/**************************************************************************//** * @file uuart_reg.h * @version V1.00 * @brief UUART register definition header file * * SPDX-License-Identifier: Apache-2.0 * @copyright (C) 2018 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #ifndef __UUART_REG_H__ #define __UUART_REG_H__ #if defined ( __CC_ARM ) #pragma anon_unions #endif /** @addtogroup REGISTER Control Register @{ */ /** @addtogroup UUART UART Mode of USCI Controller (UUART) Memory Mapped Structure for UUART Controller @{ */ typedef struct { /** * @var UUART_T::CTL * Offset: 0x00 USCI Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[2:0] |FUNMODE |Function Mode * | | |This bit field selects the protocol for this USCI controller. * | | |Selecting a protocol that is not available or a reserved combination disables the USCI. * | | |When switching between two protocols, the USCI has to be disabled before selecting a new protocol. * | | |Simultaneously, the USCI will be reset when user write 000 to FUNMODE. * | | |000 = The USCI is disabled. All protocol related state machines are set to idle state. * | | |001 = The SPI protocol is selected. * | | |010 = The UART protocol is selected. * | | |100 = The I2C protocol is selected. * | | |Note: Other bit combinations are reserved. * @var UUART_T::INTEN * Offset: 0x04 USCI Interrupt Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1] |TXSTIEN |Transmit Start Interrupt Enable Bit * | | |This bit enables the interrupt generation in case of a transmit start event. * | | |0 = The transmit start interrupt Disabled. * | | |1 = The transmit start interrupt Enabled. * |[2] |TXENDIEN |Transmit End Interrupt Enable Bit * | | |This bit enables the interrupt generation in case of a transmit finish event. * | | |0 = The transmit finish interrupt Disabled. * | | |1 = The transmit finish interrupt Enabled. * |[3] |RXSTIEN |Receive Start Interrupt Enable BIt * | | |This bit enables the interrupt generation in case of a receive start event. * | | |0 = The receive start interrupt Disabled. * | | |1 = The receive start interrupt Enabled. * |[4] |RXENDIEN |Receive End Interrupt Enable Bit * | | |This bit enables the interrupt generation in case of a receive finish event. * | | |0 = The receive end interrupt Disabled. * | | |1 = The receive end interrupt Enabled. * @var UUART_T::BRGEN * Offset: 0x08 USCI Baud Rate Generator Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |RCLKSEL |Reference Clock Source Selection * | | |This bit selects the source signal of reference clock (fREF_CLK). * | | |0 = Peripheral device clock fPCLK. * | | |1 = Reserved. * |[1] |PTCLKSEL |Protocol Clock Source Selection * | | |This bit selects the source signal of protocol clock (fPROT_CLK). * | | |0 = Reference clock fREF_CLK. * | | |1 = fREF_CLK2 (its frequency is half of fREF_CLK). * |[3:2] |SPCLKSEL |Sample Clock Source Selection * | | |This bit field used for the clock source selection of a sample clock (fSAMP_CLK) for the protocol processor. * | | |00 = fSAMP_CLK = fDIV_CLK. * | | |01 = fSAMP_CLK = fPROT_CLK. * | | |10 = fSAMP_CLK = fSCLK. * | | |11 = fSAMP_CLK = fREF_CLK. * |[4] |TMCNTEN |Timing Measurement Counter Enable Bit * | | |This bit enables the 10-bit timing measurement counter. * | | |0 = Timing measurement counter is Disabled. * | | |1 = Timing measurement counter is Enabled. * |[5] |TMCNTSRC |Timing Measurement Counter Clock Source Selection * | | |0 = Timing measurement counter with fPROT_CLK. * | | |1 = Timing measurement counter with fDIV_CLK. * |[9:8] |PDSCNT |Pre-divider for Sample Counter * | | |This bit field defines the divide ratio of the clock division from sample clock fSAMP_CLK. * | | |The divided frequency fPDS_CNT = fSAMP_CLK / (PDSCNT+1). * |[14:10] |DSCNT |Denominator for Sample Counter * | | |This bit field defines the divide ratio of the sample clock fSAMP_CLK. * | | |The divided frequency fDS_CNT = fPDS_CNT / (DSCNT+1). * | | |Note: The maximum value of DSCNT is 0xF on UART mode and suggest to set over 4 to confirm the receiver data is sampled in right value. * |[25:16] |CLKDIV |Clock Divider * | | |This bit field defines the ratio between the protocol clock frequency fPROT_CLK and the clock divider frequency fDIV_CLK (fDIV_CLK = fPROT_CLK / (CLKDIV+1) ). * | | |Note: In UART function, it can be updated by hardware in the 4th falling edge of the input data 0x55 when the auto baud rate function (ABREN(UUART_PROTCTL[6])) is enabled. * | | |The revised value is the average bit time between bit 5 and bit 6. * | | |The user can use revised CLKDIV and new BRDETITV (UUART_PROTCTL[24:16]) to calculate the precise baud rate. * @var UUART_T::DATIN0 * Offset: 0x10 USCI Input Data Signal Configuration Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |SYNCSEL |Input Signal Synchronization Selection * | | |This bit selects if the un-synchronized input signal (with optionally inverted) or the synchronized (and optionally filtered) signal can be used as input for the data shift unit. * | | |0 = The un-synchronized signal can be taken as input for the data shift unit. * | | |1 = The synchronized signal can be taken as input for the data shift unit. * |[2] |ININV |Input Signal Inverse Selection * | | |This bit defines the inverter enable of the input asynchronous signal. * | | |0 = The un-synchronized input signal will not be inverted. * | | |1 = The un-synchronized input signal will be inverted. * |[4:3] |EDGEDET |Input Signal Edge Detection Mode * | | |This bit field selects which edge actives the trigger event of input data signal. * | | |00 = The trigger event activation is disabled. * | | |01 = A rising edge activates the trigger event of input data signal. * | | |10 = A falling edge activates the trigger event of input data signal. * | | |11 = Both edges activate the trigger event of input data signal. * | | |Note: In UART function mode, it is suggested to set this bit field as 10. * @var UUART_T::CTLIN0 * Offset: 0x20 USCI Input Control Signal Configuration Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |SYNCSEL |Input Synchronization Signal Selection * | | |This bit selects if the un-synchronized input signal (with optionally inverted) or the synchronized (and optionally filtered) signal can be used as input for the data shift unit. * | | |0 = The un-synchronized signal can be taken as input for the data shift unit. * | | |1 = The synchronized signal can be taken as input for the data shift unit. * |[2] |ININV |Input Signal Inverse Selection * | | |This bit defines the inverter enable of the input asynchronous signal. * | | |0 = The un-synchronized input signal will not be inverted. * | | |1 = The un-synchronized input signal will be inverted. * @var UUART_T::CLKIN * Offset: 0x28 USCI Input Clock Signal Configuration Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |SYNCSEL |Input Synchronization Signal Selection * | | |This bit selects if the un-synchronized input signal or the synchronized (and optionally filtered) signal can be used as input for the data shift unit. * | | |0 = The un-synchronized signal can be taken as input for the data shift unit. * | | |1 = The synchronized signal can be taken as input for the data shift unit. * @var UUART_T::LINECTL * Offset: 0x2C USCI Line Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |LSB |LSB First Transmission Selection * | | |0 = The MSB, which bit of transmit/receive data buffer depends on the setting of DWIDTH, is transmitted/received first. * | | |1 = The LSB, the bit 0 of data buffer, will be transmitted/received first. * |[5] |DATOINV |Data Output Inverse Selection * | | |This bit defines the relation between the internal shift data value and the output data signal of USCIx_DAT1 pin. * | | |0 = The value of USCIx_DAT1 is equal to the data shift register. * | | |1 = The value of USCIx_DAT1 is the inversion of data shift register. * |[7] |CTLOINV |Control Signal Output Inverse Selection * | | |This bit defines the relation between the internal control signal and the output control signal. * | | |0 = No effect. * | | |1 = The control signal will be inverted before its output. * | | |Note: In UART protocol, the control signal means nRTS signal. * |[11:8] |DWIDTH |Word Length of Transmission * | | |This bit field defines the data word length (amount of bits) for reception and transmission. * | | |The data word is always right-aligned in the data buffer. * | | |USCI support word length from 4 to 16 bits. * | | |0x0: The data word contains 16 bits located at bit positions [15:0]. * | | |0x1: Reserved. * | | |0x2: Reserved. * | | |0x3: Reserved. * | | |0x4: The data word contains 4 bits located at bit positions [3:0]. * | | |0x5: The data word contains 5 bits located at bit positions [4:0]. * | | |... * | | |0xF: The data word contains 15 bits located at bit positions [14:0]. * | | |Note: In UART protocol, the length can be configured as 6~13 bits. * @var UUART_T::TXDAT * Offset: 0x30 USCI Transmit Data Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |TXDAT |Transmit Data * | | |Software can use this bit field to write 16-bit transmit data for transmission. * @var UUART_T::RXDAT * Offset: 0x34 USCI Receive Data Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |RXDAT |Received Data * | | |This bit field monitors the received data which stored in receive data buffer. * | | |Note: RXDAT[15:13] indicate the same frame status of BREAK, FRMERR and PARITYERR (UUART_PROTSTS[7:5]). * @var UUART_T::BUFCTL * Offset: 0x38 USCI Transmit/Receive Buffer Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[7] |TXCLR |Clear Transmit Buffer * | | |0 = No effect. * | | |1 = The transmit buffer is cleared (filling level is cleared and output pointer is set to input pointer value). * | | |Should only be used while the buffer is not taking part in data traffic. * | | |Note: It is cleared automatically after one PCLK cycle. * |[14] |RXOVIEN |Receive Buffer Overrun Error Interrupt Enable Bit * | | |0 = Receive overrun interrupt Disabled. * | | |1 = Receive overrun interrupt Enabled. * |[15] |RXCLR |Clear Receive Buffer * | | |0 = No effect. * | | |1 = The receive buffer is cleared (filling level is cleared and output pointer is set to input pointer value). * | | |Should only be used while the buffer is not taking part in data traffic. * | | |Note: It is cleared automatically after one PCLK cycle. * |[16] |TXRST |Transmit Reset * | | |0 = No effect. * | | |1 = Reset the transmit-related counters, state machine, and the content of transmit shift register and data buffer. * | | |Note: It is cleared automatically after one PCLK cycle. * |[17] |RXRST |Receive Reset * | | |0 = No effect. * | | |1 = Reset the receive-related counters, state machine, and the content of receive shift register and data buffer. * | | |Note1: It is cleared automatically after one PCLK cycle. * | | |Note2: It is suggested to check the RXBUSY (UUART_PROTSTS[10]) before this bit will be set to 1. * @var UUART_T::BUFSTS * Offset: 0x3C USCI Transmit/Receive Buffer Status Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |RXEMPTY |Receive Buffer Empty Indicator * | | |0 = Receive buffer is not empty. * | | |1 = Receive buffer is empty. * |[1] |RXFULL |Receive Buffer Full Indicator * | | |0 = Receive buffer is not full. * | | |1 = Receive buffer is full. * |[3] |RXOVIF |Receive Buffer Over-run Error Interrupt Status * | | |This bit indicates that a receive buffer overrun error event has been detected. * | | |If RXOVIEN (UUART_BUFCTL[14]) is enabled, the corresponding interrupt request is activated. * | | |It is cleared by software writes 1 to this bit. * | | |0 = A receive buffer overrun error event has not been detected. * | | |1 = A receive buffer overrun error event has been detected. * |[8] |TXEMPTY |Transmit Buffer Empty Indicator * | | |0 = Transmit buffer is not empty. * | | |1 = Transmit buffer is empty. * |[9] |TXFULL |Transmit Buffer Full Indicator * | | |0 = Transmit buffer is not full. * | | |1 = Transmit buffer is full. * @var UUART_T::PDMACTL * Offset: 0x40 USCI PDMA Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |PDMARST |PDMA Reset * | | |0 = No effect. * | | |1 = Reset the USCI's PDMA control logic. This bit will be cleared to 0 automatically. * |[1] |TXPDMAEN |PDMA Transmit Channel Available * | | |0 = Transmit PDMA function Disabled. * | | |1 = Transmit PDMA function Enabled. * |[2] |RXPDMAEN |PDMA Receive Channel Available * | | |0 = Receive PDMA function Disabled. * | | |1 = Receive PDMA function Enabled. * |[3] |PDMAEN |PDMA Mode Enable Bit * | | |0 = PDMA function Disabled. * | | |1 = PDMA function Enabled. * @var UUART_T::WKCTL * Offset: 0x54 USCI Wake-up Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |WKEN |Wake-up Enable Bit * | | |0 = Wake-up function Disabled. * | | |1 = Wake-up function Enabled. * |[2] |PDBOPT |Power Down Blocking Option * | | |0 = If user attempts to enter Power-down mode by executing WFI while the protocol is in transferring, MCU will stop the transfer and enter Power-down mode immediately. * | | |1 = If user attempts to enter Power-down mode by executing WFI while the protocol is in transferring, the on-going transfer will not be stopped and MCU will enter idle mode immediately. * @var UUART_T::WKSTS * Offset: 0x58 USCI Wake-up Status Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |WKF |Wake-up Flag * | | |When chip is woken up from Power-down mode, this bit is set to 1. * | | |Software can write 1 to clear this bit. * @var UUART_T::PROTCTL * Offset: 0x5C USCI Protocol Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |STOPB |Stop Bits * | | |This bit defines the number of stop bits in an UART frame. * | | |0 = The number of stop bits is 1. * | | |1 = The number of stop bits is 2. * |[1] |PARITYEN |Parity Enable Bit * | | |This bit defines the parity bit is enabled in an UART frame. * | | |0 = The parity bit Disabled. * | | |1 = The parity bit Enabled. * |[2] |EVENPARITY|Even Parity Enable Bit * | | |0 = Odd number of logic 1's is transmitted and checked in each word. * | | |1 = Even number of logic 1's is transmitted and checked in each word. * | | |Note: This bit has effect only when PARITYEN is set. * |[3] |RTSAUTOEN |nRTS Auto-flow Control Enable Bit * | | |When nRTS auto-flow is enabled, if the receiver buffer is full (RXFULL (UUART_BUFSTS[1] =1), the UART will de-assert nRTS signal. * | | |0 = nRTS auto-flow control Disabled. * | | |1 = nRTS auto-flow control Enabled. * | | |Note: This bit has effect only when the RTSAUDIREN is not set. * |[4] |CTSAUTOEN |nCTS Auto-flow Control Enable Bit * | | |When nCTS auto-flow is enabled, the UART will send data to external device when nCTS input assert (UART will not send data to device if nCTS input is dis-asserted). * | | |0 = nCTS auto-flow control Disabled. * | | |1 = nCTS auto-flow control Enabled. * |[5] |RTSAUDIREN|nRTS Auto Direction Enable Bit * | | |When nRTS auto direction is enabled, if the transmitted bytes in the TX buffer is empty, the UART asserted nRTS signal automatically. * | | |0 = nRTS auto direction control Disabled. * | | |1 = nRTS auto direction control Enabled. * | | |Note 1: This bit is used for nRTS auto direction control for RS485. * | | |Note 2: This bit has effect only when the RTSAUTOEN is not set. * |[6] |ABREN |Auto-baud Rate Detect Enable Bit * | | |0 = Auto-baud rate detect function Disabled. * | | |1 = Auto-baud rate detect function Enabled. * | | |Note: When the auto - baud rate detect operation finishes, hardware will clear this bit. * | | |The associated interrupt ABRDETIF (UUART_PROTST[9]) will be generated (If ARBIEN (UUART_PROTIEN [1]) is enabled). * |[9] |DATWKEN |Data Wake-up Mode Enable Bit * | | |0 = Data wake-up mode Disabled. * | | |1 = Data wake-up mode Enabled. * |[10] |CTSWKEN |nCTS Wake-up Mode Enable Bit * | | |0 = nCTS wake-up mode Disabled. * | | |1 = nCTS wake-up mode Enabled. * |[14:11] |WAKECNT |Wake-up Counter * | | |These bits field indicate how many clock cycle selected by fPDS_CNT do the slave can get the 1st bit (start bit) when the device is wake-up from Power-down mode. * |[24:16] |BRDETITV |Baud Rate Detection Interval * | | |This bit fields indicate how many clock cycle selected by TMCNTSRC (UUART_BRGEN [5]) does the slave calculates the baud rate in one bits. * | | |The order of the bus shall be 1 and 0 step by step (e.g. * | | |the input data pattern shall be 0x55). * | | |The user can read the value to know the current input baud rate of the bus whenever the ABRDETIF (UUART_PROTSTS[9]) is set. * | | |Note: This bit can be cleared to 0 by software writing '0' to the BRDETITV. * |[26] |STICKEN |Stick Parity Enable Bit * | | |0 = Stick parity Disabled. * | | |1 = Stick parity Enabled. * | | |Note: Refer to RS-485 Support section for detailed information. * |[29] |BCEN |Transmit Break Control Enable Bit * | | |0 = Transmit Break Control Disabled. * | | |1 = Transmit Break Control Enabled. * | | |Note: When this bit is set to logic 1, the serial data output (TX) is forced to the Spacing State (logic 0). * | | |This bit acts only on TX line and has no effect on the transmitter logic. * |[31] |PROTEN |UART Protocol Enable Bit * | | |0 = UART Protocol Disabled. * | | |1 = UART Protocol Enabled. * @var UUART_T::PROTIEN * Offset: 0x60 USCI Protocol Interrupt Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1] |ABRIEN |Auto-baud Rate Interrupt Enable Bit * | | |0 = Auto-baud rate interrupt Disabled. * | | |1 = Auto-baud rate interrupt Enabled. * |[2] |RLSIEN |Receive Line Status Interrupt Enable Bit * | | |0 = Receive line status interrupt Disabled. * | | |1 = Receive line status interrupt Enabled. * | | |Note: UUART_PROTSTS[7:5] indicates the current interrupt event for receive line status interrupt. * @var UUART_T::PROTSTS * Offset: 0x64 USCI Protocol Status Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1] |TXSTIF |Transmit Start Interrupt Flag * | | |0 = A transmit start interrupt status has not occurred. * | | |1 = A transmit start interrupt status has occurred. * | | |Note1: It is cleared by software writing one into this bit. * | | |Note2: Used for user to load next transmit data when there is no data in transmit buffer. * |[2] |TXENDIF |Transmit End Interrupt Flag * | | |0 = A transmit end interrupt status has not occurred. * | | |1 = A transmit end interrupt status has occurred. * | | |Note: It is cleared by software writing 1 into this bit. * |[3] |RXSTIF |Receive Start Interrupt Flag * | | |0 = A receive start interrupt status has not occurred. * | | |1 = A receive start interrupt status has occurred. * | | |Note: It is cleared by software writing 1 into this bit. * |[4] |RXENDIF |Receive End Interrupt Flag * | | |0 = A receive finish interrupt status has not occurred. * | | |1 = A receive finish interrupt status has occurred. * | | |Note: It is cleared by software writing 1 into this bit. * |[5] |PARITYERR |Parity Error Flag * | | |This bit is set to logic 1 whenever the received character does not have a valid "parity bit". * | | |0 = No parity error is generated. * | | |1 = Parity error is generated. * | | |Note: This bit can be cleared by writing "1" among the BREAK, FRMERR and PARITYERR bits. * |[6] |FRMERR |Framing Error Flag * | | |This bit is set to logic 1 whenever the received character does not have a valid "stop bit" (that is, the stop bit following the last data bit or parity bit is detected as logic 0). * | | |0 = No framing error is generated. * | | |1 = Framing error is generated. * | | |Note: This bit can be cleared by writing "1" among the BREAK, FRMERR and PARITYERR bits. * |[7] |BREAK |Break Flag * | | |This bit is set to logic 1 whenever the received data input (RX) is held in the "spacing state" (logic 0) for longer than a full word transmission time (that is, the total time of "start bit" + data bits + parity + stop bits). * | | |0 = No Break is generated. * | | |1 = Break is generated in the receiver bus. * | | |Note: This bit can be cleared by writing "1" among the BREAK, FRMERR and PARITYERR bits. * |[9] |ABRDETIF |Auto-baud Rate Interrupt Flag * | | |This bit is set when auto-baud rate detection is done among the falling edge of the input data. * | | |If the ABRIEN (UUART_PROTCTL[6]) is set, the auto-baud rate interrupt will be generated. * | | |This bit can be set 4 times when the input data pattern is 0x55 and it is cleared before the next falling edge of the input bus. * | | |0 = Auto-baud rate detect function is not done. * | | |1 = One Bit auto-baud rate detect function is done. * | | |Note: This bit can be cleared by writing "1" to it. * |[10] |RXBUSY |RX Bus Status Flag (Read Only) * | | |This bit indicates the busy status of the receiver. * | | |0 = The receiver is Idle. * | | |1 = The receiver is BUSY. * |[11] |ABERRSTS |Auto-baud Rate Error Status * | | |This bit is set when auto-baud rate detection counter overrun. * | | |When the auto-baud rate counter overrun, the user shall revise the CLKDIV (UUART_BRGEN[25:16]) value and enable ABREN (UUART_PROTCTL[6]) to detect the correct baud rate again. * | | |0 = Auto-baud rate detect counter is not overrun. * | | |1 = Auto-baud rate detect counter is overrun. * | | |Note 1: This bit is set at the same time of ABRDETIF. * | | |Note 2: This bit can be cleared by writing "1" to ABRDETIF or ABERRSTS. * |[16] |CTSSYNCLV |nCTS Synchronized Level Status (Read Only) * | | |This bit used to indicate the current status of the internal synchronized nCTS signal. * | | |0 = The internal synchronized nCTS is low. * | | |1 = The internal synchronized nCTS is high. * |[17] |CTSLV |nCTS Pin Status (Read Only) * | | |This bit used to monitor the current status of nCTS pin input. * | | |0 = nCTS pin input is low level voltage logic state. * | | |1 = nCTS pin input is high level voltage logic state. */ __IO uint32_t CTL; /*!< [0x0000] USCI Control Register */ __IO uint32_t INTEN; /*!< [0x0004] USCI Interrupt Enable Register */ __IO uint32_t BRGEN; /*!< [0x0008] USCI Baud Rate Generator Register */ __I uint32_t RESERVE0[1]; __IO uint32_t DATIN0; /*!< [0x0010] USCI Input Data Signal Configuration Register 0 */ __I uint32_t RESERVE1[3]; __IO uint32_t CTLIN0; /*!< [0x0020] USCI Input Control Signal Configuration Register 0 */ __I uint32_t RESERVE2[1]; __IO uint32_t CLKIN; /*!< [0x0028] USCI Input Clock Signal Configuration Register */ __IO uint32_t LINECTL; /*!< [0x002c] USCI Line Control Register */ __O uint32_t TXDAT; /*!< [0x0030] USCI Transmit Data Register */ __I uint32_t RXDAT; /*!< [0x0034] USCI Receive Data Register */ __IO uint32_t BUFCTL; /*!< [0x0038] USCI Transmit/Receive Buffer Control Register */ __IO uint32_t BUFSTS; /*!< [0x003c] USCI Transmit/Receive Buffer Status Register */ __IO uint32_t PDMACTL; /*!< [0x0040] USCI PDMA Control Register */ __I uint32_t RESERVE3[4]; __IO uint32_t WKCTL; /*!< [0x0054] USCI Wake-up Control Register */ __IO uint32_t WKSTS; /*!< [0x0058] USCI Wake-up Status Register */ __IO uint32_t PROTCTL; /*!< [0x005c] USCI Protocol Control Register */ __IO uint32_t PROTIEN; /*!< [0x0060] USCI Protocol Interrupt Enable Register */ __IO uint32_t PROTSTS; /*!< [0x0064] USCI Protocol Status Register */ } UUART_T; /** @addtogroup UUART_CONST UUART Bit Field Definition Constant Definitions for UUART Controller @{ */ #define UUART_CTL_FUNMODE_Pos (0) /*!< UUART_T::CTL: FUNMODE Position */ #define UUART_CTL_FUNMODE_Msk (0x7ul << UUART_CTL_FUNMODE_Pos) /*!< UUART_T::CTL: FUNMODE Mask */ #define UUART_INTEN_TXSTIEN_Pos (1) /*!< UUART_T::INTEN: TXSTIEN Position */ #define UUART_INTEN_TXSTIEN_Msk (0x1ul << UUART_INTEN_TXSTIEN_Pos) /*!< UUART_T::INTEN: TXSTIEN Mask */ #define UUART_INTEN_TXENDIEN_Pos (2) /*!< UUART_T::INTEN: TXENDIEN Position */ #define UUART_INTEN_TXENDIEN_Msk (0x1ul << UUART_INTEN_TXENDIEN_Pos) /*!< UUART_T::INTEN: TXENDIEN Mask */ #define UUART_INTEN_RXSTIEN_Pos (3) /*!< UUART_T::INTEN: RXSTIEN Position */ #define UUART_INTEN_RXSTIEN_Msk (0x1ul << UUART_INTEN_RXSTIEN_Pos) /*!< UUART_T::INTEN: RXSTIEN Mask */ #define UUART_INTEN_RXENDIEN_Pos (4) /*!< UUART_T::INTEN: RXENDIEN Position */ #define UUART_INTEN_RXENDIEN_Msk (0x1ul << UUART_INTEN_RXENDIEN_Pos) /*!< UUART_T::INTEN: RXENDIEN Mask */ #define UUART_BRGEN_RCLKSEL_Pos (0) /*!< UUART_T::BRGEN: RCLKSEL Position */ #define UUART_BRGEN_RCLKSEL_Msk (0x1ul << UUART_BRGEN_RCLKSEL_Pos) /*!< UUART_T::BRGEN: RCLKSEL Mask */ #define UUART_BRGEN_PTCLKSEL_Pos (1) /*!< UUART_T::BRGEN: PTCLKSEL Position */ #define UUART_BRGEN_PTCLKSEL_Msk (0x1ul << UUART_BRGEN_PTCLKSEL_Pos) /*!< UUART_T::BRGEN: PTCLKSEL Mask */ #define UUART_BRGEN_SPCLKSEL_Pos (2) /*!< UUART_T::BRGEN: SPCLKSEL Position */ #define UUART_BRGEN_SPCLKSEL_Msk (0x3ul << UUART_BRGEN_SPCLKSEL_Pos) /*!< UUART_T::BRGEN: SPCLKSEL Mask */ #define UUART_BRGEN_TMCNTEN_Pos (4) /*!< UUART_T::BRGEN: TMCNTEN Position */ #define UUART_BRGEN_TMCNTEN_Msk (0x1ul << UUART_BRGEN_TMCNTEN_Pos) /*!< UUART_T::BRGEN: TMCNTEN Mask */ #define UUART_BRGEN_TMCNTSRC_Pos (5) /*!< UUART_T::BRGEN: TMCNTSRC Position */ #define UUART_BRGEN_TMCNTSRC_Msk (0x1ul << UUART_BRGEN_TMCNTSRC_Pos) /*!< UUART_T::BRGEN: TMCNTSRC Mask */ #define UUART_BRGEN_PDSCNT_Pos (8) /*!< UUART_T::BRGEN: PDSCNT Position */ #define UUART_BRGEN_PDSCNT_Msk (0x3ul << UUART_BRGEN_PDSCNT_Pos) /*!< UUART_T::BRGEN: PDSCNT Mask */ #define UUART_BRGEN_DSCNT_Pos (10) /*!< UUART_T::BRGEN: DSCNT Position */ #define UUART_BRGEN_DSCNT_Msk (0x1ful << UUART_BRGEN_DSCNT_Pos) /*!< UUART_T::BRGEN: DSCNT Mask */ #define UUART_BRGEN_CLKDIV_Pos (16) /*!< UUART_T::BRGEN: CLKDIV Position */ #define UUART_BRGEN_CLKDIV_Msk (0x3fful << UUART_BRGEN_CLKDIV_Pos) /*!< UUART_T::BRGEN: CLKDIV Mask */ #define UUART_DATIN0_SYNCSEL_Pos (0) /*!< UUART_T::DATIN0: SYNCSEL Position */ #define UUART_DATIN0_SYNCSEL_Msk (0x1ul << UUART_DATIN0_SYNCSEL_Pos) /*!< UUART_T::DATIN0: SYNCSEL Mask */ #define UUART_DATIN0_ININV_Pos (2) /*!< UUART_T::DATIN0: ININV Position */ #define UUART_DATIN0_ININV_Msk (0x1ul << UUART_DATIN0_ININV_Pos) /*!< UUART_T::DATIN0: ININV Mask */ #define UUART_DATIN0_EDGEDET_Pos (3) /*!< UUART_T::DATIN0: EDGEDET Position */ #define UUART_DATIN0_EDGEDET_Msk (0x3ul << UUART_DATIN0_EDGEDET_Pos) /*!< UUART_T::DATIN0: EDGEDET Mask */ #define UUART_CTLIN0_SYNCSEL_Pos (0) /*!< UUART_T::CTLIN0: SYNCSEL Position */ #define UUART_CTLIN0_SYNCSEL_Msk (0x1ul << UUART_CTLIN0_SYNCSEL_Pos) /*!< UUART_T::CTLIN0: SYNCSEL Mask */ #define UUART_CTLIN0_ININV_Pos (2) /*!< UUART_T::CTLIN0: ININV Position */ #define UUART_CTLIN0_ININV_Msk (0x1ul << UUART_CTLIN0_ININV_Pos) /*!< UUART_T::CTLIN0: ININV Mask */ #define UUART_CLKIN_SYNCSEL_Pos (0) /*!< UUART_T::CLKIN: SYNCSEL Position */ #define UUART_CLKIN_SYNCSEL_Msk (0x1ul << UUART_CLKIN_SYNCSEL_Pos) /*!< UUART_T::CLKIN: SYNCSEL Mask */ #define UUART_LINECTL_LSB_Pos (0) /*!< UUART_T::LINECTL: LSB Position */ #define UUART_LINECTL_LSB_Msk (0x1ul << UUART_LINECTL_LSB_Pos) /*!< UUART_T::LINECTL: LSB Mask */ #define UUART_LINECTL_DATOINV_Pos (5) /*!< UUART_T::LINECTL: DATOINV Position */ #define UUART_LINECTL_DATOINV_Msk (0x1ul << UUART_LINECTL_DATOINV_Pos) /*!< UUART_T::LINECTL: DATOINV Mask */ #define UUART_LINECTL_CTLOINV_Pos (7) /*!< UUART_T::LINECTL: CTLOINV Position */ #define UUART_LINECTL_CTLOINV_Msk (0x1ul << UUART_LINECTL_CTLOINV_Pos) /*!< UUART_T::LINECTL: CTLOINV Mask */ #define UUART_LINECTL_DWIDTH_Pos (8) /*!< UUART_T::LINECTL: DWIDTH Position */ #define UUART_LINECTL_DWIDTH_Msk (0xful << UUART_LINECTL_DWIDTH_Pos) /*!< UUART_T::LINECTL: DWIDTH Mask */ #define UUART_TXDAT_TXDAT_Pos (0) /*!< UUART_T::TXDAT: TXDAT Position */ #define UUART_TXDAT_TXDAT_Msk (0xfffful << UUART_TXDAT_TXDAT_Pos) /*!< UUART_T::TXDAT: TXDAT Mask */ #define UUART_RXDAT_RXDAT_Pos (0) /*!< UUART_T::RXDAT: RXDAT Position */ #define UUART_RXDAT_RXDAT_Msk (0xfffful << UUART_RXDAT_RXDAT_Pos) /*!< UUART_T::RXDAT: RXDAT Mask */ #define UUART_BUFCTL_TXCLR_Pos (7) /*!< UUART_T::BUFCTL: TXCLR Position */ #define UUART_BUFCTL_TXCLR_Msk (0x1ul << UUART_BUFCTL_TXCLR_Pos) /*!< UUART_T::BUFCTL: TXCLR Mask */ #define UUART_BUFCTL_RXOVIEN_Pos (14) /*!< UUART_T::BUFCTL: RXOVIEN Position */ #define UUART_BUFCTL_RXOVIEN_Msk (0x1ul << UUART_BUFCTL_RXOVIEN_Pos) /*!< UUART_T::BUFCTL: RXOVIEN Mask */ #define UUART_BUFCTL_RXCLR_Pos (15) /*!< UUART_T::BUFCTL: RXCLR Position */ #define UUART_BUFCTL_RXCLR_Msk (0x1ul << UUART_BUFCTL_RXCLR_Pos) /*!< UUART_T::BUFCTL: RXCLR Mask */ #define UUART_BUFCTL_TXRST_Pos (16) /*!< UUART_T::BUFCTL: TXRST Position */ #define UUART_BUFCTL_TXRST_Msk (0x1ul << UUART_BUFCTL_TXRST_Pos) /*!< UUART_T::BUFCTL: TXRST Mask */ #define UUART_BUFCTL_RXRST_Pos (17) /*!< UUART_T::BUFCTL: RXRST Position */ #define UUART_BUFCTL_RXRST_Msk (0x1ul << UUART_BUFCTL_RXRST_Pos) /*!< UUART_T::BUFCTL: RXRST Mask */ #define UUART_BUFSTS_RXEMPTY_Pos (0) /*!< UUART_T::BUFSTS: RXEMPTY Position */ #define UUART_BUFSTS_RXEMPTY_Msk (0x1ul << UUART_BUFSTS_RXEMPTY_Pos) /*!< UUART_T::BUFSTS: RXEMPTY Mask */ #define UUART_BUFSTS_RXFULL_Pos (1) /*!< UUART_T::BUFSTS: RXFULL Position */ #define UUART_BUFSTS_RXFULL_Msk (0x1ul << UUART_BUFSTS_RXFULL_Pos) /*!< UUART_T::BUFSTS: RXFULL Mask */ #define UUART_BUFSTS_RXOVIF_Pos (3) /*!< UUART_T::BUFSTS: RXOVIF Position */ #define UUART_BUFSTS_RXOVIF_Msk (0x1ul << UUART_BUFSTS_RXOVIF_Pos) /*!< UUART_T::BUFSTS: RXOVIF Mask */ #define UUART_BUFSTS_TXEMPTY_Pos (8) /*!< UUART_T::BUFSTS: TXEMPTY Position */ #define UUART_BUFSTS_TXEMPTY_Msk (0x1ul << UUART_BUFSTS_TXEMPTY_Pos) /*!< UUART_T::BUFSTS: TXEMPTY Mask */ #define UUART_BUFSTS_TXFULL_Pos (9) /*!< UUART_T::BUFSTS: TXFULL Position */ #define UUART_BUFSTS_TXFULL_Msk (0x1ul << UUART_BUFSTS_TXFULL_Pos) /*!< UUART_T::BUFSTS: TXFULL Mask */ #define UUART_PDMACTL_PDMARST_Pos (0) /*!< UUART_T::PDMACTL: PDMARST Position */ #define UUART_PDMACTL_PDMARST_Msk (0x1ul << UUART_PDMACTL_PDMARST_Pos) /*!< UUART_T::PDMACTL: PDMARST Mask */ #define UUART_PDMACTL_TXPDMAEN_Pos (1) /*!< UUART_T::PDMACTL: TXPDMAEN Position*/ #define UUART_PDMACTL_TXPDMAEN_Msk (0x1ul << UUART_PDMACTL_TXPDMAEN_Pos) /*!< UUART_T::PDMACTL: TXPDMAEN Mask */ #define UUART_PDMACTL_RXPDMAEN_Pos (2) /*!< UUART_T::PDMACTL: RXPDMAEN Position*/ #define UUART_PDMACTL_RXPDMAEN_Msk (0x1ul << UUART_PDMACTL_RXPDMAEN_Pos) /*!< UUART_T::PDMACTL: RXPDMAEN Mask */ #define UUART_PDMACTL_PDMAEN_Pos (3) /*!< UUART_T::PDMACTL: PDMAEN Position */ #define UUART_PDMACTL_PDMAEN_Msk (0x1ul << UUART_PDMACTL_PDMAEN_Pos) /*!< UUART_T::PDMACTL: PDMAEN Mask */ #define UUART_WKCTL_WKEN_Pos (0) /*!< UUART_T::WKCTL: WKEN Position */ #define UUART_WKCTL_WKEN_Msk (0x1ul << UUART_WKCTL_WKEN_Pos) /*!< UUART_T::WKCTL: WKEN Mask */ #define UUART_WKCTL_PDBOPT_Pos (2) /*!< UUART_T::WKCTL: PDBOPT Position */ #define UUART_WKCTL_PDBOPT_Msk (0x1ul << UUART_WKCTL_PDBOPT_Pos) /*!< UUART_T::WKCTL: PDBOPT Mask */ #define UUART_WKSTS_WKF_Pos (0) /*!< UUART_T::WKSTS: WKF Position */ #define UUART_WKSTS_WKF_Msk (0x1ul << UUART_WKSTS_WKF_Pos) /*!< UUART_T::WKSTS: WKF Mask */ #define UUART_PROTCTL_STOPB_Pos (0) /*!< UUART_T::PROTCTL: STOPB Position */ #define UUART_PROTCTL_STOPB_Msk (0x1ul << UUART_PROTCTL_STOPB_Pos) /*!< UUART_T::PROTCTL: STOPB Mask */ #define UUART_PROTCTL_PARITYEN_Pos (1) /*!< UUART_T::PROTCTL: PARITYEN Position*/ #define UUART_PROTCTL_PARITYEN_Msk (0x1ul << UUART_PROTCTL_PARITYEN_Pos) /*!< UUART_T::PROTCTL: PARITYEN Mask */ #define UUART_PROTCTL_EVENPARITY_Pos (2) /*!< UUART_T::PROTCTL: EVENPARITY Position*/ #define UUART_PROTCTL_EVENPARITY_Msk (0x1ul << UUART_PROTCTL_EVENPARITY_Pos) /*!< UUART_T::PROTCTL: EVENPARITY Mask */ #define UUART_PROTCTL_RTSAUTOEN_Pos (3) /*!< UUART_T::PROTCTL: RTSAUTOEN Position*/ #define UUART_PROTCTL_RTSAUTOEN_Msk (0x1ul << UUART_PROTCTL_RTSAUTOEN_Pos) /*!< UUART_T::PROTCTL: RTSAUTOEN Mask */ #define UUART_PROTCTL_CTSAUTOEN_Pos (4) /*!< UUART_T::PROTCTL: CTSAUTOEN Position*/ #define UUART_PROTCTL_CTSAUTOEN_Msk (0x1ul << UUART_PROTCTL_CTSAUTOEN_Pos) /*!< UUART_T::PROTCTL: CTSAUTOEN Mask */ #define UUART_PROTCTL_RTSAUDIREN_Pos (5) /*!< UUART_T::PROTCTL: RTSAUDIREN Position*/ #define UUART_PROTCTL_RTSAUDIREN_Msk (0x1ul << UUART_PROTCTL_RTSAUDIREN_Pos) /*!< UUART_T::PROTCTL: RTSAUDIREN Mask */ #define UUART_PROTCTL_ABREN_Pos (6) /*!< UUART_T::PROTCTL: ABREN Position */ #define UUART_PROTCTL_ABREN_Msk (0x1ul << UUART_PROTCTL_ABREN_Pos) /*!< UUART_T::PROTCTL: ABREN Mask */ #define UUART_PROTCTL_DATWKEN_Pos (9) /*!< UUART_T::PROTCTL: DATWKEN Position */ #define UUART_PROTCTL_DATWKEN_Msk (0x1ul << UUART_PROTCTL_DATWKEN_Pos) /*!< UUART_T::PROTCTL: DATWKEN Mask */ #define UUART_PROTCTL_CTSWKEN_Pos (10) /*!< UUART_T::PROTCTL: CTSWKEN Position */ #define UUART_PROTCTL_CTSWKEN_Msk (0x1ul << UUART_PROTCTL_CTSWKEN_Pos) /*!< UUART_T::PROTCTL: CTSWKEN Mask */ #define UUART_PROTCTL_WAKECNT_Pos (11) /*!< UUART_T::PROTCTL: WAKECNT Position */ #define UUART_PROTCTL_WAKECNT_Msk (0xful << UUART_PROTCTL_WAKECNT_Pos) /*!< UUART_T::PROTCTL: WAKECNT Mask */ #define UUART_PROTCTL_BRDETITV_Pos (16) /*!< UUART_T::PROTCTL: BRDETITV Position*/ #define UUART_PROTCTL_BRDETITV_Msk (0x1fful << UUART_PROTCTL_BRDETITV_Pos) /*!< UUART_T::PROTCTL: BRDETITV Mask */ #define UUART_PROTCTL_STICKEN_Pos (26) /*!< UUART_T::PROTCTL: STICKEN Position */ #define UUART_PROTCTL_STICKEN_Msk (0x1ul << UUART_PROTCTL_STICKEN_Pos) /*!< UUART_T::PROTCTL: STICKEN Mask */ #define UUART_PROTCTL_BCEN_Pos (29) /*!< UUART_T::PROTCTL: BCEN Position */ #define UUART_PROTCTL_BCEN_Msk (0x1ul << UUART_PROTCTL_BCEN_Pos) /*!< UUART_T::PROTCTL: BCEN Mask */ #define UUART_PROTCTL_PROTEN_Pos (31) /*!< UUART_T::PROTCTL: PROTEN Position */ #define UUART_PROTCTL_PROTEN_Msk (0x1ul << UUART_PROTCTL_PROTEN_Pos) /*!< UUART_T::PROTCTL: PROTEN Mask */ #define UUART_PROTIEN_ABRIEN_Pos (1) /*!< UUART_T::PROTIEN: ABRIEN Position */ #define UUART_PROTIEN_ABRIEN_Msk (0x1ul << UUART_PROTIEN_ABRIEN_Pos) /*!< UUART_T::PROTIEN: ABRIEN Mask */ #define UUART_PROTIEN_RLSIEN_Pos (2) /*!< UUART_T::PROTIEN: RLSIEN Position */ #define UUART_PROTIEN_RLSIEN_Msk (0x1ul << UUART_PROTIEN_RLSIEN_Pos) /*!< UUART_T::PROTIEN: RLSIEN Mask */ #define UUART_PROTSTS_TXSTIF_Pos (1) /*!< UUART_T::PROTSTS: TXSTIF Position */ #define UUART_PROTSTS_TXSTIF_Msk (0x1ul << UUART_PROTSTS_TXSTIF_Pos) /*!< UUART_T::PROTSTS: TXSTIF Mask */ #define UUART_PROTSTS_TXENDIF_Pos (2) /*!< UUART_T::PROTSTS: TXENDIF Position */ #define UUART_PROTSTS_TXENDIF_Msk (0x1ul << UUART_PROTSTS_TXENDIF_Pos) /*!< UUART_T::PROTSTS: TXENDIF Mask */ #define UUART_PROTSTS_RXSTIF_Pos (3) /*!< UUART_T::PROTSTS: RXSTIF Position */ #define UUART_PROTSTS_RXSTIF_Msk (0x1ul << UUART_PROTSTS_RXSTIF_Pos) /*!< UUART_T::PROTSTS: RXSTIF Mask */ #define UUART_PROTSTS_RXENDIF_Pos (4) /*!< UUART_T::PROTSTS: RXENDIF Position */ #define UUART_PROTSTS_RXENDIF_Msk (0x1ul << UUART_PROTSTS_RXENDIF_Pos) /*!< UUART_T::PROTSTS: RXENDIF Mask */ #define UUART_PROTSTS_PARITYERR_Pos (5) /*!< UUART_T::PROTSTS: PARITYERR Position*/ #define UUART_PROTSTS_PARITYERR_Msk (0x1ul << UUART_PROTSTS_PARITYERR_Pos) /*!< UUART_T::PROTSTS: PARITYERR Mask */ #define UUART_PROTSTS_FRMERR_Pos (6) /*!< UUART_T::PROTSTS: FRMERR Position */ #define UUART_PROTSTS_FRMERR_Msk (0x1ul << UUART_PROTSTS_FRMERR_Pos) /*!< UUART_T::PROTSTS: FRMERR Mask */ #define UUART_PROTSTS_BREAK_Pos (7) /*!< UUART_T::PROTSTS: BREAK Position */ #define UUART_PROTSTS_BREAK_Msk (0x1ul << UUART_PROTSTS_BREAK_Pos) /*!< UUART_T::PROTSTS: BREAK Mask */ #define UUART_PROTSTS_ABRDETIF_Pos (9) /*!< UUART_T::PROTSTS: ABRDETIF Position*/ #define UUART_PROTSTS_ABRDETIF_Msk (0x1ul << UUART_PROTSTS_ABRDETIF_Pos) /*!< UUART_T::PROTSTS: ABRDETIF Mask */ #define UUART_PROTSTS_RXBUSY_Pos (10) /*!< UUART_T::PROTSTS: RXBUSY Position */ #define UUART_PROTSTS_RXBUSY_Msk (0x1ul << UUART_PROTSTS_RXBUSY_Pos) /*!< UUART_T::PROTSTS: RXBUSY Mask */ #define UUART_PROTSTS_ABERRSTS_Pos (11) /*!< UUART_T::PROTSTS: ABERRSTS Position*/ #define UUART_PROTSTS_ABERRSTS_Msk (0x1ul << UUART_PROTSTS_ABERRSTS_Pos) /*!< UUART_T::PROTSTS: ABERRSTS Mask */ #define UUART_PROTSTS_CTSSYNCLV_Pos (16) /*!< UUART_T::PROTSTS: CTSSYNCLV Position*/ #define UUART_PROTSTS_CTSSYNCLV_Msk (0x1ul << UUART_PROTSTS_CTSSYNCLV_Pos) /*!< UUART_T::PROTSTS: CTSSYNCLV Mask */ #define UUART_PROTSTS_CTSLV_Pos (17) /*!< UUART_T::PROTSTS: CTSLV Position */ #define UUART_PROTSTS_CTSLV_Msk (0x1ul << UUART_PROTSTS_CTSLV_Pos) /*!< UUART_T::PROTSTS: CTSLV Mask */ /**@}*/ /* UUART_CONST */ /**@}*/ /* end of UUART register group */ /**@}*/ /* end of REGISTER group */ #if defined ( __CC_ARM ) #pragma no_anon_unions #endif #endif /* __UUART_REG_H__ */