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targets/TARGET_NUVOTON/TARGET_M480/serial_api.c

Committer:
AnnaBridge
Date:
2017-10-25
Revision:
177:447f873cad2f
Parent:
172:7d866c31b3c5
Child:
185:08ed48f1de7f

File content as of revision 177:447f873cad2f:

/* mbed Microcontroller Library
 * Copyright (c) 2015-2016 Nuvoton
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#include "serial_api.h"

#if DEVICE_SERIAL

#include "cmsis.h"
#include "mbed_error.h"
#include "mbed_assert.h"
#include "PeripheralPins.h"
#include "nu_modutil.h"
#include "nu_bitutil.h"
#include <string.h>

#if DEVICE_SERIAL_ASYNCH
#include "dma_api.h"
#include "dma.h"
#endif

struct nu_uart_var {
    uint32_t    ref_cnt;                // Reference count of the H/W module
    serial_t *  obj;
    uint32_t    fifo_size_tx;
    uint32_t    fifo_size_rx;
    void        (*vec)(void);
#if DEVICE_SERIAL_ASYNCH
    void        (*vec_async)(void);
    uint8_t     pdma_perp_tx;
    uint8_t     pdma_perp_rx;
#endif
};

static void uart0_vec(void);
static void uart1_vec(void);
static void uart2_vec(void);
static void uart3_vec(void);
static void uart4_vec(void);
static void uart5_vec(void);
static void uart_irq(serial_t *obj);

#if DEVICE_SERIAL_ASYNCH
static void uart0_vec_async(void);
static void uart1_vec_async(void);
static void uart2_vec_async(void);
static void uart3_vec_async(void);
static void uart4_vec_async(void);
static void uart5_vec_async(void);
static void uart_irq_async(serial_t *obj);

static void uart_dma_handler_tx(uint32_t id, uint32_t event);
static void uart_dma_handler_rx(uint32_t id, uint32_t event);

static void serial_tx_enable_interrupt(serial_t *obj, uint32_t address, uint8_t enable);
static void serial_rx_enable_interrupt(serial_t *obj, uint32_t address, uint8_t enable);
static void serial_enable_interrupt(serial_t *obj, SerialIrq irq, uint32_t enable);
static void serial_rollback_interrupt(serial_t *obj, SerialIrq irq);
static int serial_write_async(serial_t *obj);
static int serial_read_async(serial_t *obj);

static uint32_t serial_rx_event_check(serial_t *obj);
static uint32_t serial_tx_event_check(serial_t *obj);

static int serial_is_tx_complete(serial_t *obj);
static void serial_tx_enable_event(serial_t *obj, int event, uint8_t enable);

static void serial_tx_buffer_set(serial_t *obj, const void *tx, size_t length, uint8_t width);
static void serial_rx_buffer_set(serial_t *obj, void *rx, size_t length, uint8_t width);
static void serial_rx_set_char_match(serial_t *obj, uint8_t char_match);
static void serial_rx_enable_event(serial_t *obj, int event, uint8_t enable);
static int serial_is_rx_complete(serial_t *obj);

static void serial_check_dma_usage(DMAUsage *dma_usage, int *dma_ch);
static int serial_is_irq_en(serial_t *obj, SerialIrq irq);
#endif

static struct nu_uart_var uart0_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart0_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart0_vec_async,
    .pdma_perp_tx       =   PDMA_UART0_TX,
    .pdma_perp_rx       =   PDMA_UART0_RX
#endif
};
static struct nu_uart_var uart1_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart1_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart1_vec_async,
    .pdma_perp_tx       =   PDMA_UART1_TX,
    .pdma_perp_rx       =   PDMA_UART1_RX
#endif
};
static struct nu_uart_var uart2_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart2_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart2_vec_async,
    .pdma_perp_tx       =   PDMA_UART2_TX,
    .pdma_perp_rx       =   PDMA_UART2_RX
#endif
};
static struct nu_uart_var uart3_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart3_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart3_vec_async,
    .pdma_perp_tx       =   PDMA_UART3_TX,
    .pdma_perp_rx       =   PDMA_UART3_RX
#endif
};
static struct nu_uart_var uart4_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart4_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart4_vec_async,
    .pdma_perp_tx       =   PDMA_UART4_TX,
    .pdma_perp_rx       =   PDMA_UART4_RX
#endif
};
static struct nu_uart_var uart5_var = {
    .ref_cnt            =   0,
    .obj                =   NULL,
    .fifo_size_tx       =   16,
    .fifo_size_rx       =   16,
    .vec                =   uart5_vec,
#if DEVICE_SERIAL_ASYNCH
    .vec_async          =   uart5_vec_async,
    .pdma_perp_tx       =   PDMA_UART5_TX,
    .pdma_perp_rx       =   PDMA_UART5_RX
#endif
};


int stdio_uart_inited = 0;
serial_t stdio_uart;
static uint32_t uart_modinit_mask = 0;

static const struct nu_modinit_s uart_modinit_tab[] = {
    {UART_0, UART0_MODULE, CLK_CLKSEL1_UART0SEL_HIRC, CLK_CLKDIV0_UART0(1), UART0_RST, UART0_IRQn, &uart0_var},
    {UART_1, UART1_MODULE, CLK_CLKSEL1_UART1SEL_HIRC, CLK_CLKDIV0_UART1(1), UART1_RST, UART1_IRQn, &uart1_var},
    {UART_2, UART2_MODULE, CLK_CLKSEL3_UART2SEL_HIRC, CLK_CLKDIV4_UART2(1), UART2_RST, UART2_IRQn, &uart2_var},
    {UART_3, UART3_MODULE, CLK_CLKSEL3_UART3SEL_HIRC, CLK_CLKDIV4_UART3(1), UART3_RST, UART3_IRQn, &uart3_var},
    {UART_4, UART4_MODULE, CLK_CLKSEL3_UART4SEL_HIRC, CLK_CLKDIV4_UART4(1), UART4_RST, UART4_IRQn, &uart4_var},
    {UART_5, UART5_MODULE, CLK_CLKSEL3_UART5SEL_HIRC, CLK_CLKDIV4_UART5(1), UART5_RST, UART5_IRQn, &uart5_var},

    {NC, 0, 0, 0, 0, (IRQn_Type) 0, NULL}
};

extern void mbed_sdk_init(void);

void serial_init(serial_t *obj, PinName tx, PinName rx)
{
    // NOTE: With armcc, serial_init() gets called from _sys_open() timing of which is before main()/mbed_sdk_init().
    mbed_sdk_init();

    // Determine which UART_x the pins are used for
    uint32_t uart_tx = pinmap_peripheral(tx, PinMap_UART_TX);
    uint32_t uart_rx = pinmap_peripheral(rx, PinMap_UART_RX);
    // Get the peripheral name (UART_x) from the pins and assign it to the object
    obj->serial.uart = (UARTName) pinmap_merge(uart_tx, uart_rx);
    MBED_ASSERT((int)obj->serial.uart != NC);

    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;

    if (! var->ref_cnt) {
        do {
            // Reset this module
            SYS_ResetModule(modinit->rsetidx);

            // Select IP clock source
            CLK_SetModuleClock(modinit->clkidx, modinit->clksrc, modinit->clkdiv);
            // Enable IP clock
            CLK_EnableModuleClock(modinit->clkidx);

            pinmap_pinout(tx, PinMap_UART_TX);
            pinmap_pinout(rx, PinMap_UART_RX);
        } while (0);

        obj->serial.pin_tx = tx;
        obj->serial.pin_rx = rx;
    }
    var->ref_cnt ++;

    // Configure the UART module and set its baudrate
    serial_baud(obj, 9600);
    // Configure data bits, parity, and stop bits
    serial_format(obj, 8, ParityNone, 1);

    obj->serial.vec = var->vec;
    obj->serial.irq_en = 0;

#if DEVICE_SERIAL_ASYNCH
    obj->serial.dma_usage_tx = DMA_USAGE_NEVER;
    obj->serial.dma_usage_rx = DMA_USAGE_NEVER;
    obj->serial.event = 0;
    obj->serial.dma_chn_id_tx = DMA_ERROR_OUT_OF_CHANNELS;
    obj->serial.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
#endif

    // For stdio management
    if (obj->serial.uart == STDIO_UART) {
        stdio_uart_inited = 1;
        memcpy(&stdio_uart, obj, sizeof(serial_t));
    }

    if (var->ref_cnt) {
        // Mark this module to be inited.
        int i = modinit - uart_modinit_tab;
        uart_modinit_mask |= 1 << i;
    }
}

void serial_free(serial_t *obj)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;

    var->ref_cnt --;
    if (! var->ref_cnt) {
#if DEVICE_SERIAL_ASYNCH
        if (obj->serial.dma_chn_id_tx != DMA_ERROR_OUT_OF_CHANNELS) {
            dma_channel_free(obj->serial.dma_chn_id_tx);
            obj->serial.dma_chn_id_tx = DMA_ERROR_OUT_OF_CHANNELS;
        }
        if (obj->serial.dma_chn_id_rx != DMA_ERROR_OUT_OF_CHANNELS) {
            dma_channel_free(obj->serial.dma_chn_id_rx);
            obj->serial.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
        }
#endif

        do {
            UART_Close((UART_T *) NU_MODBASE(obj->serial.uart));

            UART_DISABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), (UART_INTEN_RDAIEN_Msk | UART_INTEN_THREIEN_Msk | UART_INTEN_RXTOIEN_Msk));
            NVIC_DisableIRQ(modinit->irq_n);

            // Disable IP clock
            CLK_DisableModuleClock(modinit->clkidx);
        } while (0);
    }

    if (var->obj == obj) {
        var->obj = NULL;
    }

    if (obj->serial.uart == STDIO_UART) {
        stdio_uart_inited = 0;
    }

    if (! var->ref_cnt) {
        // Mark this module to be deinited.
        int i = modinit - uart_modinit_tab;
        uart_modinit_mask &= ~(1 << i);
    }
}

void serial_baud(serial_t *obj, int baudrate)
{
    // Flush Tx FIFO. Otherwise, output data may get lost on this change.
    while (! UART_IS_TX_EMPTY((UART_T *) NU_MODBASE(obj->serial.uart)));

    obj->serial.baudrate = baudrate;
    UART_Open((UART_T *) NU_MODBASE(obj->serial.uart), baudrate);
}

void serial_format(serial_t *obj, int data_bits, SerialParity parity, int stop_bits)
{
    // Flush Tx FIFO. Otherwise, output data may get lost on this change.
    while (! UART_IS_TX_EMPTY((UART_T *) NU_MODBASE(obj->serial.uart)));

    // Sanity check arguments
    MBED_ASSERT((data_bits == 5) || (data_bits == 6) || (data_bits == 7) || (data_bits == 8));
    MBED_ASSERT((parity == ParityNone) || (parity == ParityOdd) || (parity == ParityEven) || (parity == ParityForced1) || (parity == ParityForced0));
    MBED_ASSERT((stop_bits == 1) || (stop_bits == 2));

    obj->serial.databits = data_bits;
    obj->serial.parity = parity;
    obj->serial.stopbits = stop_bits;

    uint32_t databits_intern = (data_bits == 5) ? UART_WORD_LEN_5 :
                               (data_bits == 6) ? UART_WORD_LEN_6 :
                               (data_bits == 7) ? UART_WORD_LEN_7 :
                               UART_WORD_LEN_8;
    uint32_t parity_intern = (parity == ParityOdd || parity == ParityForced1) ? UART_PARITY_ODD :
                             (parity == ParityEven || parity == ParityForced0) ? UART_PARITY_EVEN :
                             UART_PARITY_NONE;
    uint32_t stopbits_intern = (stop_bits == 2) ? UART_STOP_BIT_2 : UART_STOP_BIT_1;
    UART_SetLine_Config((UART_T *) NU_MODBASE(obj->serial.uart),
                        0,  // Don't change baudrate
                        databits_intern,
                        parity_intern,
                        stopbits_intern);
}

#if DEVICE_SERIAL_FC

void serial_set_flow_control(serial_t *obj, FlowControl type, PinName rxflow, PinName txflow)
{
    UART_T *uart_base = (UART_T *) NU_MODBASE(obj->serial.uart);

    // First, disable flow control completely.
    uart_base->INTEN &= ~(UART_INTEN_ATORTSEN_Msk | UART_INTEN_ATOCTSEN_Msk);

    if ((type == FlowControlRTS || type == FlowControlRTSCTS) && rxflow != NC) {
        // Check if RTS pin matches.
        uint32_t uart_rts = pinmap_peripheral(rxflow, PinMap_UART_RTS);
        MBED_ASSERT(uart_rts == obj->serial.uart);
        // Enable the pin for RTS function
        pinmap_pinout(rxflow, PinMap_UART_RTS);

        // NOTE: Added in M480. Before configuring RTSACTLV, disable TX/RX.
        uart_base->FUNCSEL |= UART_FUNCSEL_TXRXDIS_Msk;
        while (uart_base->FIFOSTS & UART_FIFOSTS_TXRXACT_Msk);
        // nRTS pin output is low level active
        uart_base->MODEM |= UART_MODEM_RTSACTLV_Msk;
        // NOTE: Added in M480. After configuring RTSACTLV, re-enable TX/RX.
        uart_base->FUNCSEL &= ~UART_FUNCSEL_TXRXDIS_Msk;

        uart_base->FIFO = (uart_base->FIFO & ~UART_FIFO_RTSTRGLV_Msk) | UART_FIFO_RTSTRGLV_8BYTES;

        // Enable RTS
        uart_base->INTEN |= UART_INTEN_ATORTSEN_Msk;
    }

    if ((type == FlowControlCTS || type == FlowControlRTSCTS) && txflow != NC)  {
        // Check if CTS pin matches.
        uint32_t uart_cts = pinmap_peripheral(txflow, PinMap_UART_CTS);
        MBED_ASSERT(uart_cts == obj->serial.uart);
        // Enable the pin for CTS function
        pinmap_pinout(txflow, PinMap_UART_CTS);

        // NOTE: Added in M480. Before configuring CTSACTLV, disable TX/RX.
        uart_base->FUNCSEL |= UART_FUNCSEL_TXRXDIS_Msk;
        while (uart_base->FIFOSTS & UART_FIFOSTS_TXRXACT_Msk);
        // nCTS pin input is low level active
        uart_base->MODEMSTS |= UART_MODEMSTS_CTSACTLV_Msk;
        // NOTE: Added in M480. After configuring CTSACTLV, re-enable TX/RX.
        uart_base->FUNCSEL &= ~UART_FUNCSEL_TXRXDIS_Msk;

        // Enable CTS
        uart_base->INTEN |= UART_INTEN_ATOCTSEN_Msk;
    }
}

#endif  //DEVICE_SERIAL_FC

void serial_irq_handler(serial_t *obj, uart_irq_handler handler, uint32_t id)
{
    // Flush Tx FIFO. Otherwise, output data may get lost on this change.
    while (! UART_IS_TX_EMPTY((UART_T *) NU_MODBASE(obj->serial.uart)));

    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    obj->serial.irq_handler = (uint32_t) handler;
    obj->serial.irq_id = id;

    // Restore sync-mode vector
    obj->serial.vec = ((struct nu_uart_var *) modinit->var)->vec;
}

void serial_irq_set(serial_t *obj, SerialIrq irq, uint32_t enable)
{
    obj->serial.irq_en = enable;
    serial_enable_interrupt(obj, irq, enable);
}

int serial_getc(serial_t *obj)
{
    // NOTE: Every byte access requires accompaniment of one interrupt. This has side effect of performance degradation.
    while (! serial_readable(obj));
    int c = UART_READ(((UART_T *) NU_MODBASE(obj->serial.uart)));

    // NOTE: On Nuvoton targets, no H/W IRQ to match TxIrq/RxIrq.
    //       Simulation of TxIrq/RxIrq requires the call to Serial::putc()/Serial::getc() respectively.
    if (obj->serial.inten_msk & (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk)) {
        UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
    }

    return c;
}

void serial_putc(serial_t *obj, int c)
{
    // NOTE: Every byte access requires accompaniment of one interrupt. This has side effect of performance degradation.
    while (! serial_writable(obj));
    UART_WRITE(((UART_T *) NU_MODBASE(obj->serial.uart)), c);

    // NOTE: On Nuvoton targets, no H/W IRQ to match TxIrq/RxIrq.
    //       Simulation of TxIrq/RxIrq requires the call to Serial::putc()/Serial::getc() respectively.
    if (obj->serial.inten_msk & UART_INTEN_THREIEN_Msk) {
        UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_THREIEN_Msk);
    }
}

int serial_readable(serial_t *obj)
{
    return ! UART_GET_RX_EMPTY(((UART_T *) NU_MODBASE(obj->serial.uart)));
}

int serial_writable(serial_t *obj)
{
    return ! UART_IS_TX_FULL(((UART_T *) NU_MODBASE(obj->serial.uart)));
}

void serial_pinout_tx(PinName tx)
{
    pinmap_pinout(tx, PinMap_UART_TX);
}

void serial_break_set(serial_t *obj)
{
    ((UART_T *) NU_MODBASE(obj->serial.uart))->LINE |= UART_LINE_BCB_Msk;
}

void serial_break_clear(serial_t *obj)
{
    ((UART_T *) NU_MODBASE(obj->serial.uart))->LINE &= ~UART_LINE_BCB_Msk;
}

static void uart0_vec(void)
{
    uart_irq(uart0_var.obj);
}

static void uart1_vec(void)
{
    uart_irq(uart1_var.obj);
}

static void uart2_vec(void)
{
    uart_irq(uart2_var.obj);
}

static void uart3_vec(void)
{
    uart_irq(uart3_var.obj);
}

static void uart4_vec(void)
{
    uart_irq(uart4_var.obj);
}

static void uart5_vec(void)
{
    uart_irq(uart5_var.obj);
}

static void uart_irq(serial_t *obj)
{
    UART_T *uart_base = (UART_T *) NU_MODBASE(obj->serial.uart);

    if (uart_base->INTSTS & (UART_INTSTS_RDAINT_Msk | UART_INTSTS_RXTOINT_Msk)) {
        // Simulate clear of the interrupt flag. Temporarily disable the interrupt here and to be recovered on next read.
        UART_DISABLE_INT(uart_base, (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
        if (obj->serial.irq_handler) {
            ((uart_irq_handler) obj->serial.irq_handler)(obj->serial.irq_id, RxIrq);
        }
    }

    if (uart_base->INTSTS & UART_INTSTS_THREINT_Msk) {
        // Simulate clear of the interrupt flag. Temporarily disable the interrupt here and to be recovered on next write.
        UART_DISABLE_INT(uart_base, UART_INTEN_THREIEN_Msk);
        if (obj->serial.irq_handler) {
            ((uart_irq_handler) obj->serial.irq_handler)(obj->serial.irq_id, TxIrq);
        }
    }

    // FIXME: Ignore all other interrupt flags. Clear them. Otherwise, program will get stuck in interrupt.
    uart_base->INTSTS = uart_base->INTSTS;
    uart_base->FIFOSTS = uart_base->FIFOSTS;
}


#if DEVICE_SERIAL_ASYNCH
int serial_tx_asynch(serial_t *obj, const void *tx, size_t tx_length, uint8_t tx_width, uint32_t handler, uint32_t event, DMAUsage hint)
{
    MBED_ASSERT(tx_width == 8 || tx_width == 16 || tx_width == 32);

    obj->serial.dma_usage_tx = hint;
    serial_check_dma_usage(&obj->serial.dma_usage_tx, &obj->serial.dma_chn_id_tx);

    // UART IRQ is necessary for both interrupt way and DMA way
    serial_tx_enable_event(obj, event, 1);
    serial_tx_buffer_set(obj, tx, tx_length, tx_width);

    int n_word = 0;
    if (obj->serial.dma_usage_tx == DMA_USAGE_NEVER) {
        // Interrupt way
        n_word = serial_write_async(obj);
        serial_tx_enable_interrupt(obj, handler, 1);
    } else {
        // DMA way
        const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
        MBED_ASSERT(modinit != NULL);
        MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

        PDMA_T *pdma_base = dma_modbase();

        pdma_base->CHCTL |= 1 << obj->serial.dma_chn_id_tx;  // Enable this DMA channel
        PDMA_SetTransferMode(obj->serial.dma_chn_id_tx,
                             ((struct nu_uart_var *) modinit->var)->pdma_perp_tx,    // Peripheral connected to this PDMA
                             0,  // Scatter-gather disabled
                             0); // Scatter-gather descriptor address
        PDMA_SetTransferCnt(obj->serial.dma_chn_id_tx,
                            (tx_width == 8) ? PDMA_WIDTH_8 : (tx_width == 16) ? PDMA_WIDTH_16 : PDMA_WIDTH_32,
                            tx_length);
        PDMA_SetTransferAddr(obj->serial.dma_chn_id_tx,
                             (uint32_t) tx,  // NOTE:
                             // NUC472: End of source address
                             // M451: Start of source address
                             // M480: Start of source address
                             PDMA_SAR_INC,   // Source address incremental
                             (uint32_t) NU_MODBASE(obj->serial.uart),   // Destination address
                             PDMA_DAR_FIX);  // Destination address fixed
        PDMA_SetBurstType(obj->serial.dma_chn_id_tx,
                          PDMA_REQ_SINGLE,    // Single mode
                          0); // Burst size
        PDMA_EnableInt(obj->serial.dma_chn_id_tx,
                       PDMA_INT_TRANS_DONE); // Interrupt type
        // Register DMA event handler
        dma_set_handler(obj->serial.dma_chn_id_tx, (uint32_t) uart_dma_handler_tx, (uint32_t) obj, DMA_EVENT_ALL);
        serial_tx_enable_interrupt(obj, handler, 1);
        ((UART_T *) NU_MODBASE(obj->serial.uart))->INTEN |= UART_INTEN_TXPDMAEN_Msk;  // Start DMA transfer
    }

    return n_word;
}

void serial_rx_asynch(serial_t *obj, void *rx, size_t rx_length, uint8_t rx_width, uint32_t handler, uint32_t event, uint8_t char_match, DMAUsage hint)
{
    MBED_ASSERT(rx_width == 8 || rx_width == 16 || rx_width == 32);

    obj->serial.dma_usage_rx = hint;
    serial_check_dma_usage(&obj->serial.dma_usage_rx, &obj->serial.dma_chn_id_rx);
    // DMA doesn't support char match, so fall back to IRQ if it is requested.
    if (obj->serial.dma_usage_rx != DMA_USAGE_NEVER &&
            (event & SERIAL_EVENT_RX_CHARACTER_MATCH) &&
            char_match != SERIAL_RESERVED_CHAR_MATCH) {
        obj->serial.dma_usage_rx = DMA_USAGE_NEVER;
        dma_channel_free(obj->serial.dma_chn_id_rx);
        obj->serial.dma_chn_id_rx = DMA_ERROR_OUT_OF_CHANNELS;
    }

    // UART IRQ is necessary for both interrupt way and DMA way
    serial_rx_enable_event(obj, event, 1);
    serial_rx_buffer_set(obj, rx, rx_length, rx_width);
    serial_rx_set_char_match(obj, char_match);

    if (obj->serial.dma_usage_rx == DMA_USAGE_NEVER) {
        // Interrupt way
        serial_rx_enable_interrupt(obj, handler, 1);
    } else {
        // DMA way
        const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
        MBED_ASSERT(modinit != NULL);
        MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

        PDMA_T *pdma_base = dma_modbase();

        pdma_base->CHCTL |= 1 << obj->serial.dma_chn_id_rx;  // Enable this DMA channel
        PDMA_SetTransferMode(obj->serial.dma_chn_id_rx,
                             ((struct nu_uart_var *) modinit->var)->pdma_perp_rx,    // Peripheral connected to this PDMA
                             0,  // Scatter-gather disabled
                             0); // Scatter-gather descriptor address
        PDMA_SetTransferCnt(obj->serial.dma_chn_id_rx,
                            (rx_width == 8) ? PDMA_WIDTH_8 : (rx_width == 16) ? PDMA_WIDTH_16 : PDMA_WIDTH_32,
                            rx_length);
        PDMA_SetTransferAddr(obj->serial.dma_chn_id_rx,
                             (uint32_t) NU_MODBASE(obj->serial.uart),    // Source address
                             PDMA_SAR_FIX,   // Source address fixed
                             (uint32_t) rx,  // NOTE:
                             // NUC472: End of destination address
                             // M451: Start of destination address
                             // M480: Start of destination address
                             PDMA_DAR_INC);  // Destination address incremental
        PDMA_SetBurstType(obj->serial.dma_chn_id_rx,
                          PDMA_REQ_SINGLE,    // Single mode
                          0); // Burst size
        PDMA_EnableInt(obj->serial.dma_chn_id_rx,
                       PDMA_INT_TRANS_DONE); // Interrupt type
        // Register DMA event handler
        dma_set_handler(obj->serial.dma_chn_id_rx, (uint32_t) uart_dma_handler_rx, (uint32_t) obj, DMA_EVENT_ALL);
        serial_rx_enable_interrupt(obj, handler, 1);
        ((UART_T *) NU_MODBASE(obj->serial.uart))->INTEN |= UART_INTEN_RXPDMAEN_Msk;  // Start DMA transfer
    }
}

void serial_tx_abort_asynch(serial_t *obj)
{
    // Flush Tx FIFO. Otherwise, output data may get lost on this change.
    while (! UART_IS_TX_EMPTY((UART_T *) NU_MODBASE(obj->serial.uart)));

    if (obj->serial.dma_usage_tx != DMA_USAGE_NEVER) {
        PDMA_T *pdma_base = dma_modbase();

        if (obj->serial.dma_chn_id_tx != DMA_ERROR_OUT_OF_CHANNELS) {
            PDMA_DisableInt(obj->serial.dma_chn_id_tx, PDMA_INT_TRANS_DONE);
            // NOTE: On NUC472, next PDMA transfer will fail with PDMA_STOP() called. Cause is unknown.
            pdma_base->CHCTL &= ~(1 << obj->serial.dma_chn_id_tx);
        }
        UART_DISABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_TXPDMAEN_Msk);
    }

    // Necessary for both interrupt way and DMA way
    serial_enable_interrupt(obj, TxIrq, 0);
    serial_rollback_interrupt(obj, TxIrq);
}

void serial_rx_abort_asynch(serial_t *obj)
{
    if (obj->serial.dma_usage_rx != DMA_USAGE_NEVER) {
        PDMA_T *pdma_base = dma_modbase();

        if (obj->serial.dma_chn_id_rx != DMA_ERROR_OUT_OF_CHANNELS) {
            PDMA_DisableInt(obj->serial.dma_chn_id_rx, PDMA_INT_TRANS_DONE);
            // NOTE: On NUC472, next PDMA transfer will fail with PDMA_STOP() called. Cause is unknown.
            pdma_base->CHCTL &= ~(1 << obj->serial.dma_chn_id_rx);
        }
        UART_DISABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_RXPDMAEN_Msk);
    }

    // Necessary for both interrupt way and DMA way
    serial_enable_interrupt(obj, RxIrq, 0);
    serial_rollback_interrupt(obj, RxIrq);
}

uint8_t serial_tx_active(serial_t *obj)
{
    // NOTE: Judge by serial_is_irq_en(obj, TxIrq) doesn't work with sync/async modes interleaved. Change with TX FIFO empty flag.
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;
    return (obj->serial.vec == var->vec_async);
}

uint8_t serial_rx_active(serial_t *obj)
{
    // NOTE: Judge by serial_is_irq_en(obj, RxIrq) doesn't work with sync/async modes interleaved. Change with RX FIFO empty flag.
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;
    return (obj->serial.vec == var->vec_async);
}

int serial_irq_handler_asynch(serial_t *obj)
{
    int event_rx = 0;
    int event_tx = 0;

    // Necessary for both interrupt way and DMA way
    if (serial_is_irq_en(obj, RxIrq)) {
        event_rx = serial_rx_event_check(obj);
        if (event_rx) {
            serial_rx_abort_asynch(obj);
        }
    }

    if (serial_is_irq_en(obj, TxIrq)) {
        event_tx = serial_tx_event_check(obj);
        if (event_tx) {
            serial_tx_abort_asynch(obj);
        }
    }

    return (obj->serial.event & (event_rx | event_tx));
}

static void uart0_vec_async(void)
{
    uart_irq_async(uart0_var.obj);
}

static void uart1_vec_async(void)
{
    uart_irq_async(uart1_var.obj);
}

static void uart2_vec_async(void)
{
    uart_irq_async(uart2_var.obj);
}

static void uart3_vec_async(void)
{
    uart_irq_async(uart3_var.obj);
}

static void uart4_vec_async(void)
{
    uart_irq_async(uart4_var.obj);
}

static void uart5_vec_async(void)
{
    uart_irq_async(uart5_var.obj);
}

static void uart_irq_async(serial_t *obj)
{
    if (serial_is_irq_en(obj, RxIrq)) {
        (*obj->serial.irq_handler_rx_async)();
    }
    if (serial_is_irq_en(obj, TxIrq)) {
        (*obj->serial.irq_handler_tx_async)();
    }
}

static void serial_rx_set_char_match(serial_t *obj, uint8_t char_match)
{
    obj->char_match = char_match;
    obj->char_found = 0;
}

static void serial_tx_enable_event(serial_t *obj, int event, uint8_t enable)
{
    obj->serial.event &= ~SERIAL_EVENT_TX_MASK;
    obj->serial.event |= (event & SERIAL_EVENT_TX_MASK);

    if (event & SERIAL_EVENT_TX_COMPLETE) {
        // N/A
    }
}

static void serial_rx_enable_event(serial_t *obj, int event, uint8_t enable)
{
    obj->serial.event &= ~SERIAL_EVENT_RX_MASK;
    obj->serial.event |= (event & SERIAL_EVENT_RX_MASK);

    if (event & SERIAL_EVENT_RX_COMPLETE) {
        // N/A
    }
    if (event & SERIAL_EVENT_RX_OVERRUN_ERROR) {
        // N/A
    }
    if (event & SERIAL_EVENT_RX_FRAMING_ERROR) {
        UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_RLSIEN_Msk);
    }
    if (event & SERIAL_EVENT_RX_PARITY_ERROR) {
        UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_RLSIEN_Msk);
    }
    if (event & SERIAL_EVENT_RX_OVERFLOW) {
        UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_BUFERRIEN_Msk);
    }
    if (event & SERIAL_EVENT_RX_CHARACTER_MATCH) {
        // N/A
    }
}

static int serial_is_tx_complete(serial_t *obj)
{
    // NOTE: Exclude tx fifo empty check due to no such interrupt on DMA way
    return (obj->tx_buff.pos == obj->tx_buff.length);
}

static int serial_is_rx_complete(serial_t *obj)
{
    return (obj->rx_buff.pos == obj->rx_buff.length);
}

static uint32_t serial_tx_event_check(serial_t *obj)
{
    UART_T *uart_base = (UART_T *) NU_MODBASE(obj->serial.uart);

    if (uart_base->INTSTS & UART_INTSTS_THREINT_Msk) {
        // Simulate clear of the interrupt flag. Temporarily disable the interrupt here and to be recovered on next write.
        UART_DISABLE_INT(uart_base, UART_INTEN_THREIEN_Msk);
    }

    uint32_t event = 0;

    if (obj->serial.dma_usage_tx == DMA_USAGE_NEVER) {
        serial_write_async(obj);
    }

    if (serial_is_tx_complete(obj)) {
        event |= SERIAL_EVENT_TX_COMPLETE;
    }

    return event;
}

static uint32_t serial_rx_event_check(serial_t *obj)
{
    UART_T *uart_base = (UART_T *) NU_MODBASE(obj->serial.uart);

    if (uart_base->INTSTS & (UART_INTSTS_RDAINT_Msk | UART_INTSTS_RXTOINT_Msk)) {
        // Simulate clear of the interrupt flag. Temporarily disable the interrupt here and to be recovered on next read.
        UART_DISABLE_INT(uart_base, (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
    }

    uint32_t event = 0;

    if (uart_base->FIFOSTS & UART_FIFOSTS_BIF_Msk) {
        uart_base->FIFOSTS = UART_FIFOSTS_BIF_Msk;
    }
    if (uart_base->FIFOSTS & UART_FIFOSTS_FEF_Msk) {
        uart_base->FIFOSTS = UART_FIFOSTS_FEF_Msk;
        event |= SERIAL_EVENT_RX_FRAMING_ERROR;
    }
    if (uart_base->FIFOSTS & UART_FIFOSTS_PEF_Msk) {
        uart_base->FIFOSTS = UART_FIFOSTS_PEF_Msk;
        event |= SERIAL_EVENT_RX_PARITY_ERROR;
    }

    if (uart_base->FIFOSTS & UART_FIFOSTS_RXOVIF_Msk) {
        uart_base->FIFOSTS = UART_FIFOSTS_RXOVIF_Msk;
        event |= SERIAL_EVENT_RX_OVERFLOW;
    }

    if (obj->serial.dma_usage_rx == DMA_USAGE_NEVER) {
        serial_read_async(obj);
    }

    if (serial_is_rx_complete(obj)) {
        event |= SERIAL_EVENT_RX_COMPLETE;
    }
    if ((obj->char_match != SERIAL_RESERVED_CHAR_MATCH) && obj->char_found) {
        event |= SERIAL_EVENT_RX_CHARACTER_MATCH;
    }

    return event;
}

static void uart_dma_handler_tx(uint32_t id, uint32_t event_dma)
{
    serial_t *obj = (serial_t *) id;

    // FIXME: Pass this error to caller
    if (event_dma & DMA_EVENT_ABORT) {
    }
    // Expect UART IRQ will catch this transfer done event
    if (event_dma & DMA_EVENT_TRANSFER_DONE) {
        obj->tx_buff.pos = obj->tx_buff.length;
    }
    // FIXME: Pass this error to caller
    if (event_dma & DMA_EVENT_TIMEOUT) {
    }

    uart_irq_async(obj);
}

static void uart_dma_handler_rx(uint32_t id, uint32_t event_dma)
{
    serial_t *obj = (serial_t *) id;

    // FIXME: Pass this error to caller
    if (event_dma & DMA_EVENT_ABORT) {
    }
    // Expect UART IRQ will catch this transfer done event
    if (event_dma & DMA_EVENT_TRANSFER_DONE) {
        obj->rx_buff.pos = obj->rx_buff.length;
    }
    // FIXME: Pass this error to caller
    if (event_dma & DMA_EVENT_TIMEOUT) {
    }

    uart_irq_async(obj);
}

static int serial_write_async(serial_t *obj)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    UART_T *uart_base = (UART_T *) NU_MODBASE(obj->serial.uart);

    uint32_t tx_fifo_max = ((struct nu_uart_var *) modinit->var)->fifo_size_tx;
    uint32_t tx_fifo_busy = (uart_base->FIFOSTS & UART_FIFOSTS_TXPTR_Msk) >> UART_FIFOSTS_TXPTR_Pos;
    if (uart_base->FIFOSTS & UART_FIFOSTS_TXFULL_Msk) {
        tx_fifo_busy = tx_fifo_max;
    }
    uint32_t tx_fifo_free = tx_fifo_max - tx_fifo_busy;
    if (tx_fifo_free == 0) {
        // Simulate clear of the interrupt flag
        if (obj->serial.inten_msk & UART_INTEN_THREIEN_Msk) {
            UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_THREIEN_Msk);
        }
        return 0;
    }

    uint32_t bytes_per_word = obj->tx_buff.width / 8;

    uint8_t *tx = (uint8_t *)(obj->tx_buff.buffer) + bytes_per_word * obj->tx_buff.pos;
    int n_words = 0;
    while (obj->tx_buff.pos < obj->tx_buff.length && tx_fifo_free >= bytes_per_word) {
        switch (bytes_per_word) {
        case 4:
            UART_WRITE(((UART_T *) NU_MODBASE(obj->serial.uart)), *tx ++);
            UART_WRITE(((UART_T *) NU_MODBASE(obj->serial.uart)), *tx ++);
        case 2:
            UART_WRITE(((UART_T *) NU_MODBASE(obj->serial.uart)), *tx ++);
        case 1:
            UART_WRITE(((UART_T *) NU_MODBASE(obj->serial.uart)), *tx ++);
        }

        n_words ++;
        tx_fifo_free -= bytes_per_word;
        obj->tx_buff.pos ++;
    }

    if (n_words) {
        // Simulate clear of the interrupt flag
        if (obj->serial.inten_msk & UART_INTEN_THREIEN_Msk) {
            UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_THREIEN_Msk);
        }
    }

    return n_words;
}

static int serial_read_async(serial_t *obj)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    uint32_t rx_fifo_busy = (((UART_T *) NU_MODBASE(obj->serial.uart))->FIFOSTS & UART_FIFOSTS_RXPTR_Msk) >> UART_FIFOSTS_RXPTR_Pos;

    uint32_t bytes_per_word = obj->rx_buff.width / 8;

    uint8_t *rx = (uint8_t *)(obj->rx_buff.buffer) + bytes_per_word * obj->rx_buff.pos;
    int n_words = 0;
    while (obj->rx_buff.pos < obj->rx_buff.length && rx_fifo_busy >= bytes_per_word) {
        switch (bytes_per_word) {
        case 4:
            *rx ++ = UART_READ(((UART_T *) NU_MODBASE(obj->serial.uart)));
            *rx ++ = UART_READ(((UART_T *) NU_MODBASE(obj->serial.uart)));
        case 2:
            *rx ++ = UART_READ(((UART_T *) NU_MODBASE(obj->serial.uart)));
        case 1:
            *rx ++ = UART_READ(((UART_T *) NU_MODBASE(obj->serial.uart)));
        }

        n_words ++;
        rx_fifo_busy -= bytes_per_word;
        obj->rx_buff.pos ++;

        if ((obj->serial.event & SERIAL_EVENT_RX_CHARACTER_MATCH) &&
                obj->char_match != SERIAL_RESERVED_CHAR_MATCH) {
            uint8_t *rx_cmp = rx;
            switch (bytes_per_word) {
            case 4:
                rx_cmp -= 2;
            case 2:
                rx_cmp --;
            case 1:
                rx_cmp --;
            }
            if (*rx_cmp == obj->char_match) {
                obj->char_found = 1;
                break;
            }
        }
    }

    if (n_words) {
        // Simulate clear of the interrupt flag
        if (obj->serial.inten_msk & (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk)) {
            UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
        }
    }

    return n_words;
}

static void serial_tx_buffer_set(serial_t *obj, const void *tx, size_t length, uint8_t width)
{
    obj->tx_buff.buffer = (void *) tx;
    obj->tx_buff.length = length;
    obj->tx_buff.pos = 0;
    obj->tx_buff.width = width;
}

static void serial_rx_buffer_set(serial_t *obj, void *rx, size_t length, uint8_t width)
{
    obj->rx_buff.buffer = rx;
    obj->rx_buff.length = length;
    obj->rx_buff.pos = 0;
    obj->rx_buff.width = width;
}

static void serial_tx_enable_interrupt(serial_t *obj, uint32_t handler, uint8_t enable)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    // Necessary for both interrupt way and DMA way
    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;
    // With our own async vector, tx/rx handlers can be different.
    obj->serial.vec = var->vec_async;
    obj->serial.irq_handler_tx_async = (void (*)(void)) handler;
    serial_enable_interrupt(obj, TxIrq, enable);
}

static void serial_rx_enable_interrupt(serial_t *obj, uint32_t handler, uint8_t enable)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    // Necessary for both interrupt way and DMA way
    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;
    // With our own async vector, tx/rx handlers can be different.
    obj->serial.vec = var->vec_async;
    obj->serial.irq_handler_rx_async = (void (*) (void)) handler;
    serial_enable_interrupt(obj, RxIrq, enable);
}

static void serial_enable_interrupt(serial_t *obj, SerialIrq irq, uint32_t enable)
{
    if (enable) {
        const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
        MBED_ASSERT(modinit != NULL);
        MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

        NVIC_SetVector(modinit->irq_n, (uint32_t) obj->serial.vec);
        NVIC_EnableIRQ(modinit->irq_n);

        struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;
        // Multiple serial S/W objects for single UART H/W module possibly.
        // Bind serial S/W object to UART H/W module as interrupt is enabled.
        var->obj = obj;

        switch (irq) {
        // NOTE: Setting inten_msk first to avoid race condition
        case RxIrq:
            obj->serial.inten_msk = obj->serial.inten_msk | (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk);
            UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
            break;
        case TxIrq:
            obj->serial.inten_msk = obj->serial.inten_msk | UART_INTEN_THREIEN_Msk;
            UART_ENABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_THREIEN_Msk);
            break;
        }
    } else { // disable
        switch (irq) {
        case RxIrq:
            UART_DISABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk));
            obj->serial.inten_msk = obj->serial.inten_msk & ~(UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk);
            break;
        case TxIrq:
            UART_DISABLE_INT(((UART_T *) NU_MODBASE(obj->serial.uart)), UART_INTEN_THREIEN_Msk);
            obj->serial.inten_msk = obj->serial.inten_msk & ~UART_INTEN_THREIEN_Msk;
            break;
        }
    }
}

static void serial_rollback_interrupt(serial_t *obj, SerialIrq irq)
{
    const struct nu_modinit_s *modinit = get_modinit(obj->serial.uart, uart_modinit_tab);
    MBED_ASSERT(modinit != NULL);
    MBED_ASSERT(modinit->modname == (int) obj->serial.uart);

    struct nu_uart_var *var = (struct nu_uart_var *) modinit->var;

    obj->serial.vec = var->vec;
    serial_enable_interrupt(obj, irq, obj->serial.irq_en);
}

static void serial_check_dma_usage(DMAUsage *dma_usage, int *dma_ch)
{
    if (*dma_usage != DMA_USAGE_NEVER) {
        if (*dma_ch == DMA_ERROR_OUT_OF_CHANNELS) {
            *dma_ch = dma_channel_allocate(DMA_CAP_NONE);
        }
        if (*dma_ch == DMA_ERROR_OUT_OF_CHANNELS) {
            *dma_usage = DMA_USAGE_NEVER;
        }
    } else {
        dma_channel_free(*dma_ch);
        *dma_ch = DMA_ERROR_OUT_OF_CHANNELS;
    }
}

static int serial_is_irq_en(serial_t *obj, SerialIrq irq)
{
    int inten_msk = 0;

    switch (irq) {
    case RxIrq:
        inten_msk = obj->serial.inten_msk & (UART_INTEN_RDAIEN_Msk | UART_INTEN_RXTOIEN_Msk);
        break;
    case TxIrq:
        inten_msk = obj->serial.inten_msk & UART_INTEN_THREIEN_Msk;
        break;
    }

    return !! inten_msk;
}

#endif  // #if DEVICE_SERIAL_ASYNCH
#endif  // #if DEVICE_SERIAL