/**************************************************************************** * arch/arm/src/efm32/efm32_leserial.c * * Copyright (C) 2024 Gregory Nutt. All rights reserved. * Author: Gregory Nutt * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "up_arch.h" #include "up_internal.h" #include "chip/efm32_leart.h" #include "efm32_config.h" #include "efm32_lowputc.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /* Some sanity checks *******************************************************/ /* Is there at least one UART enabled and configured as a RS-232 device? */ #ifndef HAVE_LEUART_DEVICE # warning "No LEUARTs enabled" #endif /* If we are not using the serial driver for the console, then we still must * provide some minimal implementation of up_putc. */ #ifdef USE_SERIALDRIVER /* Which LEUART with be ttyLE0/console and which ttyLE1? The console will always * be ttyLE0. If there is no console then will use the lowest numbered LEUART. */ /* First pick the console and ttys0. This could be either LEUART0-1 */ #if defined(CONFIG_LEUART0_SERIAL_CONSOLE) # define CONSOLE_DEV g_leuart0port /* LEUART0 is console */ # define TTYLE0_DEV g_leuart0port /* LEUART0 is ttyLE0 */ # define LEUART0_ASSIGNED 1 #elif defined(CONFIG_LEUART1_SERIAL_CONSOLE) # define CONSOLE_DEV g_leuart1port /* LEUART1 is console */ # define TTYLE0_DEV g_leuart1port /* LEUART1 is ttyLE0 */ # define LEUART1_ASSIGNED 1 #else # undef CONSOLE_DEV /* No console */ # if defined(CONFIG_EFM32_LEUART0) # define TTYLE0_DEV g_leuart0port /* LEUART0 is ttyLE0 */ # define LEUART0_ASSIGNED 1 # elif defined(CONFIG_EFM32_LEUART1) # define TTYLE0_DEV g_leuart1port /* LEUART1 is ttyLE0 */ # define LEUART1_ASSIGNED 1 # endif #endif /* Pick ttyLE1. This could be any of LEUART0-1, excluding the and the * LEUART already selected for ttyLE0 */ #if defined(CONFIG_EFM32_LEUART0) && !defined(LEUART0_ASSIGNED) # define TTYLE1_DEV g_leuart0port /* LEUART0 is ttyLE1 */ # define LEUART0_ASSIGNED 1 #elif defined(CONFIG_EFM32_LEUART1) && !defined(LEUART1_ASSIGNED) # define TTYLE1_DEV g_leuart1port /* LEUART1 is ttyLE1 */ # define LEUART1_ASSIGNED 1 #endif /* TX/RX interrupts */ #define EFM32_TXERR_INTS (LEUART_IEN_TXOF) #define EFM32_RXERR_INTS (LEUART_IEN_RXOF | LEUART_IEN_PERR | \ LEUART_IEN_FERR) #ifdef CONFIG_DEBUG # define EFM32_TX_INTS (LEUART_IEN_TXBL | EFM32_TXERR_INTS) # define EFM32_RX_INTS (LEUART_IEN_RXDATAV | EFM32_RXERR_INTS) #else # define EFM32_TX_INTS LEUART_IEN_TXBL # define EFM32_RX_INTS LEUART_IEN_RXDATAV #endif /**************************************************************************** * Private Types ****************************************************************************/ struct efm32_config_s { uintptr_t uartbase; /* Base address of UART registers */ xcpt_t handler; /* Interrupt handler */ uint32_t baud; /* Configured baud */ uint8_t irq; /* IRQ associated with this LEUART (for enable) */ uint8_t parity; /* 0=none, 1=odd, 2=even */ uint8_t bits; /* Number of bits (8 or 9) */ bool stop2; /* True: 2 stop bits */ }; struct efm32_leuart_s { const struct efm32_config_s *config; uint16_t ien; /* Interrupts enabled */ }; /**************************************************************************** * Private Function Prototypes ****************************************************************************/ static inline uint32_t efm32_serialin(struct efm32_leuart_s *priv, int offset); static inline void efm32_serialout(struct efm32_leuart_s *priv, int offset, uint32_t value); static inline void efm32_setuartint(struct efm32_leuart_s *priv); static void efm32_restoreuartint(struct efm32_leuart_s *priv, uint32_t ien); static void efm32_disableuartint(struct efm32_leuart_s *priv, uint32_t *ien); static int efm32_setup(struct uart_dev_s *dev); static void efm32_shutdown(struct uart_dev_s *dev); static int efm32_attach(struct uart_dev_s *dev); static void efm32_detach(struct uart_dev_s *dev); static int efm32_interrupt(struct uart_dev_s *dev); #if defined(CONFIG_EFM32_LEUART0) static int efm32_leuart0_interrupt(int irq, void *context); #endif #if defined(CONFIG_EFM32_LEUART1) static int efm32_leuart1_interrupt(int irq, void *context); #endif static int efm32_ioctl(struct file *filep, int cmd, unsigned long arg); static int efm32_receive(struct uart_dev_s *dev, uint32_t *status); static void efm32_rxint(struct uart_dev_s *dev, bool enable); static bool efm32_rxavailable(struct uart_dev_s *dev); static void efm32_send(struct uart_dev_s *dev, int ch); static void efm32_txint(struct uart_dev_s *dev, bool enable); static bool efm32_txready(struct uart_dev_s *dev); static bool efm32_txempty(struct uart_dev_s *dev); /**************************************************************************** * Private Variables ****************************************************************************/ static const struct uart_ops_s g_leuart_ops = { .setup = efm32_setup, .shutdown = efm32_shutdown, .attach = efm32_attach, .detach = efm32_detach, .ioctl = efm32_ioctl, .receive = efm32_receive, .rxint = efm32_rxint, .rxavailable = efm32_rxavailable, #ifdef CONFIG_SERIAL_IFLOWCONTROL .rxflowcontrol = NULL, #endif .send = efm32_send, .txint = efm32_txint, .txready = efm32_txready, .txempty = efm32_txempty, }; /* I/O buffers */ #ifdef CONFIG_EFM32_LEUART0 static char g_leuart0rxbuffer[CONFIG_LEUART0_RXBUFSIZE]; static char g_leuart0txbuffer[CONFIG_LEUART0_TXBUFSIZE]; #endif #ifdef CONFIG_EFM32_LEUART1 static char g_leuart1rxbuffer[CONFIG_LEUART1_RXBUFSIZE]; static char g_leuart1txbuffer[CONFIG_LEUART1_TXBUFSIZE]; #endif /* This describes the state of the EFM32 LEUART0 port. */ #ifdef CONFIG_EFM32_LEUART0 static const struct efm32_leuart_s g_leuart0config = { .uartbase = EFM32_LEUART0_BASE, .handler = efm32_leuart0_interrupt, .baud = CONFIG_LEUART0_BAUD, .irq = EFM32_IRQ_LEUART0, .parity = CONFIG_LEUART0_PARITY, .bits = CONFIG_LEUART0_BITS, .stop2 = CONFIG_LEUART0_2STOP, }; static struct efm32_leuart_s g_leuart0priv = { .config = &g_leuart0config, }; static struct uart_dev_s g_leuart0port = { .recv = { .size = CONFIG_LEUART0_RXBUFSIZE, .buffer = g_leuart0rxbuffer, }, .xmit = { .size = CONFIG_LEUART0_TXBUFSIZE, .buffer = g_leuart0txbuffer, }, .ops = &g_leuart_ops, .priv = &g_leuart0priv, }; #endif /* This describes the state of the EFM32 LEUART1 port. */ #ifdef CONFIG_EFM32_LEUART1 static struct efm32_config_s g_leuart1config = { .uartbase = EFM32_LEUART1_BASE, .handler = efm32_leuart1_interrupt, .baud = CONFIG_LEUART1_BAUD, .irq = EFM32_IRQ_LEUART1, .parity = CONFIG_LEUART1_PARITY, .bits = CONFIG_LEUART1_BITS, .stop2 = CONFIG_LEUART1_2STOP, }; static struct efm32_leuart_s g_leuart1priv = { .config = &g_leuart1config, }; static struct uart_dev_s g_leuart1port = { .recv = { .size = CONFIG_LEUART1_RXBUFSIZE, .buffer = g_leuart1rxbuffer, }, .xmit = { .size = CONFIG_LEUART1_TXBUFSIZE, .buffer = g_leuart1txbuffer, }, .ops = &g_leuart_ops, .priv = &g_leuart1priv, }; #endif /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: efm32_serialin ****************************************************************************/ static inline uint32_t efm32_serialin(struct efm32_leuart_s *priv, int offset) { return getreg32(priv->config->uartbase + offset); } /**************************************************************************** * Name: efm32_serialout ****************************************************************************/ static inline void efm32_serialout(struct efm32_leuart_s *priv, int offset, uint32_t value) { putreg32(value, priv->config->uartbase + offset); } /**************************************************************************** * Name: efm32_setuartint ****************************************************************************/ static inline void efm32_setuartint(struct efm32_leuart_s *priv) { efm32_serialout(priv, EFM32_LEUART_IEN_OFFSET, priv->ien); } /**************************************************************************** * Name: efm32_restoreuartint ****************************************************************************/ static void efm32_restoreuartint(struct efm32_leuart_s *priv, uint32_t ien) { irqstate_t flags; /* Re-enable/re-disable interrupts corresponding to the state of bits in ien */ flags = irqsave(); priv->ien = ien; efm32_setuartint(priv); irqrestore(flags); } /**************************************************************************** * Name: efm32_disableuartint ****************************************************************************/ static void efm32_disableuartint(struct efm32_leuart_s *priv, uint32_t *ien) { irqstate_t flags; flags = irqsave(); if (ien) { *ien = priv->ien; } efm32_restoreuartint(priv, 0); irqrestore(flags); } /**************************************************************************** * Name: efm32_setup * * Description: * Configure the UART baud, bits, parity, etc. This method is called the * first time that the serial port is opened. * ****************************************************************************/ static int efm32_setup(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; uint32_t regval; #ifndef CONFIG_SUPPRESS_LEUART_CONFIG const struct efm32_config_s *config = priv->config; /* Configure the UART as an RS-232 UART */ efm32_leuartconfigure(config->uartbase, config->baud, config->parity, config->bits, config->stop2); #endif /* Make sure that all interrupts are disabled */ efm32_restoreuartint(priv, 0); return OK; } /**************************************************************************** * Name: efm32_shutdown * * Description: * Disable the UART. This method is called when the serial * port is closed * ****************************************************************************/ static void efm32_shutdown(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; /* Disable interrupts */ efm32_restoreuartint(priv, 0); /* Reset the LEUART/UART by disabling it and restoring all of the registers * to the initial, reset value. Only the ROUTE data set by efm32_lowsetup * is preserved. */ efm32_leuart_reset(priv->config->uartbase); } /**************************************************************************** * Name: efm32_attach * * Description: * Configure the UART to operation in interrupt driven mode. This method is * called when the serial port is opened. Normally, this is just after the * the setup() method is called, however, the serial console may operate in * a non-interrupt driven mode during the boot phase. * * RX and TX interrupts are not enabled when by the attach method (unless the * hardware supports multiple levels of interrupt enabling). The RX and TX * interrupts are not enabled until the txint() and rxint() methods are called. * ****************************************************************************/ static int efm32_attach(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; const struct efm32_config_s *config = priv->config; int ret; /* Attach and enable the IRQ(s). The interrupts are (probably) still * disabled in the C2 register. */ ret = irq_attach(config->irq, config->handler); if (ret >= 0) { up_enable_irq(config->irq); } return ret; } /**************************************************************************** * Name: efm32_detach * * Description: * Detach UART interrupts. This method is called when the serial port is * closed normally just before the shutdown method is called. The exception * is the serial console which is never shutdown. * ****************************************************************************/ static void efm32_detach(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; const struct efm32_config_s *config = priv->config; /* Disable interrupts */ efm32_restoreuartint(priv, 0); up_disable_irq(config->irq); /* Detach from the interrupt(s) */ irq_detach(config->irq); } /**************************************************************************** * Name: efm32_interrupt * * Description: * This is the common UART RX interrupt handler. * ****************************************************************************/ static int efm32_interrupt(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; uint32_t intflags; DEBUGASSERT(priv); /* Read the interrupt flags register */ intflags = efm32_serialin(priv, EFM32_LEUART_IF_OFFSET); /* Clear pending interrupts by writing to the interrupt flag clear * register. */ efm32_serialout(priv, EFM32_LEUART_IFC_OFFSET, intflags); /* Check if the receive data is available is full (RXDATAV). */ if ((intflags & LEUART_IEN_RXDATAV) != 0) { /* Process incoming bytes */ uart_recvchars(dev); } /* Check if the transmit data buffer became empty */ if ((intflags & LEUART_IEN_TXBL) != 0) { /* Process outgoing bytes */ uart_xmitchars(dev); } #ifdef CONFIG_DEBUG /* Check for receive errors */ if ((intflags & EFM32_RXERR_INTS) != 0) { /* RXOF - RX Overflow Interrupt Enable * RXUF - RX Underflow Interrupt Enable * TXUF - TX Underflow Interrupt Enable * PERR - Parity Error Interrupt Enable * FERR - Framing Error Interrupt Enable */ lldbg("RX ERROR: %08x\n", intflags); } /* Check for transmit errors */ if ((intflags & EFM32_TXERR_INTS) != 0) { /* TXOF - TX Overflow Interrupt Enable */ lldbg("RX ERROR: %08x\n", intflags); } #endif return OK; } #if defined(CONFIG_EFM32_LEUART0) static int efm32_leuart0_interrupt(int irq, void *context) { return efm32_interrupt(&g_leuart0port); } #endif #if defined(CONFIG_EFM32_LEUART1) static int efm32_leuart1_interrupt(int irq, void *context) { return efm32_interrupt(&g_leuart1port); } #endif /**************************************************************************** * Name: efm32_ioctl * * Description: * All ioctl calls will be routed through this method * ****************************************************************************/ static int efm32_ioctl(struct file *filep, int cmd, unsigned long arg) { #if 0 /* Reserved for future growth */ struct inode *inode; struct uart_dev_s *dev; struct efm32_leuart_s *priv; int ret = OK; DEBUGASSERT(filep, filep->f_inode); inode = filep->f_inode; dev = inode->i_private; DEBUGASSERT(dev, dev->priv) priv = (struct efm32_leuart_s*)dev->priv; switch (cmd) { case xxx: /* Add commands here */ break; default: ret = -ENOTTY; break; } return ret; #else return -ENOTTY; #endif } /**************************************************************************** * Name: efm32_receive * * Description: * Called (usually) from the interrupt level to receive one * character from the UART. Error bits associated with the * receipt are provided in the return 'status'. * ****************************************************************************/ static int efm32_receive(struct uart_dev_s *dev, uint32_t *status) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; uint32_t rxdatax; /* Get error status information: * * FERR Data Framing Error * PERR Data Parity Error */ rxdatax = efm32_serialin(priv, EFM32_LEUART_RXDATAX_OFFSET); /* Return status information */ if (status) { *status = rxdatax; } /* Then return the actual received byte. */ return (int)(rxdatax & _LEUART_RXDATAX_RXDATA_MASK); } /**************************************************************************** * Name: efm32_rxint * * Description: * Call to enable or disable RX interrupts * ****************************************************************************/ static void efm32_rxint(struct uart_dev_s *dev, bool enable) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; irqstate_t flags; flags = irqsave(); if (enable) { /* Receive an interrupt when their is anything in the Rx data register (or an Rx * timeout occurs). */ #ifndef CONFIG_SUPPRESS_SERIAL_INTS priv->ien |= EFM32_RX_INTS; efm32_setuartint(priv); #endif } else { priv->ien &= ~EFM32_RX_INTS; efm32_setuartint(priv); } irqrestore(flags); } /**************************************************************************** * Name: efm32_rxavailable * * Description: * Return true if the receive register is not empty * ****************************************************************************/ static bool efm32_rxavailable(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; /* Return true if the receive data is available (RXDATAV). */ return (efm32_serialin(priv, EFM32_LEUART_STATUS_OFFSET) & LEUART_STATUS_RXDATAV) != 0; } /**************************************************************************** * Name: efm32_send * * Description: * This method will send one byte on the UART. * ****************************************************************************/ static void efm32_send(struct uart_dev_s *dev, int ch) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; efm32_serialout(priv, EFM32_LEUART_TXDATA_OFFSET, (uint32_t)ch); } /**************************************************************************** * Name: efm32_txint * * Description: * Call to enable or disable TX interrupts * ****************************************************************************/ static void efm32_txint(struct uart_dev_s *dev, bool enable) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; irqstate_t flags; flags = irqsave(); if (enable) { /* Enable the TX interrupt */ #ifndef CONFIG_SUPPRESS_SERIAL_INTS priv->ien |= EFM32_TX_INTS; efm32_setuartint(priv); /* Fake a TX interrupt here by just calling uart_xmitchars() with * interrupts disabled (note this may recurse). */ uart_xmitchars(dev); #endif } else { /* Disable the TX interrupt */ priv->ien &= ~EFM32_TX_INTS; efm32_setuartint(priv); } irqrestore(flags); } /**************************************************************************** * Name: efm32_txready * * Description: * Return true if the transmit data register is not full * ****************************************************************************/ static bool efm32_txready(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; /* The TX Buffer Level (TXBL) status bit indicates the level of the * transmit buffer. Set when the transmit buffer is empty, and cleared * when it is full. */ return (efm32_serialin(priv, EFM32_LEUART_STATUS_OFFSET) & LEUART_STATUS_TXBL) != 0; } /**************************************************************************** * Name: efm32_txempty * * Description: * Return true if the transmit data register is empty * ****************************************************************************/ static bool efm32_txempty(struct uart_dev_s *dev) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)dev->priv; /* TX Complete (TXC) is set when a transmission has completed and no more * data is available in the transmit buffer. */ return (efm32_serialin(priv, EFM32_LEUART_STATUS_OFFSET) & LEUART_STATUS_TXC) != 0; } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: up_earlyserialinit * * Description: * Performs the low level UART initialization early in debug so that the * serial console will be available during bootup. This must be called * before up_serialinit. NOTE: This function depends on GPIO pin * configuration performed in efm32_consoleinit() and main clock iniialization * performed in efm32_clkinitialize(). * ****************************************************************************/ void up_earlyserialinit(void) { /* Disable interrupts from all UARTS. The console is enabled in * pic32mx_consoleinit() */ efm32_restoreuartint(TTYLE0_DEV.priv, 0); #ifdef TTYLE1_DEV efm32_restoreuartint(TTYLE1_DEV.priv, 0); #endif /* Configuration whichever one is the console */ #ifdef CONSOLE_DEV CONSOLE_DEV.isconsole = true; efm32_setup(&CONSOLE_DEV); #endif } /**************************************************************************** * Name: up_serialinit * * Description: * Register serial console and serial ports. This assumes that * up_earlyserialinit was called previously. * ****************************************************************************/ void up_serialinit(void) { /* Register the console */ #ifdef CONSOLE_DEV (void)uart_register("/dev/console", &CONSOLE_DEV); #endif /* Register all UARTs */ (void)uart_register("/dev/ttyLE0", &TTYLE0_DEV); #ifdef TTYLE1_DEV (void)uart_register("/dev/ttyLE1", &TTYLE1_DEV); #endif } /**************************************************************************** * Name: up_putc * * Description: * Provide priority, low-level access to support OS debug writes * ****************************************************************************/ #ifdef HAVE_LEUART_CONSOLE int up_putc(int ch) { struct efm32_leuart_s *priv = (struct efm32_leuart_s*)CONSOLE_DEV.priv; uint32_t ien; efm32_disableuartint(priv, &ien); /* Check for LF */ if (ch == '\n') { /* Add CR */ efm32_lowputc('\r'); } efm32_lowputc(ch); efm32_restoreuartint(priv, ien); return ch; } #endif #else /* USE_SERIALDRIVER */ /**************************************************************************** * Name: up_putc * * Description: * Provide priority, low-level access to support OS debug writes * ****************************************************************************/ #ifdef HAVE_LEUART_CONSOLE int up_putc(int ch) { /* Check for LF */ if (ch == '\n') { /* Add CR */ efm32_lowputc('\r'); } efm32_lowputc(ch); return ch; } #endif #endif /* USE_SERIALDRIVER */