00..Reserved * 0b01..Level 1 * 0b10..Level 2 * 0b11..Level 3 */ #define SYSCON_BODCTRL_BODRSTLEV(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_BODCTRL_BODRSTLEV_SHIFT)) & SYSCON_BODCTRL_BODRSTLEV_MASK) #define SYSCON_BODCTRL_BODINTVAL_MASK (0xCU) #define SYSCON_BODCTRL_BODINTVAL_SHIFT (2U) /*! BODINTVAL - BOD interrupt level * 0b00..Reserved * 0b01..Level 1 * 0b10..Level 2 * 0b11..Level 3 */ #define SYSCON_BODCTRL_BODINTVAL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_BODCTRL_BODINTVAL_SHIFT)) & SYSCON_BODCTRL_BODINTVAL_MASK) #define SYSCON_BODCTRL_BODRSTENA_MASK (0x10U) #define SYSCON_BODCTRL_BODRSTENA_SHIFT (4U) /*! BODRSTENA - BOD reset enable * 0b0..Disable reset function. * 0b1..Enable reset function. */ #define SYSCON_BODCTRL_BODRSTENA(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_BODCTRL_BODRSTENA_SHIFT)) & SYSCON_BODCTRL_BODRSTENA_MASK) /*! @} */ /*! @name SYSTCKCAL - System tick timer calibration register */ /*! @{ */ #define SYSCON_SYSTCKCAL_CAL_MASK (0x3FFFFFFU) #define SYSCON_SYSTCKCAL_CAL_SHIFT (0U) /*! CAL - System tick timer calibration value. */ #define SYSCON_SYSTCKCAL_CAL(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_SYSTCKCAL_CAL_SHIFT)) & SYSCON_SYSTCKCAL_CAL_MASK) /*! @} */ /*! @name IRQLATENCY - IRQ latency register */ /*! @{ */ #define SYSCON_IRQLATENCY_LATENCY_MASK (0xFFU) #define SYSCON_IRQLATENCY_LATENCY_SHIFT (0U) /*! LATENCY - 8-bit latency value. */ #define SYSCON_IRQLATENCY_LATENCY(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_IRQLATENCY_LATENCY_SHIFT)) & SYSCON_IRQLATENCY_LATENCY_MASK) /*! @} */ /*! @name NMISRC - NMI source selection register */ /*! @{ */ #define SYSCON_NMISRC_IRQN_MASK (0x1FU) #define SYSCON_NMISRC_IRQN_SHIFT (0U) /*! IRQN - The IRQ number of the interrupt that acts as the Non-Maskable Interrupt (NMI) if bit 31 is 1 */ #define SYSCON_NMISRC_IRQN(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_NMISRC_IRQN_SHIFT)) & SYSCON_NMISRC_IRQN_MASK) #define SYSCON_NMISRC_NMIEN_MASK (0x80000000U) #define SYSCON_NMISRC_NMIEN_SHIFT (31U) /*! NMIEN - Write a 1 to this bit to enable the Non-Maskable Interrupt (NMI) source selected by bits 4:0. */ #define SYSCON_NMISRC_NMIEN(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_NMISRC_NMIEN_SHIFT)) & SYSCON_NMISRC_NMIEN_MASK) /*! @} */ /*! @name PINTSEL - Pin interrupt select registers N */ /*! @{ */ #define SYSCON_PINTSEL_INTPIN_MASK (0x3FU) #define SYSCON_PINTSEL_INTPIN_SHIFT (0U) /*! INTPIN - Pin number select for pin interrupt or pattern match engine input. (PIO0_0 to PIO0_28 correspond to numbers 0 to 28). */ #define SYSCON_PINTSEL_INTPIN(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PINTSEL_INTPIN_SHIFT)) & SYSCON_PINTSEL_INTPIN_MASK) /*! @} */ /* The count of SYSCON_PINTSEL */ #define SYSCON_PINTSEL_COUNT (8U) /*! @name STARTERP0 - Start logic 0 pin wake-up enable register 0 */ /*! @{ */ #define SYSCON_STARTERP0_PINT0_MASK (0x1U) #define SYSCON_STARTERP0_PINT0_SHIFT (0U) /*! PINT0 - GPIO pin interrupt 0 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT0_SHIFT)) & SYSCON_STARTERP0_PINT0_MASK) #define SYSCON_STARTERP0_PINT1_MASK (0x2U) #define SYSCON_STARTERP0_PINT1_SHIFT (1U) /*! PINT1 - GPIO pin interrupt 1 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT1_SHIFT)) & SYSCON_STARTERP0_PINT1_MASK) #define SYSCON_STARTERP0_PINT2_MASK (0x4U) #define SYSCON_STARTERP0_PINT2_SHIFT (2U) /*! PINT2 - GPIO pin interrupt 2 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT2(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT2_SHIFT)) & SYSCON_STARTERP0_PINT2_MASK) #define SYSCON_STARTERP0_PINT3_MASK (0x8U) #define SYSCON_STARTERP0_PINT3_SHIFT (3U) /*! PINT3 - GPIO pin interrupt 3 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT3(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT3_SHIFT)) & SYSCON_STARTERP0_PINT3_MASK) #define SYSCON_STARTERP0_PINT4_MASK (0x10U) #define SYSCON_STARTERP0_PINT4_SHIFT (4U) /*! PINT4 - GPIO pin interrupt 4 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT4(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT4_SHIFT)) & SYSCON_STARTERP0_PINT4_MASK) #define SYSCON_STARTERP0_PINT5_MASK (0x20U) #define SYSCON_STARTERP0_PINT5_SHIFT (5U) /*! PINT5 - GPIO pin interrupt 5 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT5(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT5_SHIFT)) & SYSCON_STARTERP0_PINT5_MASK) #define SYSCON_STARTERP0_PINT6_MASK (0x40U) #define SYSCON_STARTERP0_PINT6_SHIFT (6U) /*! PINT6 - GPIO pin interrupt 6 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT6(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT6_SHIFT)) & SYSCON_STARTERP0_PINT6_MASK) #define SYSCON_STARTERP0_PINT7_MASK (0x80U) #define SYSCON_STARTERP0_PINT7_SHIFT (7U) /*! PINT7 - GPIO pin interrupt 7 wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP0_PINT7(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP0_PINT7_SHIFT)) & SYSCON_STARTERP0_PINT7_MASK) /*! @} */ /*! @name STARTERP1 - Start logic 1 interrupt wake-up enable register */ /*! @{ */ #define SYSCON_STARTERP1_SPI0_MASK (0x1U) #define SYSCON_STARTERP1_SPI0_SHIFT (0U) /*! SPI0 - SPI0 interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_SPI0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_SPI0_SHIFT)) & SYSCON_STARTERP1_SPI0_MASK) #define SYSCON_STARTERP1_SPI1_MASK (0x2U) #define SYSCON_STARTERP1_SPI1_SHIFT (1U) /*! SPI1 - SPI1 interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_SPI1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_SPI1_SHIFT)) & SYSCON_STARTERP1_SPI1_MASK) #define SYSCON_STARTERP1_USART0_MASK (0x8U) #define SYSCON_STARTERP1_USART0_SHIFT (3U) /*! USART0 - USART0 interrupt wake-up. Configure USART in synchronous slave mode. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_USART0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_USART0_SHIFT)) & SYSCON_STARTERP1_USART0_MASK) #define SYSCON_STARTERP1_USART1_MASK (0x10U) #define SYSCON_STARTERP1_USART1_SHIFT (4U) /*! USART1 - USART1 interrupt wake-up. Configure USART in synchronous slave mode. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_USART1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_USART1_SHIFT)) & SYSCON_STARTERP1_USART1_MASK) #define SYSCON_STARTERP1_USART2_MASK (0x20U) #define SYSCON_STARTERP1_USART2_SHIFT (5U) /*! USART2 - USART2 interrupt wake-up. Configure USART in synchronous slave mode. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_USART2(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_USART2_SHIFT)) & SYSCON_STARTERP1_USART2_MASK) #define SYSCON_STARTERP1_I2C1_MASK (0x80U) #define SYSCON_STARTERP1_I2C1_SHIFT (7U) /*! I2C1 - I2C1 interrupt wake-up. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_I2C1(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_I2C1_SHIFT)) & SYSCON_STARTERP1_I2C1_MASK) #define SYSCON_STARTERP1_I2C0_MASK (0x100U) #define SYSCON_STARTERP1_I2C0_SHIFT (8U) /*! I2C0 - I2C0 interrupt wake-up. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_I2C0(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_I2C0_SHIFT)) & SYSCON_STARTERP1_I2C0_MASK) #define SYSCON_STARTERP1_WWDT_MASK (0x1000U) #define SYSCON_STARTERP1_WWDT_SHIFT (12U) /*! WWDT - WWDT interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_WWDT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_WWDT_SHIFT)) & SYSCON_STARTERP1_WWDT_MASK) #define SYSCON_STARTERP1_BOD_MASK (0x2000U) #define SYSCON_STARTERP1_BOD_SHIFT (13U) /*! BOD - BOD interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_BOD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_BOD_SHIFT)) & SYSCON_STARTERP1_BOD_MASK) #define SYSCON_STARTERP1_WKT_MASK (0x8000U) #define SYSCON_STARTERP1_WKT_SHIFT (15U) /*! WKT - Self-wake-up timer interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_WKT(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_WKT_SHIFT)) & SYSCON_STARTERP1_WKT_MASK) #define SYSCON_STARTERP1_I2C2_MASK (0x200000U) #define SYSCON_STARTERP1_I2C2_SHIFT (21U) /*! I2C2 - I2C2 interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_I2C2(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_I2C2_SHIFT)) & SYSCON_STARTERP1_I2C2_MASK) #define SYSCON_STARTERP1_I2C3_MASK (0x400000U) #define SYSCON_STARTERP1_I2C3_SHIFT (22U) /*! I2C3 - I2C3 interrupt wake-up * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_STARTERP1_I2C3(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_STARTERP1_I2C3_SHIFT)) & SYSCON_STARTERP1_I2C3_MASK) /*! @} */ /*! @name PDSLEEPCFG - Deep-sleep configuration register */ /*! @{ */ #define SYSCON_PDSLEEPCFG_BOD_PD_MASK (0x8U) #define SYSCON_PDSLEEPCFG_BOD_PD_SHIFT (3U) /*! BOD_PD - BOD power-down control for Deep-sleep and Power-down mode * 0b0..powered * 0b1..powered down */ #define SYSCON_PDSLEEPCFG_BOD_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDSLEEPCFG_BOD_PD_SHIFT)) & SYSCON_PDSLEEPCFG_BOD_PD_MASK) #define SYSCON_PDSLEEPCFG_WDTOSC_PD_MASK (0x40U) #define SYSCON_PDSLEEPCFG_WDTOSC_PD_SHIFT (6U) /*! WDTOSC_PD - Watchdog oscillator power-down control for Deep-sleep and Power-down mode. Changing * this bit to powered-down has no effect when the LOCK bit in the WWDT MOD register is set. In * this case, the watchdog oscillator is always running. * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDSLEEPCFG_WDTOSC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDSLEEPCFG_WDTOSC_PD_SHIFT)) & SYSCON_PDSLEEPCFG_WDTOSC_PD_MASK) /*! @} */ /*! @name PDAWAKECFG - Wake-up configuration register */ /*! @{ */ #define SYSCON_PDAWAKECFG_IRCOUT_PD_MASK (0x1U) #define SYSCON_PDAWAKECFG_IRCOUT_PD_SHIFT (0U) /*! IRCOUT_PD - IRC oscillator output wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_IRCOUT_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_IRCOUT_PD_SHIFT)) & SYSCON_PDAWAKECFG_IRCOUT_PD_MASK) #define SYSCON_PDAWAKECFG_IRC_PD_MASK (0x2U) #define SYSCON_PDAWAKECFG_IRC_PD_SHIFT (1U) /*! IRC_PD - IRC oscillator power-down wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_IRC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_IRC_PD_SHIFT)) & SYSCON_PDAWAKECFG_IRC_PD_MASK) #define SYSCON_PDAWAKECFG_FLASH_PD_MASK (0x4U) #define SYSCON_PDAWAKECFG_FLASH_PD_SHIFT (2U) /*! FLASH_PD - Flash wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_FLASH_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_FLASH_PD_SHIFT)) & SYSCON_PDAWAKECFG_FLASH_PD_MASK) #define SYSCON_PDAWAKECFG_BOD_PD_MASK (0x8U) #define SYSCON_PDAWAKECFG_BOD_PD_SHIFT (3U) /*! BOD_PD - BOD wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_BOD_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_BOD_PD_SHIFT)) & SYSCON_PDAWAKECFG_BOD_PD_MASK) #define SYSCON_PDAWAKECFG_ADC_PD_MASK (0x10U) #define SYSCON_PDAWAKECFG_ADC_PD_SHIFT (4U) /*! ADC_PD - ADC wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_ADC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_ADC_PD_SHIFT)) & SYSCON_PDAWAKECFG_ADC_PD_MASK) #define SYSCON_PDAWAKECFG_SYSOSC_PD_MASK (0x20U) #define SYSCON_PDAWAKECFG_SYSOSC_PD_SHIFT (5U) /*! SYSOSC_PD - Crystal oscillator wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDAWAKECFG_SYSOSC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_SYSOSC_PD_SHIFT)) & SYSCON_PDAWAKECFG_SYSOSC_PD_MASK) #define SYSCON_PDAWAKECFG_WDTOSC_PD_MASK (0x40U) #define SYSCON_PDAWAKECFG_WDTOSC_PD_SHIFT (6U) /*! WDTOSC_PD - Watchdog oscillator wake-up configuration. Changing this bit to powered-down has no * effect when the LOCK bit in the WWDT MOD register is set. In this case, the watchdog * oscillator is always running * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDAWAKECFG_WDTOSC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_WDTOSC_PD_SHIFT)) & SYSCON_PDAWAKECFG_WDTOSC_PD_MASK) #define SYSCON_PDAWAKECFG_SYSPLL_PD_MASK (0x80U) #define SYSCON_PDAWAKECFG_SYSPLL_PD_SHIFT (7U) /*! SYSPLL_PD - System PLL wake-up configuration * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDAWAKECFG_SYSPLL_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_SYSPLL_PD_SHIFT)) & SYSCON_PDAWAKECFG_SYSPLL_PD_MASK) #define SYSCON_PDAWAKECFG_ACMP_MASK (0x8000U) #define SYSCON_PDAWAKECFG_ACMP_SHIFT (15U) /*! ACMP - Analog comparator wake-up configuration * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDAWAKECFG_ACMP(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDAWAKECFG_ACMP_SHIFT)) & SYSCON_PDAWAKECFG_ACMP_MASK) /*! @} */ /*! @name PDRUNCFG - Power configuration register */ /*! @{ */ #define SYSCON_PDRUNCFG_IRCOUT_PD_MASK (0x1U) #define SYSCON_PDRUNCFG_IRCOUT_PD_SHIFT (0U) /*! IRCOUT_PD - IRC oscillator output wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_IRCOUT_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_IRCOUT_PD_SHIFT)) & SYSCON_PDRUNCFG_IRCOUT_PD_MASK) #define SYSCON_PDRUNCFG_IRC_PD_MASK (0x2U) #define SYSCON_PDRUNCFG_IRC_PD_SHIFT (1U) /*! IRC_PD - IRC oscillator power-down wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_IRC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_IRC_PD_SHIFT)) & SYSCON_PDRUNCFG_IRC_PD_MASK) #define SYSCON_PDRUNCFG_FLASH_PD_MASK (0x4U) #define SYSCON_PDRUNCFG_FLASH_PD_SHIFT (2U) /*! FLASH_PD - Flash wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_FLASH_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_FLASH_PD_SHIFT)) & SYSCON_PDRUNCFG_FLASH_PD_MASK) #define SYSCON_PDRUNCFG_BOD_PD_MASK (0x8U) #define SYSCON_PDRUNCFG_BOD_PD_SHIFT (3U) /*! BOD_PD - BOD wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_BOD_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_BOD_PD_SHIFT)) & SYSCON_PDRUNCFG_BOD_PD_MASK) #define SYSCON_PDRUNCFG_ADC_PD_MASK (0x10U) #define SYSCON_PDRUNCFG_ADC_PD_SHIFT (4U) /*! ADC_PD - ADC wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_ADC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_ADC_PD_SHIFT)) & SYSCON_PDRUNCFG_ADC_PD_MASK) #define SYSCON_PDRUNCFG_SYSOSC_PD_MASK (0x20U) #define SYSCON_PDRUNCFG_SYSOSC_PD_SHIFT (5U) /*! SYSOSC_PD - Crystal oscillator wake-up configuration * 0b0..powered * 0b1..powered down */ #define SYSCON_PDRUNCFG_SYSOSC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_SYSOSC_PD_SHIFT)) & SYSCON_PDRUNCFG_SYSOSC_PD_MASK) #define SYSCON_PDRUNCFG_WDTOSC_PD_MASK (0x40U) #define SYSCON_PDRUNCFG_WDTOSC_PD_SHIFT (6U) /*! WDTOSC_PD - Watchdog oscillator wake-up configuration. Changing this bit to powered-down has no * effect when the LOCK bit in the WWDT MOD register is set. In this case, the watchdog * oscillator is always running * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDRUNCFG_WDTOSC_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_WDTOSC_PD_SHIFT)) & SYSCON_PDRUNCFG_WDTOSC_PD_MASK) #define SYSCON_PDRUNCFG_SYSPLL_PD_MASK (0x80U) #define SYSCON_PDRUNCFG_SYSPLL_PD_SHIFT (7U) /*! SYSPLL_PD - System PLL wake-up configuration * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDRUNCFG_SYSPLL_PD(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_SYSPLL_PD_SHIFT)) & SYSCON_PDRUNCFG_SYSPLL_PD_MASK) #define SYSCON_PDRUNCFG_ACMP_MASK (0x8000U) #define SYSCON_PDRUNCFG_ACMP_SHIFT (15U) /*! ACMP - Analog comparator wake-up configuration * 0b0..Disabled * 0b1..Enabled */ #define SYSCON_PDRUNCFG_ACMP(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_PDRUNCFG_ACMP_SHIFT)) & SYSCON_PDRUNCFG_ACMP_MASK) /*! @} */ /*! @name DEVICE_ID - Part ID register */ /*! @{ */ #define SYSCON_DEVICE_ID_DEVICEID_MASK (0xFFFFFFFFU) #define SYSCON_DEVICE_ID_DEVICEID_SHIFT (0U) /*! DEVICEID - Part ID */ #define SYSCON_DEVICE_ID_DEVICEID(x) (((uint32_t)(((uint32_t)(x)) << SYSCON_DEVICE_ID_DEVICEID_SHIFT)) & SYSCON_DEVICE_ID_DEVICEID_MASK) /*! @} */ /*! * @} */ /* end of group SYSCON_Register_Masks */ /* SYSCON - Peripheral instance base addresses */ /** Peripheral SYSCON base address */ #define SYSCON_BASE (0x40048000u) /** Peripheral SYSCON base pointer */ #define SYSCON ((SYSCON_Type *)SYSCON_BASE) /** Array initializer of SYSCON peripheral base addresses */ #define SYSCON_BASE_ADDRS { SYSCON_BASE } /** Array initializer of SYSCON peripheral base pointers */ #define SYSCON_BASE_PTRS { SYSCON } /** Interrupt vectors for the SYSCON peripheral type */ #define SYSCON_IRQS { BOD_IRQn } /*! * @} */ /* end of group SYSCON_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- USART Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup USART_Peripheral_Access_Layer USART Peripheral Access Layer * @{ */ /** USART - Register Layout Typedef */ typedef struct { __IO uint32_t CFG; /**< USART Configuration register. Basic USART configuration settings that typically are not changed during operation., offset: 0x0 */ __IO uint32_t CTL; /**< USART Control register. USART control settings that are more likely to change during operation., offset: 0x4 */ __IO uint32_t STAT; /**< USART Status register. The complete status value can be read here. Writing ones clears some bits in the register. Some bits can be cleared by writing a 1 to them., offset: 0x8 */ __IO uint32_t INTENSET; /**< Interrupt Enable read and Set register. Contains an individual interrupt enable bit for each potential USART interrupt. A complete value may be read from this register. Writing a 1 to any implemented bit position causes that bit to be set., offset: 0xC */ __O uint32_t INTENCLR; /**< Interrupt Enable Clear register. Allows clearing any combination of bits in the INTENSET register. Writing a 1 to any implemented bit position causes the corresponding bit to be cleared., offset: 0x10 */ __I uint32_t RXDAT; /**< Receiver Data register. Contains the last character received., offset: 0x14 */ __I uint32_t RXDATSTAT; /**< Receiver Data with Status register. Combines the last character received with the current USART receive status. Allows DMA or software to recover incoming data and status together., offset: 0x18 */ __IO uint32_t TXDAT; /**< Transmit Data register. Data to be transmitted is written here., offset: 0x1C */ __IO uint32_t BRG; /**< Baud Rate Generator register. 16-bit integer baud rate divisor value., offset: 0x20 */ __I uint32_t INTSTAT; /**< Interrupt status register. Reflects interrupts that are currently enabled., offset: 0x24 */ __IO uint32_t OSR; /**< Oversample selection register for asynchronous communication., offset: 0x28 */ __IO uint32_t ADDR; /**< Address register for automatic address matching., offset: 0x2C */ } USART_Type; /* ---------------------------------------------------------------------------- -- USART Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup USART_Register_Masks USART Register Masks * @{ */ /*! @name CFG - USART Configuration register. Basic USART configuration settings that typically are not changed during operation. */ /*! @{ */ #define USART_CFG_ENABLE_MASK (0x1U) #define USART_CFG_ENABLE_SHIFT (0U) /*! ENABLE - USART Enable. * 0b0..Disabled. The USART is disabled and the internal state machine and counters are reset. While Enable = 0, * all USART interrupts and DMA transfers are disabled. When Enable is set again, CFG and most other control * bits remain unchanged. When re-enabled, the USART will immediately be ready to transmit because the * transmitter has been reset and is therefore available. * 0b1..Enabled. The USART is enabled for operation. */ #define USART_CFG_ENABLE(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_ENABLE_SHIFT)) & USART_CFG_ENABLE_MASK) #define USART_CFG_DATALEN_MASK (0xCU) #define USART_CFG_DATALEN_SHIFT (2U) /*! DATALEN - Selects the data size for the USART. * 0b00..7 bit Data length. * 0b01..8 bit Data length. * 0b10..9 bit data length. The 9th bit is commonly used for addressing in multidrop mode. See the ADDRDET bit in the CTL register. * 0b11..Reserved. */ #define USART_CFG_DATALEN(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_DATALEN_SHIFT)) & USART_CFG_DATALEN_MASK) #define USART_CFG_PARITYSEL_MASK (0x30U) #define USART_CFG_PARITYSEL_SHIFT (4U) /*! PARITYSEL - Selects what type of parity is used by the USART. * 0b00..No parity. * 0b01..Reserved. * 0b10..Even parity. Adds a bit to each character such that the number of 1s in a transmitted character is even, * and the number of 1s in a received character is expected to be even. * 0b11..Odd parity. Adds a bit to each character such that the number of 1s in a transmitted character is odd, * and the number of 1s in a received character is expected to be odd. */ #define USART_CFG_PARITYSEL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_PARITYSEL_SHIFT)) & USART_CFG_PARITYSEL_MASK) #define USART_CFG_STOPLEN_MASK (0x40U) #define USART_CFG_STOPLEN_SHIFT (6U) /*! STOPLEN - Number of stop bits appended to transmitted data. Only a single stop bit is required for received data. * 0b0..1 stop bit. * 0b1..2 stop bits. This setting should only be used for asynchronous communication. */ #define USART_CFG_STOPLEN(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_STOPLEN_SHIFT)) & USART_CFG_STOPLEN_MASK) #define USART_CFG_CTSEN_MASK (0x200U) #define USART_CFG_CTSEN_SHIFT (9U) /*! CTSEN - CTS Enable. Determines whether CTS is used for flow control. CTS can be from the input * pin, or from the USART's own RTS if loopback mode is enabled. * 0b0..No flow control. The transmitter does not receive any automatic flow control signal. * 0b1..Flow control enabled. The transmitter uses the CTS input (or RTS output in loopback mode) for flow control purposes. */ #define USART_CFG_CTSEN(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_CTSEN_SHIFT)) & USART_CFG_CTSEN_MASK) #define USART_CFG_SYNCEN_MASK (0x800U) #define USART_CFG_SYNCEN_SHIFT (11U) /*! SYNCEN - Selects synchronous or asynchronous operation. * 0b0..Asynchronous mode. * 0b1..Synchronous mode. */ #define USART_CFG_SYNCEN(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_SYNCEN_SHIFT)) & USART_CFG_SYNCEN_MASK) #define USART_CFG_CLKPOL_MASK (0x1000U) #define USART_CFG_CLKPOL_SHIFT (12U) /*! CLKPOL - Selects the clock polarity and sampling edge of received data in synchronous mode. * 0b0..Falling edge. Un_RXD is sampled on the falling edge of SCLK. * 0b1..Rising edge. Un_RXD is sampled on the rising edge of SCLK. */ #define USART_CFG_CLKPOL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_CLKPOL_SHIFT)) & USART_CFG_CLKPOL_MASK) #define USART_CFG_SYNCMST_MASK (0x4000U) #define USART_CFG_SYNCMST_SHIFT (14U) /*! SYNCMST - Synchronous mode Master select. * 0b0..Slave. When synchronous mode is enabled, the USART is a slave. * 0b1..Master. When synchronous mode is enabled, the USART is a master. */ #define USART_CFG_SYNCMST(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_SYNCMST_SHIFT)) & USART_CFG_SYNCMST_MASK) #define USART_CFG_LOOP_MASK (0x8000U) #define USART_CFG_LOOP_SHIFT (15U) /*! LOOP - Selects data loopback mode. * 0b0..Normal operation. * 0b1..Loopback mode. This provides a mechanism to perform diagnostic loopback testing for USART data. Serial * data from the transmitter (Un_TXD) is connected internally to serial input of the receive (Un_RXD). Un_TXD * and Un_RTS activity will also appear on external pins if these functions are configured to appear on device * pins. The receiver RTS signal is also looped back to CTS and performs flow control if enabled by CTSEN. */ #define USART_CFG_LOOP(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_LOOP_SHIFT)) & USART_CFG_LOOP_MASK) #define USART_CFG_OETA_MASK (0x40000U) #define USART_CFG_OETA_SHIFT (18U) /*! OETA - Output Enable Turnaround time enable for RS-485 operation. * 0b0..Disabled. If selected by OESEL, the Output Enable signal deasserted at the end of the last stop bit of a transmission. * 0b1..Enabled. If selected by OESEL, the Output Enable signal remains asserted for one character time after the * end of the last stop bit of a transmission. OE will also remain asserted if another transmit begins * before it is deasserted. */ #define USART_CFG_OETA(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_OETA_SHIFT)) & USART_CFG_OETA_MASK) #define USART_CFG_AUTOADDR_MASK (0x80000U) #define USART_CFG_AUTOADDR_SHIFT (19U) /*! AUTOADDR - Automatic Address matching enable. * 0b0..Disabled. When addressing is enabled by ADDRDET, address matching is done by software. This provides the * possibility of versatile addressing (e.g. respond to more than one address). * 0b1..Enabled. When addressing is enabled by ADDRDET, address matching is done by hardware, using the value in * the ADDR register as the address to match. */ #define USART_CFG_AUTOADDR(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_AUTOADDR_SHIFT)) & USART_CFG_AUTOADDR_MASK) #define USART_CFG_OESEL_MASK (0x100000U) #define USART_CFG_OESEL_SHIFT (20U) /*! OESEL - Output Enable Select. * 0b0..Standard. The RTS signal is used as the standard flow control function. * 0b1..RS-485. The RTS signal configured to provide an output enable signal to control an RS-485 transceiver. */ #define USART_CFG_OESEL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_OESEL_SHIFT)) & USART_CFG_OESEL_MASK) #define USART_CFG_OEPOL_MASK (0x200000U) #define USART_CFG_OEPOL_SHIFT (21U) /*! OEPOL - Output Enable Polarity. * 0b0..Low. If selected by OESEL, the output enable is active low. * 0b1..High. If selected by OESEL, the output enable is active high. */ #define USART_CFG_OEPOL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_OEPOL_SHIFT)) & USART_CFG_OEPOL_MASK) #define USART_CFG_RXPOL_MASK (0x400000U) #define USART_CFG_RXPOL_SHIFT (22U) /*! RXPOL - Receive data polarity. * 0b0..Standard. The RX signal is used as it arrives from the pin. This means that the RX rest value is 1, start * bit is 0, data is not inverted, and the stop bit is 1. * 0b1..Inverted. The RX signal is inverted before being used by the USART. This means that the RX rest value is * 0, start bit is 1, data is inverted, and the stop bit is 0. */ #define USART_CFG_RXPOL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_RXPOL_SHIFT)) & USART_CFG_RXPOL_MASK) #define USART_CFG_TXPOL_MASK (0x800000U) #define USART_CFG_TXPOL_SHIFT (23U) /*! TXPOL - Transmit data polarity. * 0b0..Standard. The TX signal is sent out without change. This means that the TX rest value is 1, start bit is * 0, data is not inverted, and the stop bit is 1. * 0b1..Inverted. The TX signal is inverted by the USART before being sent out. This means that the TX rest value * is 0, start bit is 1, data is inverted, and the stop bit is 0. */ #define USART_CFG_TXPOL(x) (((uint32_t)(((uint32_t)(x)) << USART_CFG_TXPOL_SHIFT)) & USART_CFG_TXPOL_MASK) /*! @} */ /*! @name CTL - USART Control register. USART control settings that are more likely to change during operation. */ /*! @{ */ #define USART_CTL_TXBRKEN_MASK (0x2U) #define USART_CTL_TXBRKEN_SHIFT (1U) /*! TXBRKEN - Break Enable. * 0b0..Normal operation. * 0b1..Continuous break. Continuous break is sent immediately when this bit is set, and remains until this bit * is cleared. A break may be sent without danger of corrupting any currently transmitting character if the * transmitter is first disabled (TXDIS in CTL is set) and then waiting for the transmitter to be disabled * (TXDISINT in STAT = 1) before writing 1 to TXBRKEN. */ #define USART_CTL_TXBRKEN(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_TXBRKEN_SHIFT)) & USART_CTL_TXBRKEN_MASK) #define USART_CTL_ADDRDET_MASK (0x4U) #define USART_CTL_ADDRDET_SHIFT (2U) /*! ADDRDET - Enable address detect mode. * 0b0..Disabled. The USART presents all incoming data. * 0b1..Enabled. The USART receiver ignores incoming data that does not have the most significant bit of the data * (typically the 9th bit) = 1. When the data MSB bit = 1, the receiver treats the incoming data normally, * generating a received data interrupt. Software can then check the data to see if this is an address that * should be handled. If it is, the ADDRDET bit is cleared by software and further incoming data is handled * normally. */ #define USART_CTL_ADDRDET(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_ADDRDET_SHIFT)) & USART_CTL_ADDRDET_MASK) #define USART_CTL_TXDIS_MASK (0x40U) #define USART_CTL_TXDIS_SHIFT (6U) /*! TXDIS - Transmit Disable. * 0b0..Not disabled. USART transmitter is not disabled. * 0b1..Disabled. USART transmitter is disabled after any character currently being transmitted is complete. This * feature can be used to facilitate software flow control. */ #define USART_CTL_TXDIS(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_TXDIS_SHIFT)) & USART_CTL_TXDIS_MASK) #define USART_CTL_CC_MASK (0x100U) #define USART_CTL_CC_SHIFT (8U) /*! CC - Continuous Clock generation. By default, SCLK is only output while data is being transmitted in synchronous mode. * 0b0..Clock on character. In synchronous mode, SCLK cycles only when characters are being sent on Un_TXD or to * complete a character that is being received. * 0b1..Continuous clock. SCLK runs continuously in synchronous mode, allowing characters to be received on * Un_RxD independently from transmission on Un_TXD). */ #define USART_CTL_CC(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_CC_SHIFT)) & USART_CTL_CC_MASK) #define USART_CTL_CLRCCONRX_MASK (0x200U) #define USART_CTL_CLRCCONRX_SHIFT (9U) /*! CLRCCONRX - Clear Continuous Clock. * 0b0..No effect. No effect on the CC bit. * 0b1..Auto-clear. The CC bit is automatically cleared when a complete character has been received. This bit is cleared at the same time. */ #define USART_CTL_CLRCCONRX(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_CLRCCONRX_SHIFT)) & USART_CTL_CLRCCONRX_MASK) #define USART_CTL_AUTOBAUD_MASK (0x10000U) #define USART_CTL_AUTOBAUD_SHIFT (16U) /*! AUTOBAUD - Autobaud enable. * 0b0..Disabled. USART is in normal operating mode. * 0b1..Enabled. USART is in autobaud mode. This bit should only be set when the USART receiver is idle. The * first start bit of RX is measured and used the update the BRG register to match the received data rate. * AUTOBAUD is cleared once this process is complete, or if there is an AERR. */ #define USART_CTL_AUTOBAUD(x) (((uint32_t)(((uint32_t)(x)) << USART_CTL_AUTOBAUD_SHIFT)) & USART_CTL_AUTOBAUD_MASK) /*! @} */ /*! @name STAT - USART Status register. The complete status value can be read here. Writing ones clears some bits in the register. Some bits can be cleared by writing a 1 to them. */ /*! @{ */ #define USART_STAT_RXRDY_MASK (0x1U) #define USART_STAT_RXRDY_SHIFT (0U) /*! RXRDY - Receiver Ready flag. When 1, indicates that data is available to be read from the * receiver buffer. Cleared after a read of the RXDAT or RXDATSTAT registers. */ #define USART_STAT_RXRDY(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_RXRDY_SHIFT)) & USART_STAT_RXRDY_MASK) #define USART_STAT_RXIDLE_MASK (0x2U) #define USART_STAT_RXIDLE_SHIFT (1U) /*! RXIDLE - Receiver Idle. When 0, indicates that the receiver is currently in the process of * receiving data. When 1, indicates that the receiver is not currently in the process of receiving * data. */ #define USART_STAT_RXIDLE(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_RXIDLE_SHIFT)) & USART_STAT_RXIDLE_MASK) #define USART_STAT_TXRDY_MASK (0x4U) #define USART_STAT_TXRDY_SHIFT (2U) /*! TXRDY - Transmitter Ready flag. When 1, this bit indicates that data may be written to the * transmit buffer. Previous data may still be in the process of being transmitted. Cleared when data * is written to TXDAT. Set when the data is moved from the transmit buffer to the transmit shift * register. */ #define USART_STAT_TXRDY(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_TXRDY_SHIFT)) & USART_STAT_TXRDY_MASK) #define USART_STAT_TXIDLE_MASK (0x8U) #define USART_STAT_TXIDLE_SHIFT (3U) /*! TXIDLE - Transmitter Idle. When 0, indicates that the transmitter is currently in the process of * sending data.When 1, indicate that the transmitter is not currently in the process of sending * data. */ #define USART_STAT_TXIDLE(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_TXIDLE_SHIFT)) & USART_STAT_TXIDLE_MASK) #define USART_STAT_CTS_MASK (0x10U) #define USART_STAT_CTS_SHIFT (4U) /*! CTS - This bit reflects the current state of the CTS signal, regardless of the setting of the * CTSEN bit in the CFG register. This will be the value of the CTS input pin unless loopback mode * is enabled. */ #define USART_STAT_CTS(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_CTS_SHIFT)) & USART_STAT_CTS_MASK) #define USART_STAT_DELTACTS_MASK (0x20U) #define USART_STAT_DELTACTS_SHIFT (5U) /*! DELTACTS - This bit is set when a change in the state is detected for the CTS flag above. This bit is cleared by software. */ #define USART_STAT_DELTACTS(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_DELTACTS_SHIFT)) & USART_STAT_DELTACTS_MASK) #define USART_STAT_TXDISSTAT_MASK (0x40U) #define USART_STAT_TXDISSTAT_SHIFT (6U) /*! TXDISSTAT - Transmitter Disabled Interrupt flag. When 1, this bit indicates that the USART * transmitter is fully idle after being disabled via the TXDIS in the CTL register (TXDIS = 1). */ #define USART_STAT_TXDISSTAT(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_TXDISSTAT_SHIFT)) & USART_STAT_TXDISSTAT_MASK) #define USART_STAT_OVERRUNINT_MASK (0x100U) #define USART_STAT_OVERRUNINT_SHIFT (8U) /*! OVERRUNINT - Overrun Error interrupt flag. This flag is set when a new character is received * while the receiver buffer is still in use. If this occurs, the newly received character in the * shift register is lost. */ #define USART_STAT_OVERRUNINT(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_OVERRUNINT_SHIFT)) & USART_STAT_OVERRUNINT_MASK) #define USART_STAT_RXBRK_MASK (0x400U) #define USART_STAT_RXBRK_SHIFT (10U) /*! RXBRK - Received Break. This bit reflects the current state of the receiver break detection * logic. It is set when the Un_RXD pin remains low for 16 bit times. Note that FRAMERRINT will also * be set when this condition occurs because the stop bit(s) for the character would be missing. * RXBRK is cleared when the Un_RXD pin goes high. */ #define USART_STAT_RXBRK(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_RXBRK_SHIFT)) & USART_STAT_RXBRK_MASK) #define USART_STAT_DELTARXBRK_MASK (0x800U) #define USART_STAT_DELTARXBRK_SHIFT (11U) /*! DELTARXBRK - This bit is set when a change in the state of receiver break detection occurs.Cleared by software. */ #define USART_STAT_DELTARXBRK(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_DELTARXBRK_SHIFT)) & USART_STAT_DELTARXBRK_MASK) #define USART_STAT_START_MASK (0x1000U) #define USART_STAT_START_SHIFT (12U) /*! START - This bit is set when a start is detected on the receiver input. Its purpose is primarily * to allow wake-up from Deep-sleep or Power-down mode immediately when a start is detected. * Cleared by software. */ #define USART_STAT_START(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_START_SHIFT)) & USART_STAT_START_MASK) #define USART_STAT_FRAMERRINT_MASK (0x2000U) #define USART_STAT_FRAMERRINT_SHIFT (13U) /*! FRAMERRINT - Framing Error interrupt flag. This flag is set when a character is received with a * missing stop bit at the expected location. This could be an indication of a baud rate or * configuration mismatch with the transmitting source. */ #define USART_STAT_FRAMERRINT(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_FRAMERRINT_SHIFT)) & USART_STAT_FRAMERRINT_MASK) #define USART_STAT_PARITYERRINT_MASK (0x4000U) #define USART_STAT_PARITYERRINT_SHIFT (14U) /*! PARITYERRINT - Parity Error interrupt flag. This flag is set when a parity error is detected in a received character. */ #define USART_STAT_PARITYERRINT(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_PARITYERRINT_SHIFT)) & USART_STAT_PARITYERRINT_MASK) #define USART_STAT_RXNOISEINT_MASK (0x8000U) #define USART_STAT_RXNOISEINT_SHIFT (15U) /*! RXNOISEINT - Received Noise interrupt flag. Three samples of received data are taken in order to * determine the value of each received data bit, except in synchronous mode. This acts as a * noise filter if one sample disagrees. This flag is set when a received data bit contains one * disagreeing sample. This could indicate line noise, a baud rate or character format mismatch, or * loss of synchronization during data reception. */ #define USART_STAT_RXNOISEINT(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_RXNOISEINT_SHIFT)) & USART_STAT_RXNOISEINT_MASK) #define USART_STAT_ABERR_MASK (0x10000U) #define USART_STAT_ABERR_SHIFT (16U) /*! ABERR - Autobaud Error. An autobaud error can occur if the BRG counts to its limit before the * end of the start bit that is being measured, essentially an autobaud time-out. */ #define USART_STAT_ABERR(x) (((uint32_t)(((uint32_t)(x)) << USART_STAT_ABERR_SHIFT)) & USART_STAT_ABERR_MASK) /*! @} */ /*! @name INTENSET - Interrupt Enable read and Set register. Contains an individual interrupt enable bit for each potential USART interrupt. A complete value may be read from this register. Writing a 1 to any implemented bit position causes that bit to be set. */ /*! @{ */ #define USART_INTENSET_RXRDYEN_MASK (0x1U) #define USART_INTENSET_RXRDYEN_SHIFT (0U) /*! RXRDYEN - When 1, enables an interrupt when there is a received character available to be read from the RXDAT register. */ #define USART_INTENSET_RXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_RXRDYEN_SHIFT)) & USART_INTENSET_RXRDYEN_MASK) #define USART_INTENSET_TXRDYEN_MASK (0x4U) #define USART_INTENSET_TXRDYEN_SHIFT (2U) /*! TXRDYEN - When 1, enables an interrupt when the TXDAT register is available to take another character to transmit. */ #define USART_INTENSET_TXRDYEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_TXRDYEN_SHIFT)) & USART_INTENSET_TXRDYEN_MASK) #define USART_INTENSET_TXIDLEEN_MASK (0x8U) #define USART_INTENSET_TXIDLEEN_SHIFT (3U) /*! TXIDLEEN - When 1, enables an interrupt when the transmitter becomes idle (TXIDLE = 1). */ #define USART_INTENSET_TXIDLEEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_TXIDLEEN_SHIFT)) & USART_INTENSET_TXIDLEEN_MASK) #define USART_INTENSET_DELTACTSEN_MASK (0x20U) #define USART_INTENSET_DELTACTSEN_SHIFT (5U) /*! DELTACTSEN - When 1, enables an interrupt when there is a change in the state of the CTS input. */ #define USART_INTENSET_DELTACTSEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_DELTACTSEN_SHIFT)) & USART_INTENSET_DELTACTSEN_MASK) #define USART_INTENSET_TXDISEN_MASK (0x40U) #define USART_INTENSET_TXDISEN_SHIFT (6U) /*! TXDISEN - When 1, enables an interrupt when the transmitter is fully disabled as indicated by * the TXDISINT flag in STAT. See description of the TXDISINT bit for details. */ #define USART_INTENSET_TXDISEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_TXDISEN_SHIFT)) & USART_INTENSET_TXDISEN_MASK) #define USART_INTENSET_OVERRUNEN_MASK (0x100U) #define USART_INTENSET_OVERRUNEN_SHIFT (8U) /*! OVERRUNEN - When 1, enables an interrupt when an overrun error occurred. */ #define USART_INTENSET_OVERRUNEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_OVERRUNEN_SHIFT)) & USART_INTENSET_OVERRUNEN_MASK) #define USART_INTENSET_DELTARXBRKEN_MASK (0x800U) #define USART_INTENSET_DELTARXBRKEN_SHIFT (11U) /*! DELTARXBRKEN - When 1, enables an interrupt when a change of state has occurred in the detection * of a received break condition (break condition asserted or deasserted). */ #define USART_INTENSET_DELTARXBRKEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_DELTARXBRKEN_SHIFT)) & USART_INTENSET_DELTARXBRKEN_MASK) #define USART_INTENSET_STARTEN_MASK (0x1000U) #define USART_INTENSET_STARTEN_SHIFT (12U) /*! STARTEN - When 1, enables an interrupt when a received start bit has been detected. */ #define USART_INTENSET_STARTEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_STARTEN_SHIFT)) & USART_INTENSET_STARTEN_MASK) #define USART_INTENSET_FRAMERREN_MASK (0x2000U) #define USART_INTENSET_FRAMERREN_SHIFT (13U) /*! FRAMERREN - When 1, enables an interrupt when a framing error has been detected. */ #define USART_INTENSET_FRAMERREN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_FRAMERREN_SHIFT)) & USART_INTENSET_FRAMERREN_MASK) #define USART_INTENSET_PARITYERREN_MASK (0x4000U) #define USART_INTENSET_PARITYERREN_SHIFT (14U) /*! PARITYERREN - When 1, enables an interrupt when a parity error has been detected. */ #define USART_INTENSET_PARITYERREN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_PARITYERREN_SHIFT)) & USART_INTENSET_PARITYERREN_MASK) #define USART_INTENSET_RXNOISEEN_MASK (0x8000U) #define USART_INTENSET_RXNOISEEN_SHIFT (15U) /*! RXNOISEEN - When 1, enables an interrupt when noise is detected. */ #define USART_INTENSET_RXNOISEEN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_RXNOISEEN_SHIFT)) & USART_INTENSET_RXNOISEEN_MASK) #define USART_INTENSET_ABERREN_MASK (0x10000U) #define USART_INTENSET_ABERREN_SHIFT (16U) /*! ABERREN - When 1, enables an interrupt when an autobaud error occurs. */ #define USART_INTENSET_ABERREN(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENSET_ABERREN_SHIFT)) & USART_INTENSET_ABERREN_MASK) /*! @} */ /*! @name INTENCLR - Interrupt Enable Clear register. Allows clearing any combination of bits in the INTENSET register. Writing a 1 to any implemented bit position causes the corresponding bit to be cleared. */ /*! @{ */ #define USART_INTENCLR_RXRDYCLR_MASK (0x1U) #define USART_INTENCLR_RXRDYCLR_SHIFT (0U) /*! RXRDYCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_RXRDYCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_RXRDYCLR_SHIFT)) & USART_INTENCLR_RXRDYCLR_MASK) #define USART_INTENCLR_TXRDYCLR_MASK (0x4U) #define USART_INTENCLR_TXRDYCLR_SHIFT (2U) /*! TXRDYCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_TXRDYCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_TXRDYCLR_SHIFT)) & USART_INTENCLR_TXRDYCLR_MASK) #define USART_INTENCLR_TXIDLECLR_MASK (0x8U) #define USART_INTENCLR_TXIDLECLR_SHIFT (3U) /*! TXIDLECLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_TXIDLECLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_TXIDLECLR_SHIFT)) & USART_INTENCLR_TXIDLECLR_MASK) #define USART_INTENCLR_DELTACTSCLR_MASK (0x20U) #define USART_INTENCLR_DELTACTSCLR_SHIFT (5U) /*! DELTACTSCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_DELTACTSCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_DELTACTSCLR_SHIFT)) & USART_INTENCLR_DELTACTSCLR_MASK) #define USART_INTENCLR_TXDISINTCLR_MASK (0x40U) #define USART_INTENCLR_TXDISINTCLR_SHIFT (6U) /*! TXDISINTCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_TXDISINTCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_TXDISINTCLR_SHIFT)) & USART_INTENCLR_TXDISINTCLR_MASK) #define USART_INTENCLR_OVERRUNCLR_MASK (0x100U) #define USART_INTENCLR_OVERRUNCLR_SHIFT (8U) /*! OVERRUNCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_OVERRUNCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_OVERRUNCLR_SHIFT)) & USART_INTENCLR_OVERRUNCLR_MASK) #define USART_INTENCLR_DELTARXBRKCLR_MASK (0x800U) #define USART_INTENCLR_DELTARXBRKCLR_SHIFT (11U) /*! DELTARXBRKCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_DELTARXBRKCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_DELTARXBRKCLR_SHIFT)) & USART_INTENCLR_DELTARXBRKCLR_MASK) #define USART_INTENCLR_STARTCLR_MASK (0x1000U) #define USART_INTENCLR_STARTCLR_SHIFT (12U) /*! STARTCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_STARTCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_STARTCLR_SHIFT)) & USART_INTENCLR_STARTCLR_MASK) #define USART_INTENCLR_FRAMERRCLR_MASK (0x2000U) #define USART_INTENCLR_FRAMERRCLR_SHIFT (13U) /*! FRAMERRCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_FRAMERRCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_FRAMERRCLR_SHIFT)) & USART_INTENCLR_FRAMERRCLR_MASK) #define USART_INTENCLR_PARITYERRCLR_MASK (0x4000U) #define USART_INTENCLR_PARITYERRCLR_SHIFT (14U) /*! PARITYERRCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_PARITYERRCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_PARITYERRCLR_SHIFT)) & USART_INTENCLR_PARITYERRCLR_MASK) #define USART_INTENCLR_RXNOISECLR_MASK (0x8000U) #define USART_INTENCLR_RXNOISECLR_SHIFT (15U) /*! RXNOISECLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_RXNOISECLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_RXNOISECLR_SHIFT)) & USART_INTENCLR_RXNOISECLR_MASK) #define USART_INTENCLR_ABERRCLR_MASK (0x10000U) #define USART_INTENCLR_ABERRCLR_SHIFT (16U) /*! ABERRCLR - Writing 1 clears the corresponding bit in the INTENSET register. */ #define USART_INTENCLR_ABERRCLR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTENCLR_ABERRCLR_SHIFT)) & USART_INTENCLR_ABERRCLR_MASK) /*! @} */ /*! @name RXDAT - Receiver Data register. Contains the last character received. */ /*! @{ */ #define USART_RXDAT_RXDAT_MASK (0x1FFU) #define USART_RXDAT_RXDAT_SHIFT (0U) /*! RXDAT - The USART Receiver Data register contains the next received character. The number of * bits that are relevant depends on the USART configuration settings. */ #define USART_RXDAT_RXDAT(x) (((uint32_t)(((uint32_t)(x)) << USART_RXDAT_RXDAT_SHIFT)) & USART_RXDAT_RXDAT_MASK) /*! @} */ /*! @name RXDATSTAT - Receiver Data with Status register. Combines the last character received with the current USART receive status. Allows DMA or software to recover incoming data and status together. */ /*! @{ */ #define USART_RXDATSTAT_RXDAT_MASK (0x1FFU) #define USART_RXDATSTAT_RXDAT_SHIFT (0U) /*! RXDAT - The USART Receiver Data register contains the next received character. The number of * bits that are relevant depends on the USART configuration settings. */ #define USART_RXDATSTAT_RXDAT(x) (((uint32_t)(((uint32_t)(x)) << USART_RXDATSTAT_RXDAT_SHIFT)) & USART_RXDATSTAT_RXDAT_MASK) #define USART_RXDATSTAT_FRAMERR_MASK (0x2000U) #define USART_RXDATSTAT_FRAMERR_SHIFT (13U) /*! FRAMERR - Framing Error status flag. This bit is valid when there is a character to be read in * the RXDAT register and reflects the status of that character. This bit will set when the * character in RXDAT was received with a missing stop bit at the expected location. This could be an * indication of a baud rate or configuration mismatch with the transmitting source. */ #define USART_RXDATSTAT_FRAMERR(x) (((uint32_t)(((uint32_t)(x)) << USART_RXDATSTAT_FRAMERR_SHIFT)) & USART_RXDATSTAT_FRAMERR_MASK) #define USART_RXDATSTAT_PARITYERR_MASK (0x4000U) #define USART_RXDATSTAT_PARITYERR_SHIFT (14U) /*! PARITYERR - Parity Error status flag. This bit is valid when there is a character to be read in * the RXDAT register and reflects the status of that character. This bit will be set when a * parity error is detected in a received character. */ #define USART_RXDATSTAT_PARITYERR(x) (((uint32_t)(((uint32_t)(x)) << USART_RXDATSTAT_PARITYERR_SHIFT)) & USART_RXDATSTAT_PARITYERR_MASK) #define USART_RXDATSTAT_RXNOISE_MASK (0x8000U) #define USART_RXDATSTAT_RXNOISE_SHIFT (15U) /*! RXNOISE - Received Noise flag. */ #define USART_RXDATSTAT_RXNOISE(x) (((uint32_t)(((uint32_t)(x)) << USART_RXDATSTAT_RXNOISE_SHIFT)) & USART_RXDATSTAT_RXNOISE_MASK) /*! @} */ /*! @name TXDAT - Transmit Data register. Data to be transmitted is written here. */ /*! @{ */ #define USART_TXDAT_TXDAT_MASK (0x1FFU) #define USART_TXDAT_TXDAT_SHIFT (0U) /*! TXDAT - Writing to the USART Transmit Data Register causes the data to be transmitted as soon as * the transmit shift register is available and any conditions for transmitting data are met: * CTS low (if CTSEN bit = 1), TXDIS bit = 0. */ #define USART_TXDAT_TXDAT(x) (((uint32_t)(((uint32_t)(x)) << USART_TXDAT_TXDAT_SHIFT)) & USART_TXDAT_TXDAT_MASK) /*! @} */ /*! @name BRG - Baud Rate Generator register. 16-bit integer baud rate divisor value. */ /*! @{ */ #define USART_BRG_BRGVAL_MASK (0xFFFFU) #define USART_BRG_BRGVAL_SHIFT (0U) /*! BRGVAL - This value is used to divide the USART input clock to determine the baud rate, based on * the input clock from the FRG. 0 = FCLK is used directly by the USART function. 1 = FCLK is * divided by 2 before use by the USART function. 2 = FCLK is divided by 3 before use by the USART * function. 0xFFFF = FCLK is divided by 65,536 before use by the USART function. */ #define USART_BRG_BRGVAL(x) (((uint32_t)(((uint32_t)(x)) << USART_BRG_BRGVAL_SHIFT)) & USART_BRG_BRGVAL_MASK) /*! @} */ /*! @name INTSTAT - Interrupt status register. Reflects interrupts that are currently enabled. */ /*! @{ */ #define USART_INTSTAT_RXRDY_MASK (0x1U) #define USART_INTSTAT_RXRDY_SHIFT (0U) /*! RXRDY - Receiver Ready flag. */ #define USART_INTSTAT_RXRDY(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_RXRDY_SHIFT)) & USART_INTSTAT_RXRDY_MASK) #define USART_INTSTAT_TXRDY_MASK (0x4U) #define USART_INTSTAT_TXRDY_SHIFT (2U) /*! TXRDY - Transmitter Ready flag. */ #define USART_INTSTAT_TXRDY(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_TXRDY_SHIFT)) & USART_INTSTAT_TXRDY_MASK) #define USART_INTSTAT_TXIDLE_MASK (0x8U) #define USART_INTSTAT_TXIDLE_SHIFT (3U) /*! TXIDLE - Transmitter idle status. */ #define USART_INTSTAT_TXIDLE(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_TXIDLE_SHIFT)) & USART_INTSTAT_TXIDLE_MASK) #define USART_INTSTAT_DELTACTS_MASK (0x20U) #define USART_INTSTAT_DELTACTS_SHIFT (5U) /*! DELTACTS - This bit is set when a change in the state of the CTS input is detected. */ #define USART_INTSTAT_DELTACTS(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_DELTACTS_SHIFT)) & USART_INTSTAT_DELTACTS_MASK) #define USART_INTSTAT_TXDISINT_MASK (0x40U) #define USART_INTSTAT_TXDISINT_SHIFT (6U) /*! TXDISINT - Transmitter Disabled Interrupt flag. */ #define USART_INTSTAT_TXDISINT(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_TXDISINT_SHIFT)) & USART_INTSTAT_TXDISINT_MASK) #define USART_INTSTAT_OVERRUNINT_MASK (0x100U) #define USART_INTSTAT_OVERRUNINT_SHIFT (8U) /*! OVERRUNINT - Overrun Error interrupt flag. */ #define USART_INTSTAT_OVERRUNINT(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_OVERRUNINT_SHIFT)) & USART_INTSTAT_OVERRUNINT_MASK) #define USART_INTSTAT_DELTARXBRK_MASK (0x800U) #define USART_INTSTAT_DELTARXBRK_SHIFT (11U) /*! DELTARXBRK - This bit is set when a change in the state of receiver break detection occurs. */ #define USART_INTSTAT_DELTARXBRK(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_DELTARXBRK_SHIFT)) & USART_INTSTAT_DELTARXBRK_MASK) #define USART_INTSTAT_START_MASK (0x1000U) #define USART_INTSTAT_START_SHIFT (12U) /*! START - This bit is set when a start is detected on the receiver input. */ #define USART_INTSTAT_START(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_START_SHIFT)) & USART_INTSTAT_START_MASK) #define USART_INTSTAT_FRAMERRINT_MASK (0x2000U) #define USART_INTSTAT_FRAMERRINT_SHIFT (13U) /*! FRAMERRINT - Framing Error interrupt flag. */ #define USART_INTSTAT_FRAMERRINT(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_FRAMERRINT_SHIFT)) & USART_INTSTAT_FRAMERRINT_MASK) #define USART_INTSTAT_PARITYERRINT_MASK (0x4000U) #define USART_INTSTAT_PARITYERRINT_SHIFT (14U) /*! PARITYERRINT - Parity Error interrupt flag. */ #define USART_INTSTAT_PARITYERRINT(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_PARITYERRINT_SHIFT)) & USART_INTSTAT_PARITYERRINT_MASK) #define USART_INTSTAT_RXNOISEINT_MASK (0x8000U) #define USART_INTSTAT_RXNOISEINT_SHIFT (15U) /*! RXNOISEINT - Received Noise interrupt flag. */ #define USART_INTSTAT_RXNOISEINT(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_RXNOISEINT_SHIFT)) & USART_INTSTAT_RXNOISEINT_MASK) #define USART_INTSTAT_ABERR_MASK (0x10000U) #define USART_INTSTAT_ABERR_SHIFT (16U) /*! ABERR - Autobaud Error flag. */ #define USART_INTSTAT_ABERR(x) (((uint32_t)(((uint32_t)(x)) << USART_INTSTAT_ABERR_SHIFT)) & USART_INTSTAT_ABERR_MASK) /*! @} */ /*! @name OSR - Oversample selection register for asynchronous communication. */ /*! @{ */ #define USART_OSR_OSRVAL_MASK (0xFU) #define USART_OSR_OSRVAL_SHIFT (0U) /*! OSRVAL - Oversample Selection Value. 0 to 3 = not supported 0x4 = 5 function clocks are used to * transmit and receive each data bit. 0x5 = 6 function clocks are used to transmit and receive * each data bit. 0xF= 16 function clocks are used to transmit and receive each data bit. */ #define USART_OSR_OSRVAL(x) (((uint32_t)(((uint32_t)(x)) << USART_OSR_OSRVAL_SHIFT)) & USART_OSR_OSRVAL_MASK) /*! @} */ /*! @name ADDR - Address register for automatic address matching. */ /*! @{ */ #define USART_ADDR_ADDRESS_MASK (0xFFU) #define USART_ADDR_ADDRESS_SHIFT (0U) /*! ADDRESS - 8-bit address used with automatic address matching. Used when address detection is * enabled (ADDRDET in CTL = 1) and automatic address matching is enabled (AUTOADDR in CFG = 1). */ #define USART_ADDR_ADDRESS(x) (((uint32_t)(((uint32_t)(x)) << USART_ADDR_ADDRESS_SHIFT)) & USART_ADDR_ADDRESS_MASK) /*! @} */ /*! * @} */ /* end of group USART_Register_Masks */ /* USART - Peripheral instance base addresses */ /** Peripheral USART0 base address */ #define USART0_BASE (0x40064000u) /** Peripheral USART0 base pointer */ #define USART0 ((USART_Type *)USART0_BASE) /** Array initializer of USART peripheral base addresses */ #define USART_BASE_ADDRS { USART0_BASE } /** Array initializer of USART peripheral base pointers */ #define USART_BASE_PTRS { USART0 } /** Interrupt vectors for the USART peripheral type */ #define USART_IRQS { USART0_IRQn } /*! * @} */ /* end of group USART_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- WKT Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup WKT_Peripheral_Access_Layer WKT Peripheral Access Layer * @{ */ /** WKT - Register Layout Typedef */ typedef struct { __IO uint32_t CTRL; /**< Self wake-up timer control register., offset: 0x0 */ uint8_t RESERVED_0[8]; __IO uint32_t COUNT; /**< Counter register., offset: 0xC */ } WKT_Type; /* ---------------------------------------------------------------------------- -- WKT Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup WKT_Register_Masks WKT Register Masks * @{ */ /*! @name CTRL - Self wake-up timer control register. */ /*! @{ */ #define WKT_CTRL_CLKSEL_MASK (0x1U) #define WKT_CTRL_CLKSEL_SHIFT (0U) /*! CLKSEL - Select the self wake-up timer clock source. Remark: This bit only has an effect if the SEL_EXTCLK bit is not set. * 0b0..Divided IRC clock. This clock runs at 750 kHz and provides time-out periods of up to approximately 95 * minutes in 1.33 us increments. Remark: This clock is not available in not available in Deep-sleep, * power-down, deep power-down modes. Do not select this option if the timer is to be used to wake up from one of these * modes. * 0b1..This is the (nominally) 10 kHz clock and provides time-out periods of up to approximately 119 hours in * 100 us increments. The accuracy of this clock is limited to +/- 40 % over temperature and processing. * Remark: This clock is available in all power modes. Prior to use, the low-power oscillator must be enabled. The * oscillator must also be set to remain active in Deep power-down if needed. */ #define WKT_CTRL_CLKSEL(x) (((uint32_t)(((uint32_t)(x)) << WKT_CTRL_CLKSEL_SHIFT)) & WKT_CTRL_CLKSEL_MASK) #define WKT_CTRL_ALARMFLAG_MASK (0x2U) #define WKT_CTRL_ALARMFLAG_SHIFT (1U) /*! ALARMFLAG - Wake-up or alarm timer flag. * 0b0..No time-out. The self wake-up timer has not timed out. Writing a 0 to has no effect. * 0b1..Time-out. The self wake-up timer has timed out. This flag generates an interrupt request which can wake * up the part from any reduced power mode including Deep power-down if the clock source is the low power * oscillator. Writing a 1 clears this status bit. */ #define WKT_CTRL_ALARMFLAG(x) (((uint32_t)(((uint32_t)(x)) << WKT_CTRL_ALARMFLAG_SHIFT)) & WKT_CTRL_ALARMFLAG_MASK) #define WKT_CTRL_CLEARCTR_MASK (0x4U) #define WKT_CTRL_CLEARCTR_SHIFT (2U) /*! CLEARCTR - Clears the self wake-up timer. * 0b0..No effect. Reading this bit always returns 0. * 0b1..Clear the counter. Counting is halted until a new count value is loaded. */ #define WKT_CTRL_CLEARCTR(x) (((uint32_t)(((uint32_t)(x)) << WKT_CTRL_CLEARCTR_SHIFT)) & WKT_CTRL_CLEARCTR_MASK) #define WKT_CTRL_SEL_EXTCLK_MASK (0x8U) #define WKT_CTRL_SEL_EXTCLK_SHIFT (3U) /*! SEL_EXTCLK - Select external or internal clock source for the self wake-up timer. The internal * clock source is selected by the CLKSEL bit in this register if SET_EXTCLK is set to internal. * 0b0..Internal. The clock source is the internal clock selected by the CLKSEL bit. * 0b1..External. The self wake-up timer uses the external WKTCLKIN pin. */ #define WKT_CTRL_SEL_EXTCLK(x) (((uint32_t)(((uint32_t)(x)) << WKT_CTRL_SEL_EXTCLK_SHIFT)) & WKT_CTRL_SEL_EXTCLK_MASK) /*! @} */ /*! @name COUNT - Counter register. */ /*! @{ */ #define WKT_COUNT_VALUE_MASK (0xFFFFFFFFU) #define WKT_COUNT_VALUE_SHIFT (0U) /*! VALUE - A write to this register pre-loads start count value into the timer and starts the * count-down sequence. A read reflects the current value of the timer. */ #define WKT_COUNT_VALUE(x) (((uint32_t)(((uint32_t)(x)) << WKT_COUNT_VALUE_SHIFT)) & WKT_COUNT_VALUE_MASK) /*! @} */ /*! * @} */ /* end of group WKT_Register_Masks */ /* WKT - Peripheral instance base addresses */ /** Peripheral WKT base address */ #define WKT_BASE (0x40008000u) /** Peripheral WKT base pointer */ #define WKT ((WKT_Type *)WKT_BASE) /** Array initializer of WKT peripheral base addresses */ #define WKT_BASE_ADDRS { WKT_BASE } /** Array initializer of WKT peripheral base pointers */ #define WKT_BASE_PTRS { WKT } /** Interrupt vectors for the WKT peripheral type */ #define WKT_IRQS { WKT_IRQn } /*! * @} */ /* end of group WKT_Peripheral_Access_Layer */ /* ---------------------------------------------------------------------------- -- WWDT Peripheral Access Layer ---------------------------------------------------------------------------- */ /*! * @addtogroup WWDT_Peripheral_Access_Layer WWDT Peripheral Access Layer * @{ */ /** WWDT - Register Layout Typedef */ typedef struct { __IO uint32_t MOD; /**< Watchdog mode register. This register contains the basic mode and status of the Watchdog Timer., offset: 0x0 */ __IO uint32_t TC; /**< Watchdog timer constant register. This 24-bit register determines the time-out value., offset: 0x4 */ __O uint32_t FEED; /**< Watchdog feed sequence register. Writing 0xAA followed by 0x55 to this register reloads the Watchdog timer with the value contained in TC., offset: 0x8 */ __I uint32_t TV; /**< Watchdog timer value register. This 24-bit register reads out the current value of the Watchdog timer., offset: 0xC */ uint8_t RESERVED_0[4]; __IO uint32_t WARNINT; /**< Watchdog Warning Interrupt compare value., offset: 0x14 */ __IO uint32_t WINDOW; /**< Watchdog Window compare value., offset: 0x18 */ } WWDT_Type; /* ---------------------------------------------------------------------------- -- WWDT Register Masks ---------------------------------------------------------------------------- */ /*! * @addtogroup WWDT_Register_Masks WWDT Register Masks * @{ */ /*! @name MOD - Watchdog mode register. This register contains the basic mode and status of the Watchdog Timer. */ /*! @{ */ #define WWDT_MOD_WDEN_MASK (0x1U) #define WWDT_MOD_WDEN_SHIFT (0U) /*! WDEN - Watchdog enable bit. Once this bit is set to one and a watchdog feed is performed, the * watchdog timer will run permanently. * 0b0..Stop. The watchdog timer is stopped. * 0b1..Run. The watchdog timer is running. */ #define WWDT_MOD_WDEN(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_WDEN_SHIFT)) & WWDT_MOD_WDEN_MASK) #define WWDT_MOD_WDRESET_MASK (0x2U) #define WWDT_MOD_WDRESET_SHIFT (1U) /*! WDRESET - Watchdog reset enable bit. Once this bit has been written with a 1 it cannot be re-written with a 0. * 0b0..Interrupt. A watchdog time-out will not cause a chip reset. * 0b1..Reset. A watchdog time-out will cause a chip reset. */ #define WWDT_MOD_WDRESET(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_WDRESET_SHIFT)) & WWDT_MOD_WDRESET_MASK) #define WWDT_MOD_WDTOF_MASK (0x4U) #define WWDT_MOD_WDTOF_SHIFT (2U) /*! WDTOF - Watchdog time-out flag. Set when the watchdog timer times out, by a feed error, or by * events associated with WDPROTECT. Cleared by software writing a 0 to this bit position. Causes a * chip reset if WDRESET = 1. */ #define WWDT_MOD_WDTOF(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_WDTOF_SHIFT)) & WWDT_MOD_WDTOF_MASK) #define WWDT_MOD_WDINT_MASK (0x8U) #define WWDT_MOD_WDINT_SHIFT (3U) /*! WDINT - Warning interrupt flag. Set when the timer is at or below the value in WDWARNINT. * Cleared by software writing a 1 to this bit position. Note that this bit cannot be cleared while the * WARNINT value is equal to the value of the TV register. This can occur if the value of * WARNINT is 0 and the WDRESET bit is 0 when TV decrements to 0. */ #define WWDT_MOD_WDINT(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_WDINT_SHIFT)) & WWDT_MOD_WDINT_MASK) #define WWDT_MOD_WDPROTECT_MASK (0x10U) #define WWDT_MOD_WDPROTECT_SHIFT (4U) /*! WDPROTECT - Watchdog update mode. This bit can be set once by software and is only cleared by a reset. * 0b0..Flexible. The watchdog time-out value (TC) can be changed at any time. * 0b1..Threshold. The watchdog time-out value (TC) can be changed only after the counter is below the value of WDWARNINT and WDWINDOW. */ #define WWDT_MOD_WDPROTECT(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_WDPROTECT_SHIFT)) & WWDT_MOD_WDPROTECT_MASK) #define WWDT_MOD_LOCK_MASK (0x20U) #define WWDT_MOD_LOCK_SHIFT (5U) /*! LOCK - Once this bit is set to one and a watchdog feed is performed, disabling or powering down * the watchdog oscillator is prevented by hardware. This bit can be set once by software and is * only cleared by any reset. */ #define WWDT_MOD_LOCK(x) (((uint32_t)(((uint32_t)(x)) << WWDT_MOD_LOCK_SHIFT)) & WWDT_MOD_LOCK_MASK) /*! @} */ /*! @name TC - Watchdog timer constant register. This 24-bit register determines the time-out value. */ /*! @{ */ #define WWDT_TC_COUNT_MASK (0xFFFFFFU) #define WWDT_TC_COUNT_SHIFT (0U) /*! COUNT - Watchdog time-out value. */ #define WWDT_TC_COUNT(x) (((uint32_t)(((uint32_t)(x)) << WWDT_TC_COUNT_SHIFT)) & WWDT_TC_COUNT_MASK) /*! @} */ /*! @name FEED - Watchdog feed sequence register. Writing 0xAA followed by 0x55 to this register reloads the Watchdog timer with the value contained in TC. */ /*! @{ */ #define WWDT_FEED_FEED_MASK (0xFFU) #define WWDT_FEED_FEED_SHIFT (0U) /*! FEED - Feed value should be 0xAA followed by 0x55. */ #define WWDT_FEED_FEED(x) (((uint32_t)(((uint32_t)(x)) << WWDT_FEED_FEED_SHIFT)) & WWDT_FEED_FEED_MASK) /*! @} */ /*! @name TV - Watchdog timer value register. This 24-bit register reads out the current value of the Watchdog timer. */ /*! @{ */ #define WWDT_TV_COUNT_MASK (0xFFFFFFU) #define WWDT_TV_COUNT_SHIFT (0U) /*! COUNT - Counter timer value. */ #define WWDT_TV_COUNT(x) (((uint32_t)(((uint32_t)(x)) << WWDT_TV_COUNT_SHIFT)) & WWDT_TV_COUNT_MASK) /*! @} */ /*! @name WARNINT - Watchdog Warning Interrupt compare value. */ /*! @{ */ #define WWDT_WARNINT_WARNINT_MASK (0x3FFU) #define WWDT_WARNINT_WARNINT_SHIFT (0U) /*! WARNINT - Watchdog warning interrupt compare value. */ #define WWDT_WARNINT_WARNINT(x) (((uint32_t)(((uint32_t)(x)) << WWDT_WARNINT_WARNINT_SHIFT)) & WWDT_WARNINT_WARNINT_MASK) /*! @} */ /*! @name WINDOW - Watchdog Window compare value. */ /*! @{ */ #define WWDT_WINDOW_WINDOW_MASK (0xFFFFFFU) #define WWDT_WINDOW_WINDOW_SHIFT (0U) /*! WINDOW - Watchdog window value. */ #define WWDT_WINDOW_WINDOW(x) (((uint32_t)(((uint32_t)(x)) << WWDT_WINDOW_WINDOW_SHIFT)) & WWDT_WINDOW_WINDOW_MASK) /*! @} */ /*! * @} */ /* end of group WWDT_Register_Masks */ /* WWDT - Peripheral instance base addresses */ /** Peripheral WWDT base address */ #define WWDT_BASE (0x40000000u) /** Peripheral WWDT base pointer */ #define WWDT ((WWDT_Type *)WWDT_BASE) /** Array initializer of WWDT peripheral base addresses */ #define WWDT_BASE_ADDRS { WWDT_BASE } /** Array initializer of WWDT peripheral base pointers */ #define WWDT_BASE_PTRS { WWDT } /** Interrupt vectors for the WWDT peripheral type */ #define WWDT_IRQS { WDT_IRQn } /*! * @} */ /* end of group WWDT_Peripheral_Access_Layer */ /* ** End of section using anonymous unions */ #if defined(__ARMCC_VERSION) #if (__ARMCC_VERSION >= 6010050) #pragma clang diagnostic pop #else #pragma pop #endif #elif defined(__GNUC__) /* leave anonymous unions enabled */ #elif defined(__IAR_SYSTEMS_ICC__) #pragma language=default #else #error Not supported compiler type #endif /*! * @} */ /* end of group Peripheral_access_layer */ /* ---------------------------------------------------------------------------- -- Macros for use with bit field definitions (xxx_SHIFT, xxx_MASK). ---------------------------------------------------------------------------- */ /*! * @addtogroup Bit_Field_Generic_Macros Macros for use with bit field definitions (xxx_SHIFT, xxx_MASK). * @{ */ #if defined(__ARMCC_VERSION) #if (__ARMCC_VERSION >= 6010050) #pragma clang system_header #endif #elif defined(__IAR_SYSTEMS_ICC__) #pragma system_include #endif /** * @brief Mask and left-shift a bit field value for use in a register bit range. * @param field Name of the register bit field. * @param value Value of the bit field. * @return Masked and shifted value. */ #define NXP_VAL2FLD(field, value) (((value) << (field ## _SHIFT)) & (field ## _MASK)) /** * @brief Mask and right-shift a register value to extract a bit field value. * @param field Name of the register bit field. * @param value Value of the register. * @return Masked and shifted bit field value. */ #define NXP_FLD2VAL(field, value) (((value) & (field ## _MASK)) >> (field ## _SHIFT)) /*! * @} */ /* end of group Bit_Field_Generic_Macros */ /* ---------------------------------------------------------------------------- -- SDK Compatibility ---------------------------------------------------------------------------- */ /*! * @addtogroup SDK_Compatibility_Symbols SDK Compatibility * @{ */ /* No SDK compatibility issues. */ /*! * @} */ /* end of group SDK_Compatibility_Symbols */ #endif /* _LPC834_H_ */