@@ -1596,4 +1596,26 @@ config SERIAL_PCH_UART
This driver is for PCH(Platform controller Hub) UART of Intel EG20T
which is an IOH(Input/Output Hub) for x86 embedded processor.
Enabling PCH_DMA, this PCH UART works as DMA mode.
+
+#
+# SUART Kernel Configuration
+#
+
+config SERIAL_PRUSS_SUART
+ depends on ARCH_DAVINCI && ARCH_DAVINCI_DA850
+ select SERIAL_CORE
+ tristate "PRUSS based SoftUART emulation on DA8XX"
+ ---help---
+ This driver emulates upto eight different UARTs on the PRUSS.
+ You may modify the NR_SUARTS macro in the driver to emulate
+ less number of UARTS as per your requirement.
+ If not sure, mark N
+
+config PRUSS_SUART_MCASP
+ int "McASP number"
+ depends on ARCH_DAVINCI && ARCH_DAVINCI_DA830 && SERIAL_PRUSS_SUART
+ default "0"
+ ---help---
+ Enter the McASP number to use with SUART (0, 1 or 2).
+ You will need to recompile the kernel if this is changed.
endmenu
@@ -92,3 +92,13 @@ obj-$(CONFIG_SERIAL_MRST_MAX3110) += mrst_max3110.o
obj-$(CONFIG_SERIAL_MFD_HSU) += mfd.o
obj-$(CONFIG_SERIAL_IFX6X60) += ifx6x60.o
obj-$(CONFIG_SERIAL_PCH_UART) += pch_uart.o
+
+#
+# Makefile for SoftUART emulation
+#
+
+suart_emu-objs := pruss_suart.o \
+ pruss_suart_api.o \
+ pruss_suart_utils.o
+
+obj-$(CONFIG_SERIAL_PRUSS_SUART) += suart_emu.o
new file mode 100644
@@ -0,0 +1,1058 @@
+/*
+ * PRUSS SUART Emulation device driver
+ * Author: subhasish@mistralsolutions.com
+ *
+ * This driver supports TI's PRU SUART Emulation and the
+ * specs for the same is available at <http://www.ti.com>
+ *
+ * Copyright (C) 2009 Texas Instruments Incorporated - http://www.ti.com/
+ *
+ * This program is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU General Public License as
+ * published by the Free Software Foundation version 2.
+ *
+ * This program is distributed as is WITHOUT ANY WARRANTY of any
+ * kind, whether express or implied; without even the implied warranty
+ * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
+ * GNU General Public License for more details.
+ */
+
+#include <linux/kernel.h>
+#include <linux/errno.h>
+#include <linux/init.h>
+#include <linux/slab.h>
+#include <linux/tty.h>
+#include <linux/tty_flip.h>
+#include <linux/serial.h>
+#include <linux/serial_core.h>
+#include <linux/module.h>
+#include <mach/da8xx.h>
+#include <linux/platform_device.h>
+#include <linux/firmware.h>
+#include <linux/clk.h>
+#include <linux/serial_reg.h>
+#include <linux/delay.h>
+#include <linux/bitops.h>
+#include <mach/sram.h>
+#include "pruss_suart.h"
+
+#define NR_SUART 8
+#define DRV_NAME "da8xx_pruss_uart"
+#define DRV_DESC "PRUSS SUART Driver v1.0"
+#define MAX_SUART_RETRIES 100
+#define SUART_CNTX_SZ 512
+#define SUART_FIFO_TIMEOUT_DFLT 5
+#define SUART_FIFO_TIMEOUT_MIN 4
+#define SUART_FIFO_TIMEOUT_MAX 500
+
+/* Default timeout set to 5ms */
+static s16 suart_timeout = SUART_FIFO_TIMEOUT_DFLT;
+module_param(suart_timeout, short, S_IRUGO);
+MODULE_PARM_DESC(suart_timeout,
+ "fifo timeout in milli seconds (min: 4; max: 500)");
+
+struct suart_fifo {
+ void *fifo_vaddr_buff_tx;
+ void *fifo_vaddr_buff_rx;
+ void *fifo_phys_addr_tx;
+ void *fifo_phys_addr_rx;
+};
+
+struct omapl_pru_suart {
+ struct uart_port port[NR_SUART];
+ struct device *dev;
+ unsigned long tx_empty[NR_SUART];
+ struct clk *clk_mcasp;
+ struct suart_fifo suart_fifo_addr[NR_SUART];
+ const struct firmware *fw;
+ struct suart_handle suart_hdl[NR_SUART];
+ struct pruss_suart_iomap suart_iomap;
+ struct tasklet_struct tx_task[NR_SUART];
+ u32 clk_freq_pru;
+ u32 clk_freq_mcasp;
+ u32 tx_loadsz;
+};
+
+static u32 suart_get_duplex(struct omapl_pru_suart *soft_uart, u32 uart_no)
+{
+ return soft_uart->suart_hdl[uart_no].uart_type;
+}
+
+static inline void __stop_tx(struct omapl_pru_suart *soft_uart, u32 uart_no)
+{
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+ struct uart_port *port = &soft_uart->port[uart_no];
+ u16 txready;
+ u32 i;
+
+ /* Check if any TX in progress */
+ for (i = 0, txready = 1; (i < 10000) && txready; i++) {
+ txready = (pru_softuart_get_tx_status
+ (dev, &soft_uart->suart_hdl[uart_no]) &
+ CHN_TXRX_STATUS_RDY);
+ }
+ /* To stop tx, disable the TX interrupt */
+ spin_lock_irqsave(&port->lock, flags);
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[uart_no].uart_num,
+ PRU_TX_INTR, CHN_TXRX_IE_MASK_CMPLT);
+ pru_softuart_clr_tx_status(dev, &soft_uart->suart_hdl[uart_no]);
+ spin_unlock_irqrestore(&port->lock, flags);
+}
+
+static void pruss_suart_stop_tx(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+
+ __stop_tx(soft_uart, port->line);
+}
+
+static void omapl_pru_tx_chars(struct omapl_pru_suart *soft_uart, u32 uart_no)
+{
+ struct circ_buf *xmit = &soft_uart->port[uart_no].state->xmit;
+ struct device *dev = soft_uart->dev;
+ s32 count = 0;
+
+ if (!(suart_get_duplex(soft_uart, uart_no) & ePRU_SUART_HALF_TX))
+ return;
+
+ if (uart_circ_empty(xmit) ||
+ uart_tx_stopped(&soft_uart->port[uart_no])) {
+ pruss_suart_stop_tx(&soft_uart->port[uart_no]);
+ set_bit(0, &soft_uart->tx_empty[uart_no]);
+ return;
+ }
+
+ for (count = 0; count <= soft_uart->tx_loadsz; count++) {
+ *((s8 *)soft_uart->suart_fifo_addr[uart_no].fifo_vaddr_buff_tx
+ + count) = xmit->buf[xmit->tail];
+ xmit->tail = (xmit->tail + 1) & (UART_XMIT_SIZE - 1);
+ soft_uart->port[uart_no].icount.tx++;
+ if (uart_circ_empty(xmit)) {
+ uart_circ_clear(xmit);
+ break;
+ }
+ }
+
+ if (count == (SUART_FIFO_LEN + 1))
+ count = SUART_FIFO_LEN;
+
+ /* Write the character to the data port */
+ if (pru_softuart_write(dev,
+ &soft_uart->suart_hdl[uart_no],
+ (u32 *)&soft_uart->suart_fifo_addr
+ [uart_no].fifo_phys_addr_tx, count) != 0) {
+ dev_err(dev, "failed to tx data\n");
+ }
+
+ if (uart_circ_chars_pending(xmit) < WAKEUP_CHARS)
+ uart_write_wakeup(&soft_uart->port[uart_no]);
+
+#if 0
+ if (uart_circ_empty(xmit))
+ __stop_tx(soft_uart, uart_no);
+#endif
+}
+
+static void suart_tx_task(unsigned long data)
+{
+ struct uart_port *port = (struct uart_port *)data;
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+
+ omapl_pru_tx_chars(soft_uart, port->line);
+}
+
+static void omapl_pru_rx_chars(struct omapl_pru_suart *soft_uart, u32 uart_no)
+{
+ struct tty_struct *tty = NULL;
+ struct device *dev = soft_uart->dev;
+ s8 flags = TTY_NORMAL;
+ u16 rx_status, data_len = SUART_FIFO_LEN;
+ u32 data_len_read;
+ u8 suart_data[SUART_FIFO_LEN + 1];
+ s32 i = 0;
+
+ if (!(suart_get_duplex(soft_uart, uart_no) & ePRU_SUART_HALF_RX))
+ return;
+
+ /* read the status */
+ rx_status = pru_softuart_get_rx_status(dev,
+ &soft_uart->suart_hdl[uart_no]);
+
+ pru_softuart_read_data(dev, &soft_uart->suart_hdl[uart_no],
+ suart_data, data_len + 1, &data_len_read);
+
+ tty = tty_port_tty_get(&soft_uart->port[uart_no].state->port);
+
+ if (!tty)
+ return;
+
+ /* check for errors */
+ if (rx_status & CHN_TXRX_STATUS_ERR) {
+ if (rx_status & CHN_TXRX_STATUS_FE)
+ soft_uart->port[uart_no].icount.frame++;
+ if (rx_status & CHN_TXRX_STATUS_OVRNERR)
+ soft_uart->port[uart_no].icount.overrun++;
+ if (rx_status & CHN_TXRX_STATUS_BI)
+ soft_uart->port[uart_no].icount.brk++;
+ rx_status &= soft_uart->port[uart_no].
+ read_status_mask;
+ if (rx_status & CHN_TXRX_STATUS_FE)
+ flags = TTY_FRAME;
+ if (rx_status & CHN_TXRX_STATUS_OVRNERR)
+ flags = TTY_OVERRUN;
+ if (rx_status & CHN_TXRX_STATUS_BI)
+ flags = TTY_BREAK;
+
+#ifdef SUPPORT_SYSRQ
+ soft_uart->port[uart_no].sysrq = 0;
+#endif
+ } else {
+ for (i = 0; i <= data_len_read; i++) {
+ soft_uart->port[uart_no].icount.rx++;
+ /* check for sys rq */
+ if (uart_handle_sysrq_char
+ (&soft_uart->port[uart_no], suart_data))
+ continue;
+ }
+ tty_insert_flip_string(tty, suart_data, data_len_read);
+ }
+
+ /* push data into tty */
+ pru_softuart_clr_rx_status(dev, &soft_uart->suart_hdl[uart_no]);
+ tty_flip_buffer_push(tty);
+ tty_kref_put(tty);
+}
+
+static irqreturn_t pruss_suart_interrupt(s32 irq, void *dev_id)
+{
+ struct uart_port *port = dev_id;
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ u16 txrx_flag;
+ u32 ret;
+ unsigned long flags = 0;
+ u16 uart_num = port->line + 1;
+
+ spin_lock_irqsave(&port->lock, flags);
+
+ do {
+ ret = pru_softuart_get_isrstatus(dev, uart_num, &txrx_flag);
+ if (ret != 0) {
+ dev_err(dev, "suart%d: failed to get interrupt, ret:"
+ " 0x%X txrx_flag 0x%X\n",
+ port->line, ret, txrx_flag);
+ spin_unlock_irqrestore(&port->lock, flags);
+ return IRQ_NONE;
+ }
+ if ((PRU_RX_INTR & txrx_flag) == PRU_RX_INTR) {
+ pru_intr_clr_isrstatus(dev, uart_num, PRU_RX_INTR);
+ if ((soft_uart->port[port->line].ignore_status_mask &
+ CHN_TXRX_STATUS_RDY) == CHN_TXRX_STATUS_RDY) {
+ pru_softuart_clr_rx_status(dev,
+ &soft_uart->suart_hdl
+ [port->line]);
+ } else {
+ omapl_pru_rx_chars(soft_uart, port->line);
+ }
+ }
+
+ if ((PRU_TX_INTR & txrx_flag) == PRU_TX_INTR) {
+ pru_intr_clr_isrstatus(dev, uart_num, PRU_TX_INTR);
+ pru_softuart_clr_tx_status(dev, &soft_uart->suart_hdl
+ [port->line]);
+ tasklet_schedule(&soft_uart->tx_task[port->line]);
+ }
+ } while (txrx_flag & (PRU_RX_INTR | PRU_TX_INTR));
+
+ spin_unlock_irqrestore(&port->lock, flags);
+ return IRQ_HANDLED;
+}
+
+static void pruss_suart_stop_rx(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+
+ spin_lock_irqsave(&port->lock, flags);
+ /* disable rx interrupt */
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI
+ | CHN_TXRX_IE_MASK_FE | CHN_TXRX_IE_MASK_CMPLT
+ | CHN_TXRX_IE_MASK_TIMEOUT);
+ spin_unlock_irqrestore(&port->lock, flags);
+}
+
+static void pruss_suart_enable_ms(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ dev_err(dev, "modem control timer not supported\n");
+}
+
+static void pruss_suart_start_tx(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+
+ /* unmask the tx interrupts */
+ spin_lock_irqsave(&port->lock, flags);
+ suart_intr_setmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_TX_INTR, CHN_TXRX_IE_MASK_CMPLT);
+ spin_unlock_irqrestore(&port->lock, flags);
+
+ if (test_and_clear_bit(0, &soft_uart->tx_empty[port->line]))
+ omapl_pru_tx_chars(soft_uart, port->line);
+}
+
+static u32 pruss_suart_tx_empty(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+
+ return (pru_softuart_get_tx_status(dev,
+ &soft_uart->suart_hdl[port->line])
+ & CHN_TXRX_STATUS_RDY) ? 0 : TIOCSER_TEMT;
+}
+
+static u32 pruss_suart_get_mctrl(struct uart_port *port)
+{
+ return -ENOTSUPP;
+}
+
+static void pruss_suart_set_mctrl(struct uart_port *port, u32 mctrl)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ dev_dbg(dev, "modem control not supported\n");
+}
+
+static void pruss_suart_break_ctl(struct uart_port *port, s32 break_state)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+
+ spin_lock_irqsave(&port->lock, flags);
+
+ if (break_state == -1)
+ suart_intr_clrmask(dev,
+ soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI);
+ else
+ suart_intr_setmask(dev,
+ soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI);
+
+ spin_unlock_irqrestore(&port->lock, flags);
+}
+
+static void pruss_suart_set_termios(struct uart_port *port,
+ struct ktermios *termios,
+ struct ktermios *old)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ u8 cval = 0;
+ unsigned long flags = 0;
+ u32 baud = 0;
+ u32 old_csize = old ? old->c_cflag & CSIZE : CS8;
+
+/*
+ * Do not allow unsupported configurations to be set
+ */
+ if (1) {
+ termios->c_cflag &= ~(CRTSCTS | CMSPAR | CSTOPB
+ | PARENB | PARODD | CMSPAR);
+ }
+
+ switch (termios->c_cflag & CSIZE) {
+ case CS6:
+ cval = ePRU_SUART_DATA_BITS6;
+ break;
+ case CS7:
+ cval = ePRU_SUART_DATA_BITS7;
+ break;
+ default:
+ case CS8:
+ cval = ePRU_SUART_DATA_BITS8;
+ break;
+ }
+ /*
+ * We do not support CS5.
+ */
+ if ((termios->c_cflag & CSIZE) == CS5) {
+ termios->c_cflag &= ~CSIZE;
+ termios->c_cflag |= old_csize;
+ }
+ if (pru_softuart_setdatabits
+ (dev, &soft_uart->suart_hdl[port->line], cval, cval) != 0)
+ dev_err(dev, "failed to set data bits to: %d\n", cval);
+
+/*
+ * Ask the core to calculate the divisor for us.
+ */
+ baud = uart_get_baud_rate(port, termios, old,
+ port->uartclk / 16 / 0xffff,
+ port->uartclk / 16);
+
+/*
+ * Ok, we're now changing the port state. Do it with
+ * interrupts disabled.
+ */
+ spin_lock_irqsave(&port->lock, flags);
+
+ /* Set the baud */
+ if (pru_softuart_setbaud(dev, &soft_uart->suart_hdl[port->line],
+ SUART_DEFAULT_BAUD / baud,
+ SUART_DEFAULT_BAUD / baud) != 0)
+ dev_err(dev, "failed to set baud to: %d\n", baud);
+
+/*
+ * update port->read_config_mask and port->ignore_config_mask
+ * to indicate the events we are interested in receiving
+ */
+ suart_intr_setmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, SUART_GBL_INTR_ERR_MASK);
+ port->read_status_mask = 0;
+ if (termios->c_iflag & INPCK) { /* Input parity check not supported,
+ just enabled FE */
+ port->read_status_mask |= CHN_TXRX_STATUS_FE;
+ suart_intr_setmask(dev,
+ soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_FE);
+ }
+ if (termios->c_iflag & (BRKINT | PARMRK)) {
+ port->read_status_mask |= CHN_TXRX_STATUS_BI;
+ suart_intr_setmask(dev,
+ soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI);
+ }
+/*
+ * Characters to ignore
+ */
+ port->ignore_status_mask = 0;
+ if (termios->c_iflag & IGNBRK) {
+ port->ignore_status_mask |= CHN_TXRX_STATUS_BI;
+ /*
+ * If we're ignoring break indicators,
+ * ignore overruns too (for real raw support).
+ */
+ if (termios->c_iflag & IGNPAR) {
+ port->ignore_status_mask |=
+ (CHN_TXRX_STATUS_OVRNERR | CHN_TXRX_STATUS_FE);
+ /*
+ * Overrun in case of RX
+ * Underrun in case of TX
+ */
+ suart_intr_clrmask(dev, soft_uart->
+ suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_FE);
+ }
+ suart_intr_clrmask(dev,
+ soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI);
+ }
+/*
+ * ignore all characters if CREAD is not set
+ */
+ if ((termios->c_cflag & CREAD) == 0) {
+ port->ignore_status_mask |= CHN_TXRX_STATUS_RDY;
+ pruss_suart_stop_rx(port);
+ }
+ /*
+ * update the per port timeout
+ */
+ uart_update_timeout(port, termios->c_cflag, baud);
+
+ spin_unlock_irqrestore(&port->lock, flags);
+
+ /* Don't rewrite B0 */
+ if (tty_termios_baud_rate(termios))
+ tty_termios_encode_baud_rate(termios, baud, baud);
+}
+
+/*
+ * Grab any interrupt resources and initialise any low level driver
+ * state. Enable the port for reception. It should not activate
+ * RTS nor DTR; this will be done via a separate call to set_mctrl.
+ *
+ * This method will only be called when the port is initially opened.
+ *
+ * Locking: port_sem taken.
+ * Interrupts: globally disabled.
+ */
+static s32 pruss_suart_startup(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+ s32 retval;
+
+ /*
+ * Disable interrupts from this port
+ */
+ spin_lock_irqsave(&port->lock, flags);
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_TX_INTR, CHN_TXRX_IE_MASK_CMPLT);
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI
+ | CHN_TXRX_IE_MASK_FE | CHN_TXRX_IE_MASK_CMPLT
+ | CHN_TXRX_IE_MASK_TIMEOUT);
+ spin_unlock_irqrestore(&port->lock, flags);
+
+ retval = request_irq(port->irq, pruss_suart_interrupt,
+ port->irqflags, "suart_irq", port);
+ if (retval) {
+ free_irq(port->irq, port); /* should we free this if err */
+ goto out;
+ }
+ /*
+ * enable interrupts from this port
+ */
+ spin_lock_irqsave(&port->lock, flags);
+ suart_intr_setmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, SUART_GBL_INTR_ERR_MASK);
+
+ suart_intr_setmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI
+ | CHN_TXRX_IE_MASK_FE | CHN_TXRX_IE_MASK_CMPLT
+ | CHN_TXRX_IE_MASK_TIMEOUT);
+
+ suart_intr_setmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_TX_INTR, CHN_TXRX_IE_MASK_CMPLT);
+ spin_unlock_irqrestore(&port->lock, flags);
+
+ if ((suart_get_duplex(soft_uart, port->line) & ePRU_SUART_HALF_TX)
+ == ePRU_SUART_HALF_TX) {
+ suart_pru_to_host_intr_enable(dev, soft_uart->
+ suart_hdl[port->line].uart_num, PRU_TX_INTR, true);
+ }
+ /* Seed RX if port is half-rx or full-duplex */
+ if ((suart_get_duplex(soft_uart, port->line) & ePRU_SUART_HALF_RX)
+ == ePRU_SUART_HALF_RX) {
+ suart_pru_to_host_intr_enable(dev, soft_uart->
+ suart_hdl[port->line].uart_num, PRU_RX_INTR, true);
+ pru_softuart_read(dev, &soft_uart->suart_hdl[port->line],
+ (u32 *)&soft_uart->suart_fifo_addr[port->line].
+ fifo_phys_addr_rx, SUART_FIFO_LEN);
+ }
+out:
+ return retval;
+}
+
+/*
+ * Disable the port, disable any break condition that may be in
+ * effect, and free any interrupt resources. It should not disable
+ * RTS nor DTR; this will have already been done via a separate
+ * call to set_mctrl.
+ *
+ * Drivers must not access port->info once this call has completed.
+ *
+ * This method will only be called when there are no more users of
+ * this port.
+ *
+ * Locking: port_sem taken.
+ * Interrupts: caller dependent.
+ */
+
+static void pruss_suart_shutdown(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct device *dev = soft_uart->dev;
+ unsigned long flags = 0;
+
+ /*
+ * Disable interrupts from this port
+ */
+ /* Disable BI and FE intr */
+ spin_lock_irqsave(&port->lock, flags);
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_TX_INTR, CHN_TXRX_IE_MASK_CMPLT);
+ suart_intr_clrmask(dev, soft_uart->suart_hdl[port->line].uart_num,
+ PRU_RX_INTR, CHN_TXRX_IE_MASK_BI
+ | CHN_TXRX_IE_MASK_FE | CHN_TXRX_IE_MASK_CMPLT
+ | CHN_TXRX_IE_MASK_TIMEOUT);
+ spin_unlock_irqrestore(&port->lock, flags);
+
+ /* free interrupts */
+ free_irq(port->irq, port);
+}
+
+/*
+ * Return a pointer to a string constant describing the specified
+ * port, or return NULL, in which case the string 'unknown' is
+ * substituted.
+ *
+ * Locking: none.
+ * Interrupts: caller dependent.
+ */
+
+static const char *pruss_suart_type(struct uart_port *port)
+{
+ return "suart_tty";
+}
+
+/*
+ * Release any memory and IO region resources currently in use by
+ * the port.
+ *
+ * Locking: none.
+ * Interrupts: caller dependent.
+ */
+
+static void pruss_suart_release_port(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct platform_device *pdev = to_platform_device(port->dev);
+
+ if (0 != pru_softuart_close(&soft_uart->suart_hdl[port->line]))
+ dev_err(&pdev->dev, "failed to close suart\n");
+
+ return;
+}
+
+/*
+ * Request any memory and IO region resources required by the port.
+ * If any fail, no resources should be registered when this function
+ * returns, and it should return -EBUSY on failure.
+ *
+ * Locking: none.
+ * Interrupts: caller dependent.
+ *
+ * We need to d/l the f/w in probe and since this api
+ * is called per uart, the request_mem_region should
+ * be called in probe itself.
+ */
+static s32 pruss_suart_request_port(struct uart_port *port)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ struct platform_device *pdev = to_platform_device(port->dev);
+ struct device *dev = soft_uart->dev;
+ struct suart_config pru_suart_config;
+ s16 timeout = 0;
+ u32 err = 0;
+
+ if (soft_uart == NULL) {
+ dev_err(&pdev->dev, "soft_uart ptr failed\n");
+ return -ENODEV;
+ }
+ err = pru_softuart_open(&soft_uart->suart_hdl[port->line]);
+ if (err != 0) {
+ dev_err(&pdev->dev, "failed to open suart: %d\n", err);
+ err = -ENODEV;
+ goto exit;
+ }
+ set_bit(0, &soft_uart->tx_empty[port->line]);
+
+ /* set fifo /timeout */
+ if (SUART_FIFO_TIMEOUT_MIN > suart_timeout) {
+ dev_err(&pdev->dev, "fifo timeout less than %d ms not supported\n",
+ SUART_FIFO_TIMEOUT_MIN);
+ suart_timeout = SUART_FIFO_TIMEOUT_MIN;
+ } else if (SUART_FIFO_TIMEOUT_MAX < suart_timeout) {
+ dev_err(&pdev->dev, "fifo timeout more than %d ms not supported\n",
+ SUART_FIFO_TIMEOUT_MAX);
+ suart_timeout = SUART_FIFO_TIMEOUT_MAX;
+ }
+
+ /* This is only for x8 */
+ timeout = (SUART_DEFAULT_BAUD * suart_timeout) / 1000;
+ pru_set_fifo_timeout(dev, timeout);
+
+ if (soft_uart->suart_hdl[port->line].uart_num == PRU_SUART_UART1) {
+ pru_suart_config.tx_serializer = PRU_SUART0_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART0_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART2) {
+ pru_suart_config.tx_serializer = PRU_SUART1_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART1_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART3) {
+ pru_suart_config.tx_serializer = PRU_SUART2_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART2_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART4) {
+ pru_suart_config.tx_serializer = PRU_SUART3_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART3_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART5) {
+ pru_suart_config.tx_serializer = PRU_SUART4_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART4_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART6) {
+ pru_suart_config.tx_serializer = PRU_SUART5_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART5_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART7) {
+ pru_suart_config.tx_serializer = PRU_SUART6_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART6_CONFIG_RX_SER;
+ } else if (soft_uart->suart_hdl[port->line].uart_num ==
+ PRU_SUART_UART8) {
+ pru_suart_config.tx_serializer = PRU_SUART7_CONFIG_TX_SER;
+ pru_suart_config.rx_serializer = PRU_SUART7_CONFIG_RX_SER;
+ } else {
+ return -ENOTSUPP;
+ }
+
+ /* Some defaults to startup. reconfigured by terimos later */
+ pru_suart_config.tx_clk_divisor = 1;
+ pru_suart_config.rx_clk_divisor = 1;
+ pru_suart_config.tx_bits_per_char = ePRU_SUART_DATA_BITS8;
+ pru_suart_config.rx_bits_per_char = ePRU_SUART_DATA_BITS8;
+ pru_suart_config.oversampling = SUART_DEFAULT_OVRSMPL;
+
+ if (pru_softuart_setconfig(dev, &soft_uart->suart_hdl[port->line],
+ &pru_suart_config) != 0) {
+ dev_err(&pdev->dev,
+ "pru_softuart_setconfig: failed to set config: %X\n",
+ err);
+ }
+exit:
+ return err;
+}
+
+/*
+ * Perform any autoconfiguration steps required for the port. `flag`
+ * contains a bit mask of the required configuration. UART_CONFIG_TYPE
+ * indicates that the port requires detection and identification.
+ * port->type should be set to the type found, or PORT_UNKNOWN if
+ * no port was detected.
+ *
+ * UART_CONFIG_IRQ indicates autoconfiguration of the interrupt signal,
+ * which should be probed using standard kernel autoprobing techniques.
+ * This is not necessary on platforms where ports have interrupts
+ * internally hard wired (eg, system on a chip implementations).
+ *
+ * Locking: none.
+ * Interrupts: caller dependent.
+ */
+
+static void pruss_suart_config_port(struct uart_port *port, s32 flags)
+{
+ if (flags & UART_CONFIG_TYPE && pruss_suart_request_port(port) == 0)
+ port->type = PORT_DA8XX_PRU_SUART;
+}
+
+/*
+ * Verify the new serial port information contained within serinfo is
+ * suitable for this port type.
+ *
+ * Locking: none.
+ * Interrupts: caller dependent.
+ */
+static s32 pruss_suart_verify_port(struct uart_port *port,
+ struct serial_struct *ser)
+{
+ struct omapl_pru_suart *soft_uart =
+ container_of(port, struct omapl_pru_suart, port[port->line]);
+ s32 ret = 0;
+
+ if (ser->type != PORT_UNKNOWN && ser->type != PORT_DA8XX_PRU_SUART)
+ ret = -EINVAL;
+ if (soft_uart->port[port->line].irq != ser->irq)
+ ret = -EINVAL;
+ if (ser->io_type != UPIO_MEM)
+ ret = -EINVAL;
+ if (soft_uart->port[port->line].uartclk / 16 != ser->baud_base)
+ ret = -EINVAL;
+ if ((void *)soft_uart->port[port->line].mapbase != ser->iomem_base)
+ ret = -EINVAL;
+ if (soft_uart->port[port->line].iobase != ser->port)
+ ret = -EINVAL;
+ return ret;
+}
+
+static struct uart_ops pruss_suart_ops = {
+ .tx_empty = pruss_suart_tx_empty,
+ .set_mctrl = pruss_suart_set_mctrl,
+ .get_mctrl = pruss_suart_get_mctrl,
+ .stop_tx = pruss_suart_stop_tx,
+ .start_tx = pruss_suart_start_tx,
+ .stop_rx = pruss_suart_stop_rx,
+ .enable_ms = pruss_suart_enable_ms,
+ .break_ctl = pruss_suart_break_ctl,
+ .startup = pruss_suart_startup,
+ .shutdown = pruss_suart_shutdown,
+ .set_termios = pruss_suart_set_termios,
+ .type = pruss_suart_type,
+ .release_port = pruss_suart_release_port,
+ .request_port = pruss_suart_request_port,
+ .config_port = pruss_suart_config_port,
+ .verify_port = pruss_suart_verify_port,
+};
+
+static struct uart_driver pruss_suart_reg = {
+ .owner = THIS_MODULE,
+ .driver_name = DRV_NAME,
+ .dev_name = "ttySU",
+ .major = 0,
+ .minor = 16,
+ .nr = NR_SUART,
+};
+
+static s32 __devinit pruss_suart_probe(struct platform_device *pdev)
+{
+ struct omapl_pru_suart *soft_uart;
+ const struct da850_evm_pruss_suart_data *pdata;
+ struct device *dev = &pdev->dev;
+ struct resource *res;
+ s32 err, i;
+ u8 *fw_data = NULL;
+
+ pdata = dev->platform_data;
+ if (!pdata) {
+ dev_err(&pdev->dev, "platform data not found\n");
+ return -EINVAL;
+ }
+
+ soft_uart = kzalloc(sizeof(struct omapl_pru_suart), GFP_KERNEL);
+ if (!soft_uart)
+ return -ENOMEM;
+
+ res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
+ if (!res) {
+ dev_err(&pdev->dev, "failed to get resource");
+ return -ENOMEM;
+ }
+
+ if (!request_mem_region(res->start,
+ resource_size(res),
+ dev_name(&pdev->dev))) {
+ dev_err(&pdev->dev, "mcasp memory region already claimed!\n");
+ err = -EBUSY;
+ goto probe_exit;
+ }
+
+ soft_uart->suart_iomap.mcasp_io_addr = ioremap(res->start,
+ resource_size(res));
+ if (!soft_uart->suart_iomap.mcasp_io_addr) {
+ dev_err(&pdev->dev, "mcasp ioremap failed\n");
+ err = -EFAULT;
+ goto probe_exit_1;
+ }
+
+ soft_uart->suart_iomap.p_fifo_buff_virt_base =
+ sram_alloc(SUART_CNTX_SZ * NR_SUART * 2,
+ (dma_addr_t *) &soft_uart->suart_iomap.p_fifo_buff_phys_base);
+ if (!soft_uart->suart_iomap.p_fifo_buff_virt_base)
+ goto probe_exit_iounmap;
+
+ soft_uart->clk_freq_pru = pruss_get_clk_freq(dev);
+
+ soft_uart->clk_mcasp = clk_get(&pdev->dev, NULL);
+ if (IS_ERR(soft_uart->clk_mcasp)) {
+ dev_err(&pdev->dev, "no clock available: mcasp\n");
+ err = -ENODEV;
+ soft_uart->clk_mcasp = NULL;
+ goto probe_exit_sram_free;
+ }
+
+ soft_uart->clk_freq_mcasp = clk_get_rate(soft_uart->clk_mcasp);
+ clk_enable(soft_uart->clk_mcasp);
+
+ err = request_firmware(&soft_uart->fw, "PRU_SUART_Emulation.bin",
+ &pdev->dev);
+ if (err) {
+ dev_err(&pdev->dev, "can't load firmware\n");
+ err = -ENODEV;
+ goto probe_exit_clk;
+ }
+ dev_info(&pdev->dev, "fw size %td. downloading...\n",
+ soft_uart->fw->size);
+
+ /* download firmware into pru & init */
+ fw_data = kmalloc(soft_uart->fw->size, GFP_KERNEL);
+ memcpy((void *)fw_data, (const void *)soft_uart->fw->data,
+ soft_uart->fw->size);
+
+ soft_uart->suart_iomap.pru_clk_freq =
+ (soft_uart->clk_freq_pru / 1000000);
+
+ err = pru_softuart_init(dev, SUART_DEFAULT_BAUD, SUART_DEFAULT_BAUD,
+ SUART_DEFAULT_OVRSMPL, fw_data,
+ soft_uart->fw->size, &soft_uart->suart_iomap);
+ if (err) {
+ dev_err(&pdev->dev, "pruss init error\n");
+ err = -ENODEV;
+ kfree((const void *)fw_data);
+ goto probe_release_fw;
+ }
+ kfree((const void *)fw_data);
+
+ platform_set_drvdata(pdev, &soft_uart->port[0]);
+ soft_uart->dev = dev;
+
+ for (i = 0; i < NR_SUART; i++) {
+ soft_uart->port[i].ops = &pruss_suart_ops;
+ soft_uart->port[i].iotype = UPIO_MEM;
+ soft_uart->port[i].flags = UPF_BOOT_AUTOCONF | UPF_IOREMAP;
+ soft_uart->port[i].mapbase =
+ (u32)soft_uart->suart_iomap.p_fifo_buff_virt_base;
+ soft_uart->port[i].membase =
+ (u8 *)&soft_uart->suart_iomap;
+ soft_uart->port[i].type = PORT_DA8XX_PRU_SUART;
+ soft_uart->port[i].irq =
+ platform_get_irq(to_platform_device(dev->parent), i);
+ soft_uart->port[i].dev = &pdev->dev;
+ soft_uart->port[i].irqflags = IRQF_SHARED;
+ soft_uart->port[i].uartclk = soft_uart->clk_freq_mcasp;
+ soft_uart->port[i].fifosize = SUART_FIFO_LEN;
+ soft_uart->tx_loadsz = SUART_FIFO_LEN;
+ soft_uart->port[i].custom_divisor = 1;
+ soft_uart->port[i].line = i;
+ soft_uart->suart_hdl[i].uart_num = i + 1;
+ soft_uart->port[i].serial_in = NULL;
+
+ soft_uart->suart_fifo_addr[i].fifo_vaddr_buff_tx =
+ soft_uart->suart_iomap.p_fifo_buff_virt_base +
+ (2 * SUART_CNTX_SZ * i);
+
+ soft_uart->suart_fifo_addr[i].fifo_vaddr_buff_rx =
+ soft_uart->suart_iomap.p_fifo_buff_virt_base +
+ ((2 * SUART_CNTX_SZ * i) + SUART_CNTX_SZ);
+
+ soft_uart->suart_fifo_addr[i].fifo_phys_addr_tx =
+ soft_uart->suart_iomap.p_fifo_buff_phys_base +
+ (2 * SUART_CNTX_SZ * i);
+
+ soft_uart->suart_fifo_addr[i].fifo_phys_addr_rx =
+ soft_uart->suart_iomap.p_fifo_buff_phys_base +
+ ((2 * SUART_CNTX_SZ * i) + SUART_CNTX_SZ);
+
+ soft_uart->port[i].serial_out = NULL;
+ tasklet_init(&soft_uart->tx_task[i], suart_tx_task,
+ (unsigned long)&soft_uart->port[i]);
+ uart_add_one_port(&pruss_suart_reg, &soft_uart->port[i]);
+ }
+
+ dev_info(&pdev->dev,
+ "%s device registered (pru_clk=%d, asp_clk=%d)\n",
+ DRV_NAME, soft_uart->clk_freq_pru, soft_uart->clk_freq_mcasp);
+
+ return 0;
+
+probe_release_fw:
+ release_firmware(soft_uart->fw);
+probe_exit_clk:
+ clk_put(soft_uart->clk_mcasp);
+ clk_disable(soft_uart->clk_mcasp);
+probe_exit_sram_free:
+ sram_free(soft_uart->suart_iomap.p_fifo_buff_virt_base,
+ SUART_CNTX_SZ * NR_SUART * 2);
+probe_exit_iounmap:
+ iounmap(soft_uart->suart_iomap.mcasp_io_addr);
+probe_exit_1:
+ release_mem_region(res->start,
+ resource_size(res));
+probe_exit:
+ kfree(soft_uart);
+ return err;
+}
+
+static s32 __devexit pruss_suart_remove(struct platform_device *pdev)
+{
+ struct omapl_pru_suart *soft_uart = platform_get_drvdata(pdev);
+ const struct da850_evm_pruss_suart_data *pdata;
+ struct device *dev = &pdev->dev;
+ struct resource *res;
+ int i;
+
+ pdata = dev->platform_data;
+ if (!pdata)
+ dev_err(&pdev->dev, "platform data not found\n");
+
+ res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
+ if (!res) {
+ dev_err(&pdev->dev, "failed to get resource");
+ return -ENOMEM;
+ }
+
+ platform_set_drvdata(pdev, NULL);
+
+ if (soft_uart) {
+ for (i = 0; i < NR_SUART; i++) {
+ uart_remove_one_port(&pruss_suart_reg,
+ &soft_uart->port[i]);
+ }
+ }
+
+ sram_free(soft_uart->suart_iomap.p_fifo_buff_virt_base,
+ SUART_CNTX_SZ * NR_SUART * 2);
+ release_firmware(soft_uart->fw);
+ clk_put(soft_uart->clk_mcasp);
+ pru_mcasp_deinit();
+ clk_disable(soft_uart->clk_mcasp);
+ iounmap(soft_uart->suart_iomap.mcasp_io_addr);
+ if (pdata) {
+ release_mem_region(res->start,
+ resource_size(res));
+ }
+ kfree(soft_uart);
+ return 0;
+}
+
+#define pruss_suart_suspend NULL
+#define pruss_suart_resume NULL
+
+static struct platform_driver serial_pruss_driver = {
+ .probe = pruss_suart_probe,
+ .remove = __devexit_p(pruss_suart_remove),
+ .suspend = pruss_suart_suspend,
+ .resume = pruss_suart_resume,
+ .driver = {
+ .name = DRV_NAME,
+ .owner = THIS_MODULE,
+ },
+};
+
+static s32 __init pruss_suart_init(void)
+{
+ s32 ret;
+
+ pruss_suart_reg.nr = NR_SUART;
+ ret = uart_register_driver(&pruss_suart_reg);
+ if (ret)
+ return ret;
+ ret = platform_driver_register(&serial_pruss_driver);
+ if (ret)
+ goto out;
+
+ pr_debug("SUART serial driver loaded\n");
+ return ret;
+out:
+ uart_unregister_driver(&pruss_suart_reg);
+ return ret;
+}
+
+module_init(pruss_suart_init);
+
+static void __exit pruss_suart_exit(void)
+{
+ platform_driver_unregister(&serial_pruss_driver);
+ uart_unregister_driver(&pruss_suart_reg);
+ pr_debug("SUART serial driver unloaded\n");
+}
+
+module_exit(pruss_suart_exit);
+
+/* Module information */
+MODULE_AUTHOR("Subhasish Ghosh <subhasish@mistralsolutions.com>");
+MODULE_LICENSE("GPL");
+MODULE_DESCRIPTION(DRV_DESC);
new file mode 100644
@@ -0,0 +1,1081 @@
+/*
+ * Copyright (C) 2010 Texas Instruments Incorporated
+ * Author: Jitendra Kumar <jitendra@mistralsolutions.com>
+ *
+ * This program is free software; you can redistribute it and/or modify it
+ * under the terms of the GNU General Public License as published by the
+ * Free Software Foundation version 2.
+ *
+ * This program is distributed "as is" WITHOUT ANY WARRANTY of any kind,
+ * whether express or implied; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * General Public License for more details.
+ */
+
+#ifndef _SUART_API_H_
+#define _SUART_API_H_
+
+#include <linux/types.h>
+#include <linux/bitops.h>
+#include <linux/io.h>
+#include <linux/mfd/da8xx/da8xx_pru.h>
+
+#define SINGLE_PRU 0
+#define BOTH_PRU 1
+#define PRU_ACTIVE BOTH_PRU
+#define PRU_CLK_228 228
+#define PRU_CLK_186 186
+
+#define PRU_SUART_SERIALIZER_0 (0u)
+#define PRU_SUART_SERIALIZER_1 (1u)
+#define PRU_SUART_SERIALIZER_2 (2u)
+#define PRU_SUART_SERIALIZER_3 (3u)
+#define PRU_SUART_SERIALIZER_4 (4u)
+#define PRU_SUART_SERIALIZER_5 (5u)
+#define PRU_SUART_SERIALIZER_6 (6u)
+#define PRU_SUART_SERIALIZER_7 (7u)
+#define PRU_SUART_SERIALIZER_8 (8u)
+#define PRU_SUART_SERIALIZER_9 (9u)
+#define PRU_SUART_SERIALIZER_10 (10u)
+#define PRU_SUART_SERIALIZER_11 (11u)
+#define PRU_SUART_SERIALIZER_12 (12u)
+#define PRU_SUART_SERIALIZER_13 (13u)
+#define PRU_SUART_SERIALIZER_14 (14u)
+#define PRU_SUART_SERIALIZER_15 (15u)
+#define PRU_SUART_SERIALIZER_NONE (16u)
+
+#define PRU_SUART_UART1 (1u)
+#define PRU_SUART_UART2 (2u)
+#define PRU_SUART_UART3 (3u)
+#define PRU_SUART_UART4 (4u)
+#define PRU_SUART_UART5 (5u)
+#define PRU_SUART_UART6 (6u)
+#define PRU_SUART_UART7 (7u)
+#define PRU_SUART_UART8 (8u)
+#define PRU_SUART_UARTx_INVALID (9u)
+
+#define PRU_SUART_HALF_TX (1u)
+#define PRU_SUART_HALF_RX (2u)
+#define PRU_SUART_HALF_TX_DISABLED (4u)
+#define PRU_SUART_HALF_RX_DISABLED (8u)
+
+#define PRU_SUART0_CONFIG_DUPLEX (PRU_SUART_HALF_TX_DISABLED | \
+ PRU_SUART_HALF_RX_DISABLED)
+#define PRU_SUART0_CONFIG_RX_SER (PRU_SUART_SERIALIZER_NONE)
+#define PRU_SUART0_CONFIG_TX_SER (PRU_SUART_SERIALIZER_NONE)
+
+#define PRU_SUART1_CONFIG_DUPLEX (PRU_SUART_HALF_TX | \
+ PRU_SUART_HALF_RX)
+#define PRU_SUART1_CONFIG_RX_SER (PRU_SUART_SERIALIZER_7)
+#define PRU_SUART1_CONFIG_TX_SER (PRU_SUART_SERIALIZER_8)
+
+#define PRU_SUART2_CONFIG_DUPLEX (PRU_SUART_HALF_TX | \
+ PRU_SUART_HALF_RX)
+#define PRU_SUART2_CONFIG_RX_SER (PRU_SUART_SERIALIZER_9)
+#define PRU_SUART2_CONFIG_TX_SER (PRU_SUART_SERIALIZER_10)
+
+#define PRU_SUART3_CONFIG_DUPLEX (PRU_SUART_HALF_TX | \
+ PRU_SUART_HALF_RX)
+#define PRU_SUART3_CONFIG_RX_SER (PRU_SUART_SERIALIZER_13)
+#define PRU_SUART3_CONFIG_TX_SER (PRU_SUART_SERIALIZER_14)
+
+#define PRU_SUART4_CONFIG_DUPLEX (PRU_SUART_HALF_TX_DISABLED | \
+ PRU_SUART_HALF_RX_DISABLED)
+#define PRU_SUART4_CONFIG_RX_SER (PRU_SUART_SERIALIZER_NONE)
+#define PRU_SUART4_CONFIG_TX_SER (PRU_SUART_SERIALIZER_NONE)
+
+#define PRU_SUART5_CONFIG_DUPLEX (PRU_SUART_HALF_TX_DISABLED | \
+ PRU_SUART_HALF_RX_DISABLED)
+#define PRU_SUART5_CONFIG_RX_SER (PRU_SUART_SERIALIZER_NONE)
+#define PRU_SUART5_CONFIG_TX_SER (PRU_SUART_SERIALIZER_NONE)
+
+#define PRU_SUART6_CONFIG_DUPLEX (PRU_SUART_HALF_TX_DISABLED | \
+ PRU_SUART_HALF_RX_DISABLED)
+#define PRU_SUART6_CONFIG_RX_SER (PRU_SUART_SERIALIZER_NONE)
+#define PRU_SUART6_CONFIG_TX_SER (PRU_SUART_SERIALIZER_NONE)
+
+#define PRU_SUART7_CONFIG_DUPLEX (PRU_SUART_HALF_TX_DISABLED | \
+ PRU_SUART_HALF_RX_DISABLED)
+#define PRU_SUART7_CONFIG_RX_SER (PRU_SUART_SERIALIZER_NONE)
+#define PRU_SUART7_CONFIG_TX_SER (PRU_SUART_SERIALIZER_NONE)
+
+#define SUART_NUM_OF_CHANNELS_PER_SUART 2
+#define SUART_NUM_OF_BYTES_PER_CHANNEL 16
+
+#define PRU_TX_INTR 1
+#define PRU_RX_INTR 2
+
+#define CHN_TXRX_STATUS_TIMEOUT BIT(6)
+#define CHN_TXRX_STATUS_BI BIT(5)
+#define CHN_TXRX_STATUS_FE BIT(4)
+#define CHN_TXRX_STATUS_UNERR BIT(3)
+#define CHN_TXRX_STATUS_OVRNERR BIT(3)
+#define CHN_TXRX_STATUS_ERR BIT(2)
+#define CHN_TXRX_STATUS_CMPLT BIT(1)
+#define CHN_TXRX_STATUS_RDY BIT(0)
+
+#define CHN_TXRX_IE_MASK_TIMEOUT BIT(14)
+#define CHN_TXRX_IE_MASK_BI BIT(13)
+#define CHN_TXRX_IE_MASK_FE BIT(12)
+#define CHN_TXRX_IE_MASK_CMPLT BIT(1)
+
+#define SUART_GBL_INTR_ERR_MASK BIT(9)
+#define SUART_PRU_ID_MASK 0xFF
+
+#define SUART_FIFO_LEN 15
+#define SUART_8X_OVRSMPL 1
+#define SUART_16X_OVRSMPL 2
+#define SUART_DEFAULT_OVRSMPL SUART_8X_OVRSMPL
+
+#define SUART_DEFAULT_OVRSMPL_OFFSET 26
+#define SUART_CHN_OFFSET 31
+#define SERIALIZER_OFFSET 8
+
+#if (SUART_DEFAULT_OVRSMPL == SUART_16X_OVRSMPL)
+#define SUART_DEFAULT_BAUD 57600
+#else
+#define SUART_DEFAULT_BAUD 115200
+#endif
+
+#define PRU_MODE_INVALID 0x0
+#define PRU_MODE_TX_ONLY 0x1
+#define PRU_MODE_RX_ONLY 0x2
+#define PRU_MODE_RX_TX_BOTH 0x3
+
+#if (PRU_ACTIVE == BOTH_PRU)
+#define PRU0_MODE PRU_MODE_RX_ONLY
+#define PRU1_MODE PRU_MODE_TX_ONLY
+#elif (PRU_ACTIVE == SINGLE_PRU)
+#define PRU0_MODE PRU_MODE_RX_TX_BOTH
+#define PRU1_MODE PRU_MODE_INVALID
+#else
+#define PRU0_MODE PRU_MODE_INVALID
+#define PRU1_MODE PRU_MODE_INVALID
+#endif
+
+#define MCASP_XBUF_BASE_ADDR (0x01d00200)
+#define MCASP_RBUF_BASE_ADDR (0x01d00280)
+#define MCASP_SRCTL_BASE_ADDR (0x01d00180)
+
+#define MCASP_SRCTL_TX_MODE (0x000D)
+#define MCASP_SRCTL_RX_MODE (0x000E)
+
+/* Since only PRU0 can work as RX */
+#define RX_DEFAULT_DATA_DUMP_ADDR (0x00001FC)
+#define PRU_NUM_OF_CHANNELS (16)
+
+/* MCASP */
+
+#define OMAPL_MCASP_PFUNC_AFSR_MASK (0x80000000u)
+#define OMAPL_MCASP_PFUNC_AFSR_SHIFT (0x0000001Fu)
+#define OMAPL_MCASP_PFUNC_AFSR_RESETVAL (0x00000000u)
+/* AFSR Tokens */
+#define OMAPL_MCASP_PFUNC_AFSR_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AFSR_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AHCLKR_MASK (0x40000000u)
+#define OMAPL_MCASP_PFUNC_AHCLKR_SHIFT (0x0000001Eu)
+#define OMAPL_MCASP_PFUNC_AHCLKR_RESETVAL (0x00000000u)
+/* AHCLKR Tokens */
+#define OMAPL_MCASP_PFUNC_AHCLKR_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AHCLKR_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_ACLKR_MASK (0x20000000u)
+#define OMAPL_MCASP_PFUNC_ACLKR_SHIFT (0x0000001Du)
+#define OMAPL_MCASP_PFUNC_ACLKR_RESETVAL (0x00000000u)
+/* ACLKR Tokens */
+#define OMAPL_MCASP_PFUNC_ACLKR_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_ACLKR_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AFSX_MASK (0x10000000u)
+#define OMAPL_MCASP_PFUNC_AFSX_SHIFT (0x0000001Cu)
+#define OMAPL_MCASP_PFUNC_AFSX_RESETVAL (0x00000000u)
+/* AFSX Tokens */
+#define OMAPL_MCASP_PFUNC_AFSX_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AFSX_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AHCLKX_MASK (0x08000000u)
+#define OMAPL_MCASP_PFUNC_AHCLKX_SHIFT (0x0000001Bu)
+#define OMAPL_MCASP_PFUNC_AHCLKX_RESETVAL (0x00000000u)
+/* AHCLKX Tokens */
+#define OMAPL_MCASP_PFUNC_AHCLKX_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AHCLKX_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_ACLKX_MASK (0x04000000u)
+#define OMAPL_MCASP_PFUNC_ACLKX_SHIFT (0x0000001Au)
+#define OMAPL_MCASP_PFUNC_ACLKX_RESETVAL (0x00000000u)
+/* ACLKX Tokens */
+#define OMAPL_MCASP_PFUNC_ACLKX_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_ACLKX_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AMUTE_MASK (0x02000000u)
+#define OMAPL_MCASP_PFUNC_AMUTE_SHIFT (0x00000019u)
+#define OMAPL_MCASP_PFUNC_AMUTE_RESETVAL (0x00000000u)
+/* AMUTE Tokens */
+#define OMAPL_MCASP_PFUNC_AMUTE_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AMUTE_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR15_MASK (0x00008000u)
+#define OMAPL_MCASP_PFUNC_AXR15_SHIFT (0x0000000Fu)
+#define OMAPL_MCASP_PFUNC_AXR15_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR15_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR15_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR14_MASK (0x00004000u)
+#define OMAPL_MCASP_PFUNC_AXR14_SHIFT (0x0000000Eu)
+#define OMAPL_MCASP_PFUNC_AXR14_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR14_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR14_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR13_MASK (0x00002000u)
+#define OMAPL_MCASP_PFUNC_AXR13_SHIFT (0x0000000Du)
+#define OMAPL_MCASP_PFUNC_AXR13_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR13_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR13_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR12_MASK (0x00001000u)
+#define OMAPL_MCASP_PFUNC_AXR12_SHIFT (0x0000000Cu)
+#define OMAPL_MCASP_PFUNC_AXR12_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR12_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR12_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR11_MASK (0x00000800u)
+#define OMAPL_MCASP_PFUNC_AXR11_SHIFT (0x0000000Bu)
+#define OMAPL_MCASP_PFUNC_AXR11_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR11_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR11_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR10_MASK (0x00000400u)
+#define OMAPL_MCASP_PFUNC_AXR10_SHIFT (0x0000000Au)
+#define OMAPL_MCASP_PFUNC_AXR10_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR10_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR10_GPIO (0x00000001u)
+#define OMAPL_MCASP_PFUNC_AXR9_MASK (0x00000200u)
+#define OMAPL_MCASP_PFUNC_AXR9_SHIFT (0x00000009u)
+#define OMAPL_MCASP_PFUNC_AXR9_RESETVAL (0x00000000u)
+/* AXR9 Token */
+#define OMAPL_MCASP_PFUNC_AXR9_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR9_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR8_MASK (0x00000100u)
+#define OMAPL_MCASP_PFUNC_AXR8_SHIFT (0x00000008u)
+#define OMAPL_MCASP_PFUNC_AXR8_RESETVAL (0x00000000u)
+/* AXR8 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR8_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR8_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR7_MASK (0x00000080u)
+#define OMAPL_MCASP_PFUNC_AXR7_SHIFT (0x00000007u)
+#define OMAPL_MCASP_PFUNC_AXR7_RESETVAL (0x00000000u)
+/* AXR7 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR7_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR7_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR6_MASK (0x00000040u)
+#define OMAPL_MCASP_PFUNC_AXR6_SHIFT (0x00000006u)
+#define OMAPL_MCASP_PFUNC_AXR6_RESETVAL (0x00000000u)
+/* AXR6 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR6_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR6_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR5_MASK (0x00000020u)
+#define OMAPL_MCASP_PFUNC_AXR5_SHIFT (0x00000005u)
+#define OMAPL_MCASP_PFUNC_AXR5_RESETVAL (0x00000000u)
+/* AXR5 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR5_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR5_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR4_MASK (0x00000010u)
+#define OMAPL_MCASP_PFUNC_AXR4_SHIFT (0x00000004u)
+#define OMAPL_MCASP_PFUNC_AXR4_RESETVAL (0x00000000u)
+/* AXR4 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR4_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR4_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR3_MASK (0x00000008u)
+#define OMAPL_MCASP_PFUNC_AXR3_SHIFT (0x00000003u)
+#define OMAPL_MCASP_PFUNC_AXR3_RESETVAL (0x00000000u)
+/* AXR3 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR3_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR3_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR2_MASK (0x00000004u)
+#define OMAPL_MCASP_PFUNC_AXR2_SHIFT (0x00000002u)
+#define OMAPL_MCASP_PFUNC_AXR2_RESETVAL (0x00000000u)
+/* AXR2 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR2_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR2_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR1_MASK (0x00000002u)
+#define OMAPL_MCASP_PFUNC_AXR1_SHIFT (0x00000001u)
+#define OMAPL_MCASP_PFUNC_AXR1_RESETVAL (0x00000000u)
+/* AXR1 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR1_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR1_GPIO (0x00000001u)
+
+#define OMAPL_MCASP_PFUNC_AXR0_MASK (0x00000001u)
+#define OMAPL_MCASP_PFUNC_AXR0_SHIFT (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR0_RESETVAL (0x00000000u)
+/* AXR0 Tokens */
+#define OMAPL_MCASP_PFUNC_AXR0_MCASP (0x00000000u)
+#define OMAPL_MCASP_PFUNC_AXR0_GPIO (0x00000001u)
+#define OMAPL_MCASP_PFUNC_RESETVAL (0x00000000u)
+
+#define OMAPL_MCASP_PDIR_AFSR_MASK (0x80000000u)
+#define OMAPL_MCASP_PDIR_AFSR_SHIFT (0x0000001Fu)
+#define OMAPL_MCASP_PDIR_AFSR_RESETVAL (0x00000000u)
+/* AFSR Tokens */
+#define OMAPL_MCASP_PDIR_AFSR_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AFSR_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AHCLKR_MASK (0x40000000u)
+#define OMAPL_MCASP_PDIR_AHCLKR_SHIFT (0x0000001Eu)
+#define OMAPL_MCASP_PDIR_AHCLKR_RESETVAL (0x00000000u)
+/* AHCLKR Tokens */
+#define OMAPL_MCASP_PDIR_AHCLKR_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AHCLKR_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_ACLKR_MASK (0x20000000u)
+#define OMAPL_MCASP_PDIR_ACLKR_SHIFT (0x0000001Du)
+#define OMAPL_MCASP_PDIR_ACLKR_RESETVAL (0x00000000u)
+/* ACLKR Tokens */
+#define OMAPL_MCASP_PDIR_ACLKR_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_ACLKR_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AFSX_MASK (0x10000000u)
+#define OMAPL_MCASP_PDIR_AFSX_SHIFT (0x0000001Cu)
+#define OMAPL_MCASP_PDIR_AFSX_RESETVAL (0x00000000u)
+/* AFSX Tokens */
+#define OMAPL_MCASP_PDIR_AFSX_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AFSX_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AHCLKX_MASK (0x08000000u)
+#define OMAPL_MCASP_PDIR_AHCLKX_SHIFT (0x0000001Bu)
+#define OMAPL_MCASP_PDIR_AHCLKX_RESETVAL (0x00000000u)
+/* AHCLKX Tokens */
+#define OMAPL_MCASP_PDIR_AHCLKX_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AHCLKX_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_ACLKX_MASK (0x04000000u)
+#define OMAPL_MCASP_PDIR_ACLKX_SHIFT (0x0000001Au)
+#define OMAPL_MCASP_PDIR_ACLKX_RESETVAL (0x00000000u)
+/* ACLKX Tokens */
+#define OMAPL_MCASP_PDIR_ACLKX_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_ACLKX_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AMUTE_MASK (0x02000000u)
+#define OMAPL_MCASP_PDIR_AMUTE_SHIFT (0x00000019u)
+#define OMAPL_MCASP_PDIR_AMUTE_RESETVAL (0x00000000u)
+/* AMUTE Tokens */
+#define OMAPL_MCASP_PDIR_AMUTE_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AMUTE_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR15_MASK (0x00008000u)
+#define OMAPL_MCASP_PDIR_AXR15_SHIFT (0x0000000Fu)
+#define OMAPL_MCASP_PDIR_AXR15_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR15_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR15_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR14_MASK (0x00004000u)
+#define OMAPL_MCASP_PDIR_AXR14_SHIFT (0x0000000Eu)
+#define OMAPL_MCASP_PDIR_AXR14_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR14_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR14_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR13_MASK (0x00002000u)
+#define OMAPL_MCASP_PDIR_AXR13_SHIFT (0x0000000Du)
+#define OMAPL_MCASP_PDIR_AXR13_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR13_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR13_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR12_MASK (0x00001000u)
+#define OMAPL_MCASP_PDIR_AXR12_SHIFT (0x0000000Cu)
+#define OMAPL_MCASP_PDIR_AXR12_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR12_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR12_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR11_MASK (0x00000800u)
+#define OMAPL_MCASP_PDIR_AXR11_SHIFT (0x0000000Bu)
+#define OMAPL_MCASP_PDIR_AXR11_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR11_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR11_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR10_MASK (0x00000400u)
+#define OMAPL_MCASP_PDIR_AXR10_SHIFT (0x0000000Au)
+#define OMAPL_MCASP_PDIR_AXR10_RESETVAL (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR10_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR10_OUTPUT (0x00000001u)
+#define OMAPL_MCASP_PDIR_AXR9_MASK (0x00000200u)
+#define OMAPL_MCASP_PDIR_AXR9_SHIFT (0x00000009u)
+#define OMAPL_MCASP_PDIR_AXR9_RESETVAL (0x00000000u)
+/* AXR9 Tokens */
+#define OMAPL_MCASP_PDIR_AXR9_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR9_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR8_MASK (0x00000100u)
+#define OMAPL_MCASP_PDIR_AXR8_SHIFT (0x00000008u)
+#define OMAPL_MCASP_PDIR_AXR8_RESETVAL (0x00000000u)
+/* AXR8 Tokens */
+#define OMAPL_MCASP_PDIR_AXR8_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR8_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR7_MASK (0x00000080u)
+#define OMAPL_MCASP_PDIR_AXR7_SHIFT (0x00000007u)
+#define OMAPL_MCASP_PDIR_AXR7_RESETVAL (0x00000000u)
+/*----AXR7 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR7_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR7_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR6_MASK (0x00000040u)
+#define OMAPL_MCASP_PDIR_AXR6_SHIFT (0x00000006u)
+#define OMAPL_MCASP_PDIR_AXR6_RESETVAL (0x00000000u)
+/*----AXR6 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR6_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR6_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR5_MASK (0x00000020u)
+#define OMAPL_MCASP_PDIR_AXR5_SHIFT (0x00000005u)
+#define OMAPL_MCASP_PDIR_AXR5_RESETVAL (0x00000000u)
+/*----AXR5 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR5_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR5_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR4_MASK (0x00000010u)
+#define OMAPL_MCASP_PDIR_AXR4_SHIFT (0x00000004u)
+#define OMAPL_MCASP_PDIR_AXR4_RESETVAL (0x00000000u)
+/*----AXR4 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR4_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR4_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR3_MASK (0x00000008u)
+#define OMAPL_MCASP_PDIR_AXR3_SHIFT (0x00000003u)
+#define OMAPL_MCASP_PDIR_AXR3_RESETVAL (0x00000000u)
+/*----AXR3 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR3_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR3_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR2_MASK (0x00000004u)
+#define OMAPL_MCASP_PDIR_AXR2_SHIFT (0x00000002u)
+#define OMAPL_MCASP_PDIR_AXR2_RESETVAL (0x00000000u)
+/*----AXR2 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR2_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR2_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR1_MASK (0x00000002u)
+#define OMAPL_MCASP_PDIR_AXR1_SHIFT (0x00000001u)
+#define OMAPL_MCASP_PDIR_AXR1_RESETVAL (0x00000000u)
+/*----AXR1 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR1_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR1_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_AXR0_MASK (0x00000001u)
+#define OMAPL_MCASP_PDIR_AXR0_SHIFT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR0_RESETVAL (0x00000000u)
+/*----AXR0 Tokens----*/
+#define OMAPL_MCASP_PDIR_AXR0_INPUT (0x00000000u)
+#define OMAPL_MCASP_PDIR_AXR0_OUTPUT (0x00000001u)
+
+#define OMAPL_MCASP_PDIR_RESETVAL (0x00000000u)
+
+#define OMAPL_MCASP_ACLKXCTL_CLKXP_MASK (0x00000080u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXP_SHIFT (0x00000007u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXP_RESETVAL (0x00000000u)
+/*----CLKXP Tokens----*/
+#define OMAPL_MCASP_ACLKXCTL_CLKXP_RISINGEDGE (0x00000000u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXP_FALLINGEDGE (0x00000001u)
+
+#define OMAPL_MCASP_ACLKXCTL_ASYNC_MASK (0x00000040u)
+#define OMAPL_MCASP_ACLKXCTL_ASYNC_SHIFT (0x00000006u)
+#define OMAPL_MCASP_ACLKXCTL_ASYNC_RESETVAL (0x00000001u)
+/*----ASYNC Tokens----*/
+#define OMAPL_MCASP_ACLKXCTL_ASYNC_SYNC (0x00000000u)
+#define OMAPL_MCASP_ACLKXCTL_ASYNC_ASYNC (0x00000001u)
+
+#define OMAPL_MCASP_ACLKXCTL_CLKXM_MASK (0x00000020u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXM_SHIFT (0x00000005u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXM_RESETVAL (0x00000001u)
+/*----CLKXM Tokens----*/
+#define OMAPL_MCASP_ACLKXCTL_CLKXM_EXTERNAL (0x00000000u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXM_INTERNAL (0x00000001u)
+
+#define OMAPL_MCASP_ACLKXCTL_CLKXDIV_MASK (0x0000001Fu)
+#define OMAPL_MCASP_ACLKXCTL_CLKXDIV_SHIFT (0x00000000u)
+#define OMAPL_MCASP_ACLKXCTL_CLKXDIV_RESETVAL (0x00000000u)
+
+#define OMAPL_MCASP_ACLKXCTL_RESETVAL (0x00000060u)
+
+/* AHCLKXCTL */
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXM_MASK (0x00008000u)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXM_SHIFT (0x0000000Fu)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXM_RESETVAL (0x00000001u)
+/*----HCLKXM Tokens----*/
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXM_EXTERNAL (0x00000000u)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXM_INTERNAL (0x00000001u)
+
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXP_MASK (0x00004000u)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXP_SHIFT (0x0000000Eu)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXP_RESETVAL (0x00000000u)
+/*----HCLKXP Tokens----*/
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXP_NOTINVERTED (0x00000000u)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXP_INVERTED (0x00000001u)
+
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_MASK (0x00000FFFu)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_SHIFT (0x00000000u)
+#define OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_RESETVAL (0x00000000u)
+
+#define OMAPL_MCASP_AHCLKXCTL_RESETVAL (0x00008000u)
+
+#define MCASP_SUART_GBLCTL (0X00000000)
+#define MCASP_SUART_RGBLCTL (0X00000000)
+#define MCASP_SUART_XGBLCTL (0X00000000)
+#define MCASP_SUART_RMASK_8 (0x000000FF)
+#define MCASP_SUART_RMASK_16 (0x0000FFFF)
+#define MCASP_SUART_RFMT_8 (0x0000A038)
+#define MCASP_SUART_RFMT_16 (0x0000A078)
+#define MCASP_SUART_FSRM (0X00000002)
+#define MCASP_SUART_CLKRM_CLKRP (0X000000A0)
+#define MCASP_SUART_HCLKRP (0X00008000)
+#define MCASP_SUART_RTDMS0 (0X00000001)
+#define MCASP_SUART_RSYNCERR (0X00000002)
+#define MCASP_SUART_RMAX_RPS_256 (0x00FF0008)
+#define MCASP_SUART_XMASK_0_31 (0X0000FFFF)
+#define MCASP_SUART_XBUSEL_XSSZ_16_XPAD_0 (0x00002078)
+#define MCASP_SUART_FSXM (0x00000002)
+#define MCASP_SUART_CLKXM_ASYNC_CLKXP (0x000000E0)
+#define MCASP_SUART_HCLKXM (0x00008000)
+#define MCASP_SUART_XTDMS0 (0X00000001)
+#define MCASP_SUART_XSYNCERR (0x00000002)
+#define MCASP_SUART_XMAX_XPS_256 (0x00FF0008)
+#define MCASP_SUART_SRCTL_DISMOD (0x0000000c)
+#define MCASP_SUART_DIT_DISABLE (0X00000000)
+#define MCASP_SUART_LOOPBACK_DISABLE (0x00000000)
+#define MCASP_SUART_AMUTE_DISABLE (0X00000000)
+#define MCASP_SUART_XSTAT (0x0000FFFF)
+#define MCASP_SUART_RSTAT (0x0000FFFF)
+
+/* SUART REGS */
+
+/* PRU0 DATA RAM base address */
+#define PRU0_DATARAM_OFFSET (0x0000u)
+/* PRU1 DATA RAM base address */
+#define PRU1_DATARAM_OFFSET (0x2000u)
+
+/* PRU0 DATA RAM size */
+#define PRU0_DATARAM_SIZE (0x200u)
+/* PRU1 DATA RAM size */
+#define PRU1_DATARAM_SIZE (0x200u)
+
+#define PRU_SUART_PRU0_CH0_OFFSET (0x0000)
+#define PRU_SUART_PRU0_CH1_OFFSET (0x0010)
+#define PRU_SUART_PRU0_CH2_OFFSET (0x0020)
+#define PRU_SUART_PRU0_CH3_OFFSET (0x0030)
+#define PRU_SUART_PRU0_CH4_OFFSET (0x0040)
+#define PRU_SUART_PRU0_CH5_OFFSET (0x0050)
+#define PRU_SUART_PRU0_CH6_OFFSET (0x0060)
+#define PRU_SUART_PRU0_CH7_OFFSET (0x0070)
+#define PRU_SUART_PRU0_IMR_OFFSET (0x0080)
+/* Interrupt Mask Register */
+#define PRU_SUART_PRU0_ISR_OFFSET (0x0082)
+/* Interrupt Status Register */
+#define PRU_SUART_PRU0_ID_ADDR (0x0084)
+/* PRU ID Register */
+#define PRU_SUART_PRU0_RX_TX_MODE (0x0085)
+#define PRU_SUART_PRU0_DELAY_OFFSET (0x0086)
+#define PRU_SUART_PRU0_IDLE_TIMEOUT_OFFSET (0x0088)
+
+/* PRU 1 Macros */
+#define PRU_SUART_PRU1_CH0_OFFSET (0x2000)
+#define PRU_SUART_PRU1_CH1_OFFSET (0x2010)
+#define PRU_SUART_PRU1_CH2_OFFSET (0x2020)
+#define PRU_SUART_PRU1_CH3_OFFSET (0x2030)
+#define PRU_SUART_PRU1_CH4_OFFSET (0x2040)
+#define PRU_SUART_PRU1_CH5_OFFSET (0x2050)
+#define PRU_SUART_PRU1_CH6_OFFSET (0x2060)
+#define PRU_SUART_PRU1_CH7_OFFSET (0x2070)
+#define PRU_SUART_PRU1_IMR_OFFSET (0x2080)
+#define PRU_SUART_PRU1_ISR_OFFSET (0x2082)
+#define PRU_SUART_PRU1_ID_ADDR (0x2084)
+#define PRU_SUART_PRU1_RX_TX_MODE (0x2085)
+#define PRU_SUART_PRU1_DELAY_OFFSET (0x2086)
+#define PRU_SUART_PRU1_IDLE_TIMEOUT_OFFSET (0x2088)
+
+/* SUART Channel Control Register bit descriptions */
+#define PRU_SUART_CH_CTRL_MODE_SHIFT 0x0000
+#define PRU_SUART_CH_CTRL_MODE_MASK 0x0003
+#define PRU_SUART_CH_CTRL_TX_MODE 0x0001
+#define PRU_SUART_CH_CTRL_RX_MODE 0x0002
+
+/* Service Request */
+#define PRU_SUART_CH_CTRL_SREQ_SHIFT 0x0002
+#define PRU_SUART_CH_CTRL_SREQ_MASK 0x0004
+#define PRU_SUART_CH_CTRL_SREQ 0x0001
+
+/* McASP Instance */
+#define PRU_SUART_CH_CTRL_MCASP_SHIFT 0x0003
+#define PRU_SUART_CH_CTRL_MCASP_MASK 0x0018
+#define PRU_SUART_CH_CTRL_SR_SHIFT 0x0008
+#define PRU_SUART_CH_CTRL_SR_MASK 0x0F00
+
+/* SUART channel configuration1 register descriptions */
+
+/* clock divisor - relative baud value */
+#define PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT 0x0000
+#define PRU_SUART_CH_CONFIG1_DIVISOR_MASK 0x03FF
+/* oversampling */
+#define PRU_SUART_CH_CONFIG1_OVS_SHIFT 0x000A
+#define PRU_SUART_CH_CONFIG1_OVS_MASK 0x0C00
+
+/* SUART channel configuration2 register descriptions */
+/* Bits per character */
+#define PRU_SUART_CH_CONFIG2_BITPERCHAR_SHIFT 0x0000
+#define PRU_SUART_CH_CONFIG2_BITPERCHAR_MASK 0x000F
+
+/* Bits per character */
+#define PRU_SUART_CH_CONFIG2_DATALEN_SHIFT 0x0008
+#define PRU_SUART_CH_CONFIG2_DATALEN_MASK 0x0F00
+
+/* SUART Channel STATUS Register*/
+#define PRU_SUART_CH_STATUS_EN_BIT_MASK 0x8000
+
+/* SUART Channel register offsets */
+#define PRU_SUART_CH_CTRL_OFFSET 0x00
+#define PRU_SUART_CH_CONFIG1_OFFSET 0x02
+#define PRU_SUART_CH_CONFIG2_OFFSET 0x04
+#define PRU_SUART_CH_TXRXSTATUS_OFFSET 0x06
+#define PRU_SUART_CH_TXRXDATA_OFFSET 0x08
+#define PRU_SUART_CH_BYTESDONECNTR_OFFSET 0x0C
+
+/* SUART Event Numbers macros */
+#define PRU_SUART0_TX_EVT 34
+#define PRU_SUART0_RX_EVT 35
+#define PRU_SUART1_TX_EVT 36
+#define PRU_SUART1_RX_EVT 37
+#define PRU_SUART2_TX_EVT 38
+#define PRU_SUART2_RX_EVT 39
+#define PRU_SUART3_TX_EVT 40
+#define PRU_SUART3_RX_EVT 41
+#define PRU_SUART4_TX_EVT 42
+#define PRU_SUART4_RX_EVT 43
+#define PRU_SUART5_TX_EVT 44
+#define PRU_SUART5_RX_EVT 45
+#define PRU_SUART6_TX_EVT 46
+#define PRU_SUART6_RX_EVT 47
+#define PRU_SUART7_TX_EVT 48
+#define PRU_SUART7_RX_EVT 49
+
+#define PRU_SUART0_TX_EVT_BIT BIT(2)
+#define PRU_SUART0_RX_EVT_BIT BIT(3)
+#define PRU_SUART1_TX_EVT_BIT BIT(4)
+#define PRU_SUART1_RX_EVT_BIT BIT(5)
+#define PRU_SUART2_TX_EVT_BIT BIT(6)
+#define PRU_SUART2_RX_EVT_BIT BIT(7)
+#define PRU_SUART3_TX_EVT_BIT BIT(8)
+#define PRU_SUART3_RX_EVT_BIT BIT(9)
+#define PRU_SUART4_TX_EVT_BIT BIT(10)
+#define PRU_SUART4_RX_EVT_BIT BIT(11)
+#define PRU_SUART5_TX_EVT_BIT BIT(12)
+#define PRU_SUART5_RX_EVT_BIT BIT(13)
+#define PRU_SUART6_TX_EVT_BIT BIT(14)
+#define PRU_SUART6_RX_EVT_BIT BIT(15)
+#define PRU_SUART7_TX_EVT_BIT BIT(16)
+#define PRU_SUART7_RX_EVT_BIT BIT(17)
+
+/* Total number of baud rates supported */
+#define SUART_NUM_OF_BAUDS_SUPPORTED 13
+
+#define MCASP_PDIR_VAL ( \
+ OMAPL_MCASP_PDIR_AFSR_OUTPUT<<OMAPL_MCASP_PDIR_AFSR_SHIFT | \
+ OMAPL_MCASP_PDIR_AHCLKR_OUTPUT<<OMAPL_MCASP_PDIR_AHCLKR_SHIFT | \
+ OMAPL_MCASP_PDIR_ACLKR_OUTPUT<<OMAPL_MCASP_PDIR_ACLKR_SHIFT | \
+ OMAPL_MCASP_PDIR_AFSX_OUTPUT<<OMAPL_MCASP_PDIR_AFSX_SHIFT | \
+ OMAPL_MCASP_PDIR_AHCLKX_OUTPUT<<OMAPL_MCASP_PDIR_AHCLKX_SHIFT | \
+ OMAPL_MCASP_PDIR_ACLKX_OUTPUT<<OMAPL_MCASP_PDIR_ACLKX_SHIFT)
+
+/*
+ * This enum is used to specify the direction of the channel in UART
+ */
+enum SUART_CHN_DIR {
+ SUART_CHN_TX = 1,
+ SUART_CHN_RX = 2
+};
+
+/*
+ * This enum is used to specify the state of the channel in UART. It
+ * is either enabled or disabled.
+ */
+enum SUART_CHN_STATE {
+ SUART_CHN_DISABLED = 0,
+ SUART_CHN_ENABLED = 1
+};
+
+enum SUART_EN_BITSPERCHAR {
+ ePRU_SUART_DATA_BITS6 = 8,
+ ePRU_SUART_DATA_BITS7,
+ ePRU_SUART_DATA_BITS8,
+ ePRU_SUART_DATA_BITS9,
+ ePRU_SUART_DATA_BITS10,
+ ePRU_SUART_DATA_BITS11,
+ ePRU_SUART_DATA_BITS12
+};
+
+enum SUART_EN_UARTNUM {
+ ePRU_SUART_NUM_1 = 1,
+ ePRU_SUART_NUM_2,
+ ePRU_SUART_NUM_3,
+ ePRU_SUART_NUM_4,
+ ePRU_SUART_NUM_5,
+ ePRU_SUART_NUM_6,
+ ePRU_SUART_NUM_7,
+ ePRU_SUART_NUM_8
+};
+
+enum SUART_EN_UARTTYPE {
+ ePRU_SUART_HALF_TX = 1,
+ ePRU_SUART_HALF_RX,
+ ePRU_SUART_FULL_TX_RX,
+ ePRU_SUART_HALF_TX_DISABLED = 4,
+ ePRU_SUART_HALF_RX_DISABLED = 8
+};
+
+enum SUART_EN_TXCHANNEL {
+ ePRU_SUART_TX_CH0 = 0,
+ ePRU_SUART_TX_CH1,
+ ePRU_SUART_TX_CH2,
+ ePRU_SUART_TX_CH3,
+ ePRU_SUART_TX_CH4,
+ ePRU_SUART_TX_CH5,
+ ePRU_SUART_TX_CH6,
+ ePRU_SUART_TX_CH7
+};
+
+enum SUART_EN_RXCHANNEL {
+ ePRU_SUART_RX_CH0 = 0,
+ ePRU_SUART_RX_CH1,
+ ePRU_SUART_RX_CH2,
+ ePRU_SUART_RX_CH3,
+ ePRU_SUART_RX_CH4,
+ ePRU_SUART_RX_CH5,
+ ePRU_SUART_RX_CH6,
+ ePRU_SUART_RX_CH7
+};
+
+enum SUART_EN_UART_STATUS {
+ ePRU_SUART_UART_FREE = 0,
+ ePRU_SUART_UART_IN_USE
+};
+
+struct pru_suart_cnh_cntrl_config1 {
+ u32 mode:2;
+ u32 service_req:1;
+ u32 asp_id:2;
+ u32 reserved1:3;
+ u32 serializer_num:4;
+ u32 reserved2:4;
+ u32 presacler:10;
+ u32 over_sampling:2;
+ u32 framing_mask:1;
+ u32 break_mask:1;
+ u32 timeout_mask:1;
+ u32 reserved3:1;
+};
+
+struct pru_suart_chn_config2_status {
+ u32 bits_per_char:4;
+ u32 reserved1:4;
+ u32 data_len:4;
+ u32 reserved2:4;
+ u32 txrx_ready:1;
+ u32 txrx_complete:1;
+ u32 txrx_error:1;
+ u32 txrx_underrun:1;
+ u32 framing_error:1;
+ u32 break_error:1;
+ u32 timeout_error:1;
+ u32 reserved3:8;
+ u32 chn_state:1;
+};
+
+struct pru_suart_regs_ovly {
+ struct pru_suart_cnh_cntrl_config1 ch_ctrl_config1;
+ struct pru_suart_chn_config2_status ch_config2_txrx_status;
+ u32 ch_txrx_data;
+ u32 reserved1;
+};
+
+struct pru_suart_tx_cntx_priv {
+ u32 asp_xsrctl_base;
+ u32 asp_xbuf_base;
+ u16 buff_addr;
+ u8 buff_size;
+ u8 bits_loaded;
+};
+
+struct pru_suart_rx_cntx_priv {
+ u32 asp_rbuf_base;
+ u32 asp_rsrctl_base;
+ u32 reserved1;
+ u32 reserved2;
+ u32 reserved3;
+ u32 reserved4;
+};
+
+struct suart_config {
+ u8 tx_serializer;
+ u8 rx_serializer;
+ u16 tx_clk_divisor;
+ u16 rx_clk_divisor;
+ u8 tx_bits_per_char;
+ u8 rx_bits_per_char;
+ u8 oversampling;
+ u8 bi_inter_mask;
+ u8 fe_intr_mask;
+};
+
+struct suart_handle {
+ u16 uart_num;
+ u16 uart_type;
+ u16 uart_tx_channel;
+ u16 uart_rx_channel;
+ u16 uart_status;
+};
+
+struct pruss_suart_iomap {
+ void *mcasp_io_addr;
+ void *p_fifo_buff_phys_base;
+ void *p_fifo_buff_virt_base;
+ u32 pru_clk_freq;
+};
+
+/* MCASP */
+struct omapl_mcasp_regs_ovly {
+ u32 REVID;
+ u32 RSVD0[3];
+ u32 PFUNC;
+ u32 PDIR;
+ u32 PDOUT;
+ u32 PDIN;
+ u32 PDCLR;
+ u32 RSVD1[8];
+ u32 GBLCTL;
+ u32 AMUTE;
+ u32 DLBCTL;
+ u32 DITCTL;
+ u32 RSVD2[3];
+ u32 RGBLCTL;
+ u32 RMASK;
+ u32 RFMT;
+ u32 AFSRCTL;
+ u32 ACLKRCTL;
+ u32 AHCLKRCTL;
+ u32 RTDM;
+ u32 RINTCTL;
+ u32 RSTAT;
+ u32 RSLOT;
+ u32 RCLKCHK;
+ u32 REVTCTL;
+ u32 RSVD3[4];
+ u32 XGBLCTL;
+ u32 XMASK;
+ u32 XFMT;
+ u32 AFSXCTL;
+ u32 ACLKXCTL;
+ u32 AHCLKXCTL;
+ u32 XTDM;
+ u32 XINTCTL;
+ u32 XSTAT;
+ u32 XSLOT;
+ u32 XCLKCHK;
+ u32 XEVTCTL;
+ u32 RSVD4[12];
+ u32 DITCSRA0;
+ u32 DITCSRA1;
+ u32 DITCSRA2;
+ u32 DITCSRA3;
+ u32 DITCSRA4;
+ u32 DITCSRA5;
+ u32 DITCSRB0;
+ u32 DITCSRB1;
+ u32 DITCSRB2;
+ u32 DITCSRB3;
+ u32 DITCSRB4;
+ u32 DITCSRB5;
+ u32 DITUDRA0;
+ u32 DITUDRA1;
+ u32 DITUDRA2;
+ u32 DITUDRA3;
+ u32 DITUDRA4;
+ u32 DITUDRA5;
+ u32 DITUDRB0;
+ u32 DITUDRB1;
+ u32 DITUDRB2;
+ u32 DITUDRB3;
+ u32 DITUDRB4;
+ u32 DITUDRB5;
+ u32 RSVD5[8];
+ u32 SRCTL0;
+ u32 SRCTL1;
+ u32 SRCTL2;
+ u32 SRCTL3;
+ u32 SRCTL4;
+ u32 SRCTL5;
+ u32 SRCTL6;
+ u32 SRCTL7;
+ u32 SRCTL8;
+ u32 SRCTL9;
+ u32 SRCTL10;
+ u32 SRCTL11;
+ u32 SRCTL12;
+ u32 SRCTL13;
+ u32 SRCTL14;
+ u32 SRCTL15;
+ u32 RSVD6[16];
+ u32 XBUF0;
+ u32 XBUF1;
+ u32 XBUF2;
+ u32 XBUF3;
+ u32 XBUF4;
+ u32 XBUF5;
+ u32 XBUF6;
+ u32 XBUF7;
+ u32 XBUF8;
+ u32 XBUF9;
+ u32 XBUF10;
+ u32 XBUF11;
+ u32 XBUF12;
+ u32 XBUF13;
+ u32 XBUF14;
+ u32 XBUF15;
+ u32 RSVD7[16];
+ u32 RBUF0;
+ u32 RBUF1;
+ u32 RBUF2;
+ u32 RBUF3;
+ u32 RBUF4;
+ u32 RBUF5;
+ u32 RBUF6;
+ u32 RBUF7;
+ u32 RBUF8;
+ u32 RBUF9;
+ u32 RBUF10;
+ u32 RBUF11;
+ u32 RBUF12;
+ u32 RBUF13;
+ u32 RBUF14;
+ u32 RBUF15;
+};
+
+/*
+ * SUART Config regs
+ */
+struct suart_struct_pru_regs {
+ u16 chn_ctrl;
+ u16 chn_config1;
+ u16 chn_config2;
+ u16 chn_txrx_status;
+ u32 chn_txrx_data;
+};
+
+extern s16 pru_softuart_init(struct device *dev, u32 tx_baud_value,
+ u32 rx_baud_value, u32 oversampling,
+ u8 *pru_suart_emu_code, u32 fw_size,
+ struct pruss_suart_iomap *pruss_ioaddr);
+
+extern s16 pru_softuart_open(struct suart_handle *h_suart);
+
+extern s16 pru_softuart_close(struct suart_handle *h_uart);
+
+extern s16 pru_softuart_setbaud(struct device *dev,
+ struct suart_handle *h_uart,
+ u16 tx_clk_divisor, u16 rx_clk_divisor);
+
+extern s16 pru_softuart_setdatabits(struct device *dev,
+ struct suart_handle *h_uart,
+ u16 tx_data_bits, u16 rx_data_bits);
+
+extern s16 pru_softuart_setconfig(struct device *dev,
+ struct suart_handle *h_uart,
+ struct suart_config *config_uart);
+
+extern s16 pru_softuart_getconfig(struct device *dev,
+ struct suart_handle *h_uart,
+ struct suart_config *config_uart);
+
+extern s32 pru_softuart_pending_tx_request(struct device *dev);
+
+extern s16 pru_softuart_write(struct device *dev,
+ struct suart_handle *h_uart,
+ u32 *pt_tx_data_buf, u16 data_len);
+
+extern s16 pru_softuart_read(struct device *dev,
+ struct suart_handle *h_uart,
+ u32 *pt_data_buf, u16 data_len);
+
+extern s32 suart_intr_clrmask(struct device *dev, u16 uart_num,
+ u32 txrxmode,
+ u32 intrmask);
+
+extern s16 pru_softuart_clr_tx_status(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 pru_softuart_get_tx_status(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 pru_softuart_clr_rx_status(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 pru_softuart_get_rx_status(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 pru_softuart_get_isrstatus(struct device *dev, u16 uart_num,
+ u16 *txrx_flag);
+
+extern s32 pru_intr_clr_isrstatus(struct device *dev, u16 uart_num,
+ u32 txrxmode);
+
+extern s32 suart_intr_getmask(struct device *dev, u16 uart_num,
+ u32 txrxmode,
+ u32 intrmask);
+
+extern s32 suart_intr_setmask(struct device *dev, u16 uart_num,
+ u32 txrxmode, u32 intrmask);
+
+extern s16 pru_softuart_get_tx_data_len(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 pru_softuart_get_rx_data_len(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s16 suart_arm_to_pru_intr(struct device *dev, u16 uart_num);
+
+extern void pru_mcasp_deinit(void);
+
+extern s16 pru_softuart_read_data(struct device *dev,
+ struct suart_handle *h_uart,
+ u8 *p_data_buffer, s32 max_len,
+ u32 *pdata_read);
+
+extern s16 pru_softuart_stop_receive(struct device *dev,
+ struct suart_handle *h_uart);
+
+extern s32 suart_pru_to_host_intr_enable(struct device *dev,
+ u16 uart_num,
+ u32 txrxmode, s32 flag);
+
+extern void pru_set_fifo_timeout(struct device *dev, s16 timeout);
+
+extern void suart_mcasp_config(u32 tx_baud_value,
+ u32 rx_baud_value, u32 oversampling,
+ struct pruss_suart_iomap *pruss_ioaddr);
+
+extern void suart_mcasp_reset(struct pruss_suart_iomap *pruss_ioaddr);
+
+extern short suart_asp_baud_set(u32 tx_baud_value,
+ u32 rx_baud_value, u32 oversampling,
+ struct pruss_suart_iomap *pruss_ioaddr);
+
+extern short suart_asp_serializer_deactivate(u16 sr_num,
+ struct pruss_suart_iomap *pruss_ioaddr);
+
+extern void suart_mcasp_tx_serialzier_set(u32 serializer_num,
+ struct pruss_suart_iomap *pruss_ioaddr);
+#endif
new file mode 100644
@@ -0,0 +1,1757 @@
+/*
+ * Copyright (C) 2010 Texas Instruments Incorporated
+ * Author: Jitendra Kumar <jitendra@mistralsolutions.com>
+ *
+ * This program is free software; you can redistribute it and/or modify it
+ * under the terms of the GNU General Public License as published by the
+ * Free Software Foundation version 2.
+ *
+ * This program is distributed "as is" WITHOUT ANY WARRANTY of any kind,
+ * whether express or implied; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * General Public License for more details.
+ */
+
+#include <linux/types.h>
+#include <linux/mfd/da8xx/da8xx_pru.h>
+#include <linux/io.h>
+#include <mach/hardware.h>
+#include "pruss_suart.h"
+
+static u8 uart_statu_table[8];
+static struct pruss_suart_iomap suart_iomap;
+
+static u32 uart_rx[8] = {PRU_SUART0_CONFIG_RX_SER, PRU_SUART1_CONFIG_RX_SER,
+ PRU_SUART2_CONFIG_RX_SER, PRU_SUART3_CONFIG_RX_SER,
+ PRU_SUART4_CONFIG_RX_SER, PRU_SUART5_CONFIG_RX_SER,
+ PRU_SUART6_CONFIG_RX_SER, PRU_SUART7_CONFIG_RX_SER};
+
+static u32 uart_tx[8] = {PRU_SUART0_CONFIG_TX_SER, PRU_SUART1_CONFIG_TX_SER,
+ PRU_SUART2_CONFIG_TX_SER, PRU_SUART3_CONFIG_TX_SER,
+ PRU_SUART4_CONFIG_TX_SER, PRU_SUART5_CONFIG_TX_SER,
+ PRU_SUART6_CONFIG_TX_SER, PRU_SUART7_CONFIG_TX_SER};
+
+static u32 uart_config[8] = {PRU_SUART0_CONFIG_DUPLEX, PRU_SUART1_CONFIG_DUPLEX,
+ PRU_SUART2_CONFIG_DUPLEX, PRU_SUART3_CONFIG_DUPLEX,
+ PRU_SUART4_CONFIG_DUPLEX, PRU_SUART5_CONFIG_DUPLEX,
+ PRU_SUART6_CONFIG_DUPLEX, PRU_SUART7_CONFIG_DUPLEX};
+
+static s16 pru_softuart_clr_rx_fifo(struct device *dev,
+ struct suart_handle *h_uart);
+static s16 arm_to_pru_intr_init(struct device *dev);
+
+#if (PRU_ACTIVE == BOTH_PRU)
+static void pru_set_ram_data(struct device *dev,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ u32 datatowrite;
+ u32 i;
+ struct pru_suart_regs_ovly *pru_suart_regs = PRU0_DATARAM_OFFSET;
+ u32 *p_sr_ctl_addr = (u32 *)(pruss_ioaddr->mcasp_io_addr + 0x180);
+ struct pru_suart_tx_cntx_priv *pru_suart_tx_priv = NULL;
+ struct pru_suart_rx_cntx_priv *pru_suart_rx_priv = NULL;
+
+ /* RX PRU - 0 Chanel 0-7 context information */
+ for (i = 0; i < 8; i++, pru_suart_regs++) {
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ 0x3, SUART_CHN_RX);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0xF << SERIALIZER_OFFSET),
+ ((0xF & uart_rx[i]) << SERIALIZER_OFFSET));
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0x3 << SUART_DEFAULT_OVRSMPL_OFFSET),
+ (SUART_DEFAULT_OVRSMPL <<
+ SUART_DEFAULT_OVRSMPL_OFFSET));
+ pruss_rmwl(dev,
+ (u32) &pru_suart_regs->ch_config2_txrx_status,
+ 0xF, 8);
+ if ((uart_config[i] & PRU_SUART_HALF_RX_DISABLED) ==
+ PRU_SUART_HALF_RX_DISABLED) {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_DISABLED << SUART_CHN_OFFSET));
+ } else {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_ENABLED << SUART_CHN_OFFSET));
+ __raw_writel(MCASP_SRCTL_RX_MODE, p_sr_ctl_addr +
+ uart_rx[i]);
+ }
+ /*
+ * RX is active by default, write the dummy received data at
+ * PRU RAM addr 0x1FC to avoid memory corruption.
+ */
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_txrx_data,
+ 0xFFFF, RX_DEFAULT_DATA_DUMP_ADDR);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->reserved1,
+ 0xFFFF, 0);
+ /* SUART1 RX context base addr */
+ pru_suart_rx_priv = (struct pru_suart_rx_cntx_priv *)
+ (PRU0_DATARAM_OFFSET + (0x090 + (i * 0x020)));
+ datatowrite = (MCASP_RBUF_BASE_ADDR + (uart_rx[i] << 2));
+ pruss_writel(dev, (u32) &pru_suart_rx_priv->asp_rbuf_base,
+ &datatowrite, 1);
+ datatowrite = (MCASP_SRCTL_BASE_ADDR + (uart_rx[i] << 2));
+ pruss_writel(dev, (u32) &pru_suart_rx_priv->asp_rsrctl_base,
+ &datatowrite, 1);
+ }
+
+ /* ****************** PRU1 RAM BASE ADDR ************************ */
+ pru_suart_regs = (struct pru_suart_regs_ovly *) PRU1_DATARAM_OFFSET;
+
+ /* ******************* TX PRU - 1 *********************** */
+ /* Channel 0-7 context information */
+ for (i = 0; i < 8; i++, pru_suart_regs++) {
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ 0x3, SUART_CHN_TX);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0xF << SERIALIZER_OFFSET),
+ ((0xF & uart_tx[i]) << SERIALIZER_OFFSET));
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0x3 << SUART_DEFAULT_OVRSMPL_OFFSET),
+ (SUART_DEFAULT_OVRSMPL <<
+ SUART_DEFAULT_OVRSMPL_OFFSET));
+ pruss_rmwl(dev,
+ (u32) &pru_suart_regs->ch_config2_txrx_status,
+ 0xF, 8);
+ if ((uart_config[i] & PRU_SUART_HALF_TX_DISABLED) ==
+ PRU_SUART_HALF_TX_DISABLED) {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_DISABLED << SUART_CHN_OFFSET));
+ } else {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_ENABLED << SUART_CHN_OFFSET));
+ __raw_writel(MCASP_SRCTL_TX_MODE,
+ p_sr_ctl_addr + uart_tx[i]);
+ }
+ pruss_rmwl(dev, (u32) &pru_suart_regs->reserved1,
+ 0xFFFF, 1);
+ /* SUART1 TX context base addr */
+ pru_suart_tx_priv = (struct pru_suart_tx_cntx_priv *)
+ (PRU1_DATARAM_OFFSET + (0x0B0 + (i * 0x02C)));
+ datatowrite = (MCASP_SRCTL_BASE_ADDR + (uart_tx[i] << 2));
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->asp_xsrctl_base,
+ &datatowrite, 1);
+ datatowrite = (MCASP_XBUF_BASE_ADDR + (uart_tx[i] << 2));
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->asp_xbuf_base,
+ &datatowrite, 1);
+ /* SUART1 TX formatted data base addr */
+ datatowrite = (0x0090 + (i * 0x002C));
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->buff_addr,
+ &datatowrite, 1);
+ }
+}
+#else
+static void pru_set_ram_data(struct device *dev,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+
+ struct pru_suart_regs_ovly *pru_suart_regs =
+ (struct pru_suart_regs_ovly *)pruss_ioaddr->pru_io_addr;
+ u32 i;
+ u32 *p_sr_ctl_addr = (u32 *)(pruss_ioaddr->mcasp_io_addr + 0x180);
+ struct pru_suart_tx_cntx_priv *pru_suart_tx_priv = NULL;
+ struct pru_suart_rx_cntx_priv *pru_suart_rx_priv = NULL;
+
+ /* ***************** UART 0 ************************ */
+ /* Channel 0 context information is Tx */
+ for (i = 0; i < 4; i++, pru_suart_regs++) {
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ 0x3, SUART_CHN_TX);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0xF << SERIALIZER_OFFSET),
+ ((0xF & uart_tx[i]) << SERIALIZER_OFFSET));
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0x3 << SUART_DEFAULT_OVRSMPL_OFFSET),
+ (SUART_DEFAULT_OVRSMPL <<
+ SUART_DEFAULT_OVRSMPL_OFFSET));
+ pruss_rmwl(dev,
+ (u32) &pru_suart_regs->ch_config2_txrx_status,
+ 0xF, 8);
+ if ((uart_config[i] & PRU_SUART_HALF_TX_DISABLED) ==
+ PRU_SUART_HALF_TX_DISABLED){
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_DISABLED << SUART_CHN_OFFSET));
+ } else {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_ENABLED << SUART_CHN_OFFSET));
+ __raw_writel(MCASP_SRCTL_TX_MODE,
+ p_sr_ctl_addr + uart_tx[i]);
+ }
+ pruss_rmwl(dev, (u32) &pru_suart_regs->reserved1,
+ 0xFFFF, 1);
+ /* SUART1 TX context base addr */
+ pru_suart_tx_priv = (struct pru_suart_tx_cntx_priv *)
+ (PRU0_DATARAM_OFFSET + (0x0B0 + (i * 0x50)));
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->asp_xsrctl_base,
+ (MCASP_SRCTL_BASE_ADDR + (uart_tx[i] << 2)), 1);
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->asp_xbuf_base,
+ (MCASP_XBUF_BASE_ADDR + (uart_tx[i] << 2)), 1);
+ /* SUART1 TX formatted data base addr */
+ pruss_writel(dev, (u32) &pru_suart_tx_priv->buff_addr,
+ (0x0090 + (i * 0x050)), 1);
+
+ /* Channel 1 is Rx context information */
+ pru_suart_regs++;
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ 0x3, SUART_CHN_RX);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0xF << SERIALIZER_OFFSET),
+ ((0xF & uart_rx[i]) << SERIALIZER_OFFSET));
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_ctrl_config1,
+ (0x3 << SUART_DEFAULT_OVRSMPL_OFFSET),
+ (SUART_DEFAULT_OVRSMPL <<
+ SUART_DEFAULT_OVRSMPL_OFFSET));
+ pruss_rmwl(dev,
+ (u32) &pru_suart_regs->ch_config2_txrx_status,
+ 0xF, 8);
+
+ if ((uart_config[i] & PRU_SUART_HALF_RX_DISABLED) ==
+ PRU_SUART_HALF_RX_DISABLED) {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_DISABLED << SUART_CHN_OFFSET));
+ } else {
+ pruss_rmwl(dev, (u32)
+ &pru_suart_regs->ch_config2_txrx_status,
+ (0x1 << SUART_CHN_OFFSET),
+ (SUART_CHN_ENABLED << SUART_CHN_OFFSET));
+ __raw_writel(MCASP_SRCTL_RX_MODE,
+ p_sr_ctl_addr + uart_rx[i]);
+ }
+ /* RX is active by default, write the dummy received data
+ * at PRU RAM addr 0x1FC to avoid memory corruption
+ */
+ pruss_rmwl(dev, (u32) &pru_suart_regs->ch_txrx_data,
+ 0xFFFF, RX_DEFAULT_DATA_DUMP_ADDR);
+ pruss_rmwl(dev, (u32) &pru_suart_regs->reserved1,
+ 0xFFFF, 0);
+ /* SUART1 RX context base addr */
+ pru_suart_rx_priv = (struct pru_suart_rx_cntx_priv *)
+ (PRU0_DATARAM_OFFSET + (0x0C0 + (i * 0x50)));
+ pruss_writel(dev, (u32) &pru_suart_rx_priv->asp_rbuf_base,
+ (MCASP_RBUF_BASE_ADDR + (uart_rx[i] << 2)), 1);
+ pruss_writel(dev, (u32) &pru_suart_rx_priv->asp_rsrctl_base,
+ (MCASP_SRCTL_BASE_ADDR + (uart_rx[i] << 2)), 1);
+ }
+}
+#endif
+
+static void pru_set_rx_tx_mode(struct device *dev, u32 pru_mode, u32 pru_num)
+{
+
+ u32 pru_offset;
+
+ if (pru_num == PRUSS_NUM0)
+ pru_offset = PRU_SUART_PRU0_RX_TX_MODE;
+ else if (pru_num == PRUSS_NUM1)
+ pru_offset = PRU_SUART_PRU1_RX_TX_MODE;
+ else
+ return;
+ pruss_writeb(dev, pru_offset, (u8 *) &pru_mode, 1);
+}
+
+static void pru_set_delay_count(struct device *dev, u32 pru_freq)
+{
+ u32 delay_cnt;
+
+ if (pru_freq == PRU_CLK_228)
+ delay_cnt = 5;
+ else if (pru_freq == PRU_CLK_186)
+ delay_cnt = 5;
+ else
+ delay_cnt = 3;
+
+ /* PRU 0 */
+ pruss_writeb(dev, PRU_SUART_PRU0_DELAY_OFFSET,
+ (u8 *) &delay_cnt, 1);
+
+ /* PRU 1 */
+ pruss_writeb(dev, PRU_SUART_PRU1_DELAY_OFFSET,
+ (u8 *) &delay_cnt, 1);
+}
+
+static s32 suart_set_pru_id(struct device *dev, u32 pru_no)
+{
+ u32 offset;
+ u8 reg_val = 0;
+
+ if (PRUSS_NUM0 == pru_no)
+ offset = PRU_SUART_PRU0_ID_ADDR;
+ else if (PRUSS_NUM1 == pru_no)
+ offset = PRU_SUART_PRU1_ID_ADDR;
+ else
+ return -EINVAL;
+
+ reg_val = pru_no;
+ pruss_writeb(dev, offset, (u8 *) ®_val, 1);
+
+ return 0;
+}
+
+/*
+ * suart Initialization routine
+ */
+s16 pru_softuart_init(struct device *dev, u32 tx_baud_value,
+ u32 rx_baud_value, u32 oversampling,
+ u8 *pru_suart_emu_code, u32 fw_size,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ u32 datatowrite[128] = {0};
+ s16 status = 0;
+ s16 idx;
+ s16 retval;
+
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) &&
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH))
+ return -EINVAL;
+
+ suart_iomap.mcasp_io_addr = pruss_ioaddr->mcasp_io_addr;
+ suart_iomap.p_fifo_buff_phys_base =
+ pruss_ioaddr->p_fifo_buff_phys_base;
+ suart_iomap.p_fifo_buff_virt_base =
+ pruss_ioaddr->p_fifo_buff_virt_base;
+ suart_iomap.pru_clk_freq = pruss_ioaddr->pru_clk_freq;
+ /* Configure McASP0 */
+ suart_mcasp_config(tx_baud_value,
+ rx_baud_value, oversampling, pruss_ioaddr);
+ pruss_enable(dev, PRUSS_NUM0);
+
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pruss_enable(dev, PRUSS_NUM1);
+
+ /* Reset PRU RAM */
+ pruss_writel(dev, PRU0_DATARAM_OFFSET, datatowrite,
+ (PRU0_DATARAM_SIZE / sizeof(int)));
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pruss_writel(dev, PRU1_DATARAM_OFFSET, datatowrite,
+ (PRU1_DATARAM_SIZE / sizeof(int)));
+
+ pruss_load(dev, PRUSS_NUM0, (u32 *)pru_suart_emu_code,
+ (fw_size / sizeof(u32)));
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pruss_load(dev, PRUSS_NUM1, (u32 *)pru_suart_emu_code,
+ (fw_size / sizeof(u32)));
+
+ retval = arm_to_pru_intr_init(dev);
+ if (-1 == retval)
+ return status;
+ pru_set_delay_count(dev, pruss_ioaddr->pru_clk_freq);
+ suart_set_pru_id(dev, PRUSS_NUM0);
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ suart_set_pru_id(dev, PRUSS_NUM1);
+
+ pru_set_rx_tx_mode(dev, PRU0_MODE, PRUSS_NUM0);
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pru_set_rx_tx_mode(dev, PRU1_MODE, PRUSS_NUM1);
+
+ pru_set_ram_data(dev, pruss_ioaddr);
+ pruss_run(dev, PRUSS_NUM0);
+
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pruss_run(dev, PRUSS_NUM1);
+
+ /* Initialize uart_statu_table */
+ for (idx = 0; idx < 8; idx++)
+ uart_statu_table[idx] = ePRU_SUART_UART_FREE;
+
+ return status;
+}
+
+void pru_set_fifo_timeout(struct device *dev, s16 timeout)
+{
+ pruss_writew(dev, PRU_SUART_PRU0_IDLE_TIMEOUT_OFFSET,
+ &timeout, 1);
+ if (PRU1_MODE != PRU_MODE_INVALID)
+ pruss_writew(dev, PRU_SUART_PRU1_IDLE_TIMEOUT_OFFSET,
+ &timeout, 1);
+}
+
+void pru_mcasp_deinit(void)
+{
+ suart_mcasp_reset(&suart_iomap);
+}
+
+/* suart Instance open routine */
+s16 pru_softuart_open(struct suart_handle *h_suart)
+{
+ s16 status = 0;
+ u16 uart_num = h_suart->uart_num - 1;
+
+ if (uart_statu_table[h_suart->uart_num - 1] ==
+ ePRU_SUART_UART_IN_USE) {
+ status = EUSERS;
+ return status;
+ } else {
+ h_suart->uart_type = uart_config[uart_num];
+ h_suart->uart_tx_channel = uart_tx[uart_num];
+ h_suart->uart_rx_channel = uart_rx[uart_num];
+ h_suart->uart_status = ePRU_SUART_UART_IN_USE;
+ uart_statu_table[h_suart->uart_num - 1] =
+ ePRU_SUART_UART_IN_USE;
+ }
+ return status;
+}
+
+/* suart instance close routine */
+s16 pru_softuart_close(struct suart_handle *h_uart)
+{
+ s16 status = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ } else {
+ uart_statu_table[h_uart->uart_num - 1] =
+ ePRU_SUART_UART_FREE;
+ /* Reset the Instance to Invalid */
+ h_uart->uart_num = PRU_SUART_UARTx_INVALID;
+ h_uart->uart_status = ePRU_SUART_UART_FREE;
+ }
+ return status;
+}
+
+static s16 search_chnum(u16 uart_num, u16 *ch_num, u32 *pru_offset, u16 mode)
+{
+ *ch_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ *ch_num = (uart_num *
+ SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+ if (uart_num <= 4) {
+ *pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ } else {
+ *pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ *ch_num -= 8;
+ }
+ if (mode == 2)
+ *ch_num = *ch_num + 1;
+
+ } else if ((mode == 1) || (mode == 2)) {
+ if (mode == 1) {
+ if (PRU0_MODE == PRU_MODE_TX_ONLY)
+ *pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ else if (PRU1_MODE == PRU_MODE_TX_ONLY)
+ *pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else if (mode == 2) {
+ if (PRU0_MODE == PRU_MODE_RX_ONLY)
+ *pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ else if (PRU1_MODE == PRU_MODE_RX_ONLY)
+ *pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ }
+ } else {
+ return 0;
+ }
+
+ return 0;
+}
+
+/*
+ * suart routine for setting relative baud rate
+ */
+s16 pru_softuart_setbaud(struct device *dev, struct suart_handle *h_uart,
+ u16 tx_clk_divisor, u16 rx_clk_divisor)
+{
+ u32 offset;
+ u32 pru_offset;
+ s16 status = 0;
+ u16 ch_num;
+ u16 regval = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ /* Set the clock divisor value s32o the McASP */
+ if ((tx_clk_divisor > 385) || (tx_clk_divisor == 0))
+ return -EINVAL;
+ if ((rx_clk_divisor > 385) || (rx_clk_divisor == 0))
+ return -EINVAL;
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ if (tx_clk_divisor != 0) {
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= (~0x3FF);
+ regval |= tx_clk_divisor;
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+ if (PRU0_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ } else if (PRU1_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ ch_num++;
+ } else {
+ return 0;
+ }
+ regval = 0;
+ if (rx_clk_divisor != 0) {
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= (~0x3FF);
+ regval |= tx_clk_divisor;
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+ return status;
+}
+
+/*
+ * suart routine for setting number of bits per character for a specific uart
+ */
+s16 pru_softuart_setdatabits(struct device *dev, struct suart_handle *h_uart,
+ u16 tx_data_bits, u16 rx_data_bits)
+{
+ u32 offset;
+ u32 pru_offset;
+ s16 status = 0;
+ u16 ch_num;
+ u32 reg_val;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ /*
+ * NOTE:
+ * The supported data bits are 6,7,8,9,10,11,12 bits per character
+ */
+
+ if ((tx_data_bits < ePRU_SUART_DATA_BITS6)
+ || (tx_data_bits > ePRU_SUART_DATA_BITS12))
+ return -EINVAL;
+
+ if ((rx_data_bits < ePRU_SUART_DATA_BITS6)
+ || (rx_data_bits > ePRU_SUART_DATA_BITS12))
+ return -EINVAL;
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ if (tx_data_bits != 0) {
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 1);
+ reg_val &= ~(0xF);
+ reg_val |= tx_data_bits;
+ pruss_writeb(dev, offset, (u8 *) ®_val, 1);
+ }
+ if (PRU0_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ } else if (PRU1_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ ch_num++;
+ } else {
+ return 0;
+ }
+ if (rx_data_bits != 0) {
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 1);
+ reg_val &= ~(0xF);
+ reg_val |= rx_data_bits;
+ pruss_writeb(dev, offset, (u8 *) &rx_data_bits, 1);
+ }
+
+ return status;
+}
+
+/*
+ * suart routine to configure specific uart
+ */
+s16 pru_softuart_setconfig(struct device *dev, struct suart_handle *h_uart,
+ struct suart_config *config_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ s16 status = 0;
+ u16 ch_num;
+ u16 reg_val = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ /*
+ * NOTE:
+ * Dependent baud rate for the given UART,the value MUST BE LESS THAN OR
+ * EQUAL TO 64, preScalarValue <= 64
+ */
+ if ((config_uart->tx_clk_divisor > 384)
+ || (config_uart->rx_clk_divisor > 384)) {
+ return -EINVAL;
+ }
+ if ((config_uart->tx_bits_per_char < 8)
+ || (config_uart->tx_bits_per_char > 14)) {
+ return -EINVAL;
+ }
+ if ((config_uart->rx_bits_per_char < 8)
+ || (config_uart->rx_bits_per_char > 14)) {
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ /* Configuring the Transmit part of the given UART */
+ /* Serializer has been as TX in mcasp config, by writing 1 in bits
+ * corresponding to tx serializer in PFUNC regsiter ie already set
+ * to GPIO mode PRU code will set then back to MCASP mode once TX
+ * request for that serializer is posted.It is required because at this
+ * pos32 Mcasp is accessed by both PRU and DSP have lower priority for
+ * Mcasp in comparison to PRU and DPS keeps on looping there only
+ */
+ /*
+ * suart_mcasp_tx_serialzier_set
+ * (config_uart->tx_serializer, &suart_iomap);
+ */
+ /* Configuring TX serializer */
+ if (config_uart->tx_serializer != PRU_SUART_SERIALIZER_NONE) {
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->tx_serializer <<
+ PRU_SUART_CH_CTRL_SR_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->tx_clk_divisor <<
+ PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->tx_bits_per_char <<
+ PRU_SUART_CH_CONFIG2_BITPERCHAR_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+ }
+
+ if (PRU0_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ } else if (PRU1_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ ch_num++;
+ } else {
+ return 0;
+ }
+
+ /* Configuring the Transmit part of the given UART */
+ if (config_uart->rx_serializer != PRU_SUART_SERIALIZER_NONE) {
+ /* Configuring RX serializer */
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->rx_serializer <<
+ PRU_SUART_CH_CTRL_SR_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* Configuring RX prescalar value and Oversampling */
+ offset = pru_offset +
+ (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->rx_clk_divisor <<
+ PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT) |
+ (config_uart->oversampling <<
+ PRU_SUART_CH_CONFIG1_OVS_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* Configuring RX bits per character value */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL)
+ + PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val = reg_val | (config_uart->rx_bits_per_char <<
+ PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+ }
+ return status;
+}
+
+/*
+ * suart routine for getting the number of bytes transfered
+ */
+s16 pru_softuart_get_tx_data_len(struct device *dev,
+ struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 ch_num;
+ u16 read_value = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &read_value, 2);
+ read_value = ((read_value & PRU_SUART_CH_CONFIG1_DIVISOR_MASK)
+ >> PRU_SUART_CH_CONFIG2_DATALEN_SHIFT);
+ return read_value;
+}
+
+/*
+ * suart routine for getting the number of bytes received
+ */
+s16 pru_softuart_get_rx_data_len(struct device *dev,
+ struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 ch_num;
+ u16 read_value = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &read_value, 2);
+ read_value = ((read_value & PRU_SUART_CH_CONFIG1_DIVISOR_MASK)
+ >> PRU_SUART_CH_CONFIG2_DATALEN_SHIFT);
+
+ return read_value;
+}
+
+/*
+ * suart routine to get the configuration information from a specific uart
+ */
+s16 pru_softuart_getconfig(struct device *dev,
+ struct suart_handle *h_uart,
+ struct suart_config *config_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 ch_num;
+ u16 reg_val = 0;
+ s16 status = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+
+ /*
+ * NOTE:
+ * Dependent baud rate for the given UART,the value MUST BE LESS THAN OR
+ * EQUAL TO 64, preScalarValue <= 64
+ */
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ /* Configuring the Transmit part of the given UART */
+ /* Configuring TX serializer */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->tx_serializer = ((reg_val & PRU_SUART_CH_CTRL_SR_MASK) >>
+ PRU_SUART_CH_CTRL_SR_SHIFT);
+ /* Configuring TX prescalar value */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->tx_clk_divisor = ((reg_val &
+ PRU_SUART_CH_CONFIG1_DIVISOR_MASK) >>
+ PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+
+ /* Configuring TX bits per character value */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->tx_bits_per_char = ((reg_val &
+ PRU_SUART_CH_CONFIG1_DIVISOR_MASK) >>
+ PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+
+ if (PRU0_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ } else if (PRU1_MODE == PRU_MODE_RX_ONLY) {
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ ch_num++;
+ } else {
+ return 0;
+ }
+ /* Configuring the Transmit part of the given UART */
+ /* Configuring RX serializer */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->rx_serializer = ((reg_val & PRU_SUART_CH_CTRL_SR_MASK) >>
+ PRU_SUART_CH_CTRL_SR_SHIFT);
+
+ /* Configuring RX prescalar value and oversampling */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG1_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->rx_clk_divisor = ((reg_val &
+ PRU_SUART_CH_CONFIG1_DIVISOR_MASK)
+ >> PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+ config_uart->oversampling = ((reg_val &
+ PRU_SUART_CH_CONFIG1_OVS_MASK) >>
+ PRU_SUART_CH_CONFIG1_OVS_SHIFT);
+
+ /* Configuring RX bits per character value */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ config_uart->rx_bits_per_char = ((reg_val &
+ PRU_SUART_CH_CONFIG1_DIVISOR_MASK)
+ >> PRU_SUART_CH_CONFIG1_DIVISOR_SHIFT);
+
+ return status;
+}
+
+s32 pru_softuart_pending_tx_request(struct device *dev)
+{
+ u32 offset = 0;
+ u32 ISR_value = 0;
+
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ return 0;
+ } else if (PRU0_MODE == PRU_MODE_TX_ONLY) {
+ /* Read PRU Interrupt Status Register from PRU */
+ offset = (u32) (PRUSS_INTC_STATCLRINT1 & 0xFFFF);
+ pruss_readl(dev, offset, (u32 *)&ISR_value, 1);
+ if ((ISR_value & 0x1) == 0x1)
+ return -EINVAL;
+ } else if (PRU1_MODE == PRU_MODE_TX_ONLY) {
+ /* Read PRU Interrupt Status Register from PRU */
+ offset = (u32) (PRUSS_INTC_STATCLRINT1 & 0xFFFF);
+ pruss_readl(dev, offset, (u32 *)&ISR_value, 1);
+ if ((ISR_value & 0x2) == 0x2)
+ return -EINVAL;
+ } else {
+ return 0;
+ }
+
+ return 0;
+}
+
+/*
+ * suart data transmit routine
+ */
+s16 pru_softuart_write(struct device *dev, struct suart_handle *h_uart,
+ u32 *pt_tx_data_buf, u16 data_len)
+{
+ u32 offset = 0;
+ u32 pru_offset;
+ s16 status = 0;
+ u16 ch_num;
+ u16 reg_val = 0;
+ u16 pru_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH))
+ pru_num = h_uart->uart_num;
+ else if (PRU0_MODE == PRU_MODE_TX_ONLY)
+ pru_num = 0;
+ else if (PRU1_MODE == PRU_MODE_TX_ONLY)
+ pru_num = 1;
+ else
+ return 0;
+
+ /* Writing data length to SUART channel register */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val &= ~PRU_SUART_CH_CONFIG2_DATALEN_MASK;
+ reg_val = reg_val | (data_len << PRU_SUART_CH_CONFIG2_DATALEN_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* Writing the data pos32er to channel TX data pointer */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXDATA_OFFSET;
+ pruss_writeb(dev, offset, (u8 *) pt_tx_data_buf, 4);
+
+ /* Service Request to PRU */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val &= ~(PRU_SUART_CH_CTRL_MODE_MASK |
+ PRU_SUART_CH_CTRL_SREQ_MASK);
+ reg_val |= (PRU_SUART_CH_CTRL_TX_MODE <<
+ PRU_SUART_CH_CTRL_MODE_SHIFT) | (PRU_SUART_CH_CTRL_SREQ <<
+ PRU_SUART_CH_CTRL_SREQ_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* generate ARM->PRU event */
+ suart_arm_to_pru_intr(dev, pru_num);
+
+ return status;
+}
+
+/*
+ * suart data receive routine
+ */
+s16 pru_softuart_read(struct device *dev, struct suart_handle *h_uart,
+ u32 *ptDataBuf, u16 data_len)
+{
+ u32 offset = 0;
+ u32 pru_offset;
+ s16 status = 0;
+ u16 ch_num;
+ u16 reg_val = 0;
+ u16 pru_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* channel starts from 0 and uart instance starts from 1 */
+ ch_num = (h_uart->uart_num *
+ SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+ pru_num = h_uart->uart_num;
+ } else if (PRU0_MODE == PRU_MODE_RX_ONLY) {
+ pru_num = 0;
+ } else if (PRU1_MODE == PRU_MODE_RX_ONLY) {
+ pru_num = 1;
+ } else {
+ return 0;
+ }
+ /* Writing data length to SUART channel register */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val &= ~PRU_SUART_CH_CONFIG2_DATALEN_MASK;
+ reg_val = reg_val | (data_len << PRU_SUART_CH_CONFIG2_DATALEN_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* Writing the data pos32er to channel RX data pointer */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXDATA_OFFSET;
+ pruss_writeb(dev, offset, (u8 *) ptDataBuf, 4);
+
+ /* Service Request to PRU */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val &= ~(PRU_SUART_CH_CTRL_MODE_MASK |
+ PRU_SUART_CH_CTRL_SREQ_MASK);
+ reg_val |= (PRU_SUART_CH_CTRL_RX_MODE <<
+ PRU_SUART_CH_CTRL_MODE_SHIFT) | (PRU_SUART_CH_CTRL_SREQ <<
+ PRU_SUART_CH_CTRL_SREQ_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+
+ /* enable the timeout s32errupt */
+ suart_intr_setmask(dev, h_uart->uart_num, PRU_RX_INTR,
+ CHN_TXRX_IE_MASK_TIMEOUT);
+
+ /* generate ARM->PRU event */
+ suart_arm_to_pru_intr(dev, pru_num);
+
+ return status;
+}
+
+/*
+ * suart routine to read the data from the RX FIFO
+ */
+s16 pru_softuart_read_data(struct device *dev, struct suart_handle *h_uart,
+ u8 *p_data_buffer, s32 max_len,
+ u32 *pdata_read)
+{
+ s16 ret_val = 0;
+ u8 *psrc_addr = NULL;
+ u32 data_read = 0;
+ u32 data_len = 0;
+ u32 char_len = 0;
+ u32 offset = 0;
+ u32 pru_offset;
+ u16 ch_num;
+ u16 status = 0;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+
+ /* Get the data pos32er from channel RX data pointer */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXDATA_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &psrc_addr, 4);
+
+ /* Reading data length from SUART channel register */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CONFIG2_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &data_len, 2);
+
+ /* read the character length */
+ char_len = data_len & PRU_SUART_CH_CONFIG2_BITPERCHAR_MASK;
+ char_len -= 2; /* remove the START & STOP bit */
+
+ data_len &= PRU_SUART_CH_CONFIG2_DATALEN_MASK;
+ data_len = data_len >> PRU_SUART_CH_CONFIG2_DATALEN_SHIFT;
+ data_len++;
+
+ /* if the character length is greater than 8, then the size doubles */
+ if (char_len > 8)
+ data_len *= 2;
+
+ /* Check if the time-out had occured. If, yes, then we need to find the
+ * number of bytes read from PRU. Else, we need to
+ * read the requested bytes
+ */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+ if (CHN_TXRX_STATUS_TIMEOUT == (status & CHN_TXRX_STATUS_TIMEOUT)) {
+ /* determine the number of bytes read s32o the FIFO */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL)
+ + PRU_SUART_CH_BYTESDONECNTR_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &data_read, 1);
+
+ /* if the character length is greater than 8,
+ then the size doubles */
+ if (char_len > 8)
+ data_read *= 2;
+
+/*
+ * the data corresponding is loaded in second
+ * half during the timeout
+ */
+ if (data_read > data_len) {
+ data_read -= data_len;
+ psrc_addr += data_len;
+ }
+
+ pru_softuart_clr_rx_fifo(dev, h_uart);
+ } else {
+ data_read = data_len;
+/*
+ * if the bit is set, the data is in the first
+ * half of the FIFO else the data is in the second half
+ */
+ /* Determine the buffer index by reading FIFO_OddEven flag*/
+ if (status & CHN_TXRX_STATUS_CMPLT)
+ psrc_addr += data_len;
+ }
+
+ /* we should be copying only max len given by the application */
+ if (data_read > max_len)
+ data_read = max_len;
+
+/* evaluate the virtual address of the FIFO address
+ * based on the physical addr
+ */
+ psrc_addr = (u8 *)((u32) psrc_addr -
+ (u32) suart_iomap.p_fifo_buff_phys_base +
+ (u32) suart_iomap.p_fifo_buff_virt_base);
+
+ /* Now we have both the data length and the source address. copy */
+ for (offset = 0; offset < data_read; offset++)
+ *p_data_buffer++ = *psrc_addr++;
+ *pdata_read = data_read;
+ ret_val = 0;
+
+ return ret_val;
+}
+
+/*
+ * suart routine to disable the receive functionality.
+ * This routine stops the PRU from receiving on selected
+ * UART and also disables the McASP serializer corresponding
+ * to this UART Rx line.
+ */
+s16 pru_softuart_stop_receive(struct device *dev, struct suart_handle *h_uart)
+{
+ u16 ret_status = 0;
+ u32 offset;
+ u32 pru_offset;
+ u16 ch_num;
+ u16 status;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+
+ /* read the existing value of status flag */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+
+ /* we need to clear the busy bit corresponding to receive channel */
+ status &= ~(CHN_TXRX_STATUS_RDY);
+ pruss_writeb(dev, offset, (u8 *) &status, 1);
+
+ /* get the serizlizer number being used for this Rx channel */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 2);
+ status &= PRU_SUART_CH_CTRL_SR_MASK;
+ status = status >> PRU_SUART_CH_CTRL_SR_SHIFT;
+
+ /* we need to de-activate the serializer corresponding to this rx */
+ ret_status = suart_asp_serializer_deactivate(status, &suart_iomap);
+
+ return ret_status;
+}
+
+/*
+ * suart routine to get the tx status for a specific uart
+ */
+s16 pru_softuart_get_tx_status(struct device *dev, struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 status = 0;
+ u16 ch_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+ return status;
+}
+
+s16 pru_softuart_clr_tx_status(struct device *dev, struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 status = 0;
+ u16 ch_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 1);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+ status &= ~(0x2);
+ pruss_writeb(dev, offset, (u8 *) &status, 1);
+ return status;
+}
+
+/*
+ * suart routine to get the rx status for a specific uart
+ */
+s16 pru_softuart_get_rx_status(struct device *dev, struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 status = 0;
+ u16 ch_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+ return status;
+}
+
+static s16 pru_softuart_clr_rx_fifo(struct device *dev,
+ struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 status = 0;
+ u16 ch_num;
+ u16 reg_val;
+ u16 uart_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ uart_num = h_uart->uart_num;
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+ if (PRU0_MODE == PRU_MODE_RX_ONLY)
+ uart_num = 0;
+ else if (PRU1_MODE == PRU_MODE_RX_ONLY)
+ uart_num = 1;
+
+ /* Reset the number of bytes read into the FIFO */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL)
+ + PRU_SUART_CH_BYTESDONECNTR_OFFSET;
+ pruss_readw(dev, offset, (u16 *) ®_val, 1);
+ reg_val &= 0x00;
+ pruss_writew(dev, offset, (u16 *) ®_val, 1);
+
+
+ /* Service Request to PRU */
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_CTRL_OFFSET;
+ pruss_readb(dev, offset, (u8 *) ®_val, 2);
+ reg_val &= ~(PRU_SUART_CH_CTRL_MODE_MASK | PRU_SUART_CH_CTRL_SREQ_MASK);
+ reg_val |= (PRU_SUART_CH_CTRL_RX_MODE << PRU_SUART_CH_CTRL_MODE_SHIFT) |
+ (PRU_SUART_CH_CTRL_SREQ << PRU_SUART_CH_CTRL_SREQ_SHIFT);
+ pruss_writeb(dev, offset, (u8 *) ®_val, 2);
+ suart_intr_setmask(dev, h_uart->uart_num, PRU_RX_INTR,
+ CHN_TXRX_IE_MASK_TIMEOUT);
+
+ /* generate ARM->PRU event */
+ suart_arm_to_pru_intr(dev, uart_num);
+
+ return status;
+}
+
+s16 pru_softuart_clr_rx_status(struct device *dev, struct suart_handle *h_uart)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 status = 0;
+ u16 ch_num;
+
+ if (h_uart == NULL) {
+ WARN_ON(1);
+ return -EINVAL;
+ }
+ search_chnum(h_uart->uart_num, &ch_num, &pru_offset, 2);
+
+ offset = pru_offset + (ch_num * SUART_NUM_OF_BYTES_PER_CHANNEL) +
+ PRU_SUART_CH_TXRXSTATUS_OFFSET;
+ pruss_readb(dev, offset, (u8 *) &status, 1);
+ status &= ~(0x3C);
+ pruss_writeb(dev, offset, (u8 *) &status, 1);
+ return status;
+}
+
+/*
+ * suart_s32r_status_read: Gets the Global Interrupt status register
+ * for the specified SUART.
+ * uart_num < 1 to 6 >
+ * txrx_flag < Indicates TX or RX s32errupt for the uart >
+ */
+s16 pru_softuart_get_isrstatus(struct device *dev, u16 uart_num, u16 *txrx_flag)
+{
+ u32 intc_offset;
+ u32 ch_num = 0xFF;
+ u32 reg_val = 0;
+ u32 reg_val2 = 0;
+ u32 ISR_value = 0;
+ u32 ack_reg_val = 0;
+ u32 stat_inx_clr_regoffset = 0;
+
+ /* initialize the status & Flag to known value */
+ *txrx_flag = 0;
+
+ stat_inx_clr_regoffset = (u32) (PRUSS_INTC_STATIDXCLR & 0xFFFF);
+
+ /* Read PRU Interrupt Status Register from PRU */
+ intc_offset = (u32) (PRUSS_INTC_STATCLRINT1 & 0xFFFF);
+
+ pruss_readl(dev, intc_offset, (u32 *)&ISR_value, 1);
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* Check if the interrupt occured for Tx */
+ ch_num = uart_num * 2 - 2;
+ reg_val2 = PRU_SUART0_TX_EVT_BIT << ((uart_num - 1) * 2);
+ if (ISR_value & reg_val2) {
+ /* interupt occured for TX */
+ *txrx_flag |= PRU_TX_INTR;
+ /* acknowledge the RX interrupt */
+ ack_reg_val = ch_num + PRU_SUART0_TX_EVT;
+ pruss_writel(dev, stat_inx_clr_regoffset,
+ (u32 *)&ack_reg_val, 1);
+ }
+
+ /* Check if the interrupt occured for Rx */
+ reg_val2 = PRU_SUART0_RX_EVT_BIT << ((uart_num - 1) * 2);
+ pruss_readl(dev, intc_offset, (u32 *)&ISR_value, 1);
+ if (ISR_value & reg_val2) {
+ /* interupt occured for RX */
+ *txrx_flag |= PRU_RX_INTR;
+ ch_num += 1;
+
+ /* acknowledge the RX interrupt */
+ ack_reg_val = ch_num + PRU_SUART0_TX_EVT;
+ pruss_writel(dev, stat_inx_clr_regoffset,
+ (u32 *)&ack_reg_val, 1);
+ }
+ } else {
+ ch_num = uart_num - 1;
+ if ((ISR_value & 0x03FC) != 0) {
+ reg_val2 = 1 << (uart_num + 1);
+ if (ISR_value & reg_val2) {
+ /* acknowledge the s32errupt */
+ ack_reg_val = ch_num + PRU_SUART0_TX_EVT;
+ pruss_writel(dev, stat_inx_clr_regoffset,
+ (u32 *)&ack_reg_val, 1);
+ *txrx_flag |= PRU_RX_INTR;
+ }
+ }
+ pruss_readl(dev, intc_offset, (u32 *)&ISR_value, 1);
+ if (ISR_value & 0x3FC00) {
+ reg_val2 = 1 << (uart_num + 9);
+ if (ISR_value & reg_val2) {
+ /* acknowledge the s32errupt */
+ ack_reg_val = ch_num + PRU_SUART4_TX_EVT;
+ pruss_writel(dev, stat_inx_clr_regoffset,
+ (u32 *)&ack_reg_val, 1);
+ *txrx_flag |= PRU_TX_INTR;
+ }
+ }
+ }
+ return reg_val;
+}
+
+s32 pru_intr_clr_isrstatus(struct device *dev, u16 uart_num, u32 txrxmode)
+{
+ u32 offset;
+ u16 txrx_flag = 0;
+ u16 chn_num;
+
+ chn_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* channel starts from 0 and uart instance starts from 1 */
+ chn_num = (uart_num * SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+ if (uart_num <= 4) {
+ /* PRU0 */
+ offset = PRU_SUART_PRU0_ISR_OFFSET + 1;
+ } else {
+ /* PRU1 */
+ offset = PRU_SUART_PRU1_ISR_OFFSET + 1;
+ /* First 8 channel corresponds to PRU0 */
+ chn_num -= 8;
+ }
+ if (2 == txrxmode)
+ chn_num++;
+ } else if (PRU0_MODE == txrxmode) {
+ offset = PRU_SUART_PRU0_ISR_OFFSET + 1;
+ } else if (PRU1_MODE == txrxmode) {
+ offset = PRU_SUART_PRU1_ISR_OFFSET + 1;
+ } else {
+ return 0;
+ }
+
+ pruss_readb(dev, offset, (u8 *) &txrx_flag, 1);
+ txrx_flag &= ~(0x2);
+ pruss_writeb(dev, offset, (u8 *) &txrx_flag, 1);
+
+ return 0;
+}
+
+s16 suart_arm_to_pru_intr(struct device *dev, u16 uart_num)
+{
+ u32 offset;
+ u32 value;
+ s16 retval;
+
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ if ((uart_num > 0) && (uart_num <= 4)) {
+ /* PRU0 SYS_EVT32 */
+ value = 0x20;
+ } else if ((uart_num > 4) && (uart_num <= 8)) {
+ /* PRU1 SYS_EVT33 */
+ value = 0x21;
+ } else {
+ return -EINVAL;
+ }
+ }
+
+ if ((PRU0_MODE == PRU_MODE_RX_ONLY) || (PRU1_MODE == PRU_MODE_RX_ONLY)
+ || (PRU0_MODE == PRU_MODE_TX_ONLY)
+ || (PRU1_MODE == PRU_MODE_TX_ONLY)) {
+ if (uart_num == PRUSS_NUM0) {
+ /* PRU0 SYS_EVT32 */
+ value = 0x20;
+ }
+
+ if (uart_num == PRUSS_NUM1) {
+ /* PRU0 SYS_EVT33 */
+ value = 0x21;
+ }
+ }
+
+ offset = (u32) (PRUSS_INTC_STATIDXSET & 0xFFFF);
+ retval = pruss_writel(dev, offset, (u32 *)&value, 1);
+ if (retval == -1)
+ return -1;
+ return 0;
+}
+
+static s16 arm_to_pru_intr_init(struct device *dev)
+{
+ u32 value;
+ u32 int_offset;
+
+ /* Clear all the host interrupts */
+ for (int_offset = 0; int_offset <= PRUSS_INTC_HOSTINTLVL_MAX;
+ int_offset++)
+ pruss_idx_writel(dev, PRUSS_INTC_HSTINTENIDXCLR, int_offset);
+
+ /* Enable the global s32errupt */
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_GLBLEN & 0xFFFF), 0, 1);
+
+ /* Enable the Host interrupts for all host channels */
+ for (int_offset = 0; int_offset <= PRUSS_INTC_HOSTINTLVL_MAX;
+ int_offset++)
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_HSTINTENIDXSET & 0xFFFF),
+ 0, int_offset);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_HOSTMAP0 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_HOSTMAP0_CHAN);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_HOSTMAP1 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_HOSTMAP1_CHAN);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_HOSTMAP2 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_HOSTMAP2_CHAN);
+
+ /* MAP Channel 0 to SYS_EVT31 */
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP7 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP7_SYS_EVT31);
+
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* Sets the channels for the system interrupt */
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP8 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP8_FULL);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP9 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP9_FULL);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP10 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP10_FULL);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP11 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP11_FULL);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP12 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP12_FULL);
+ }
+ if ((PRU0_MODE == PRU_MODE_RX_ONLY) || (PRU1_MODE == PRU_MODE_RX_ONLY)
+ || (PRU0_MODE == PRU_MODE_TX_ONLY)
+ || (PRU1_MODE == PRU_MODE_TX_ONLY)) {
+
+ /* Sets the channels for the system interrupt */
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP8 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP8_HALF);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP9 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP9_HALF);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP10 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP10_HALF);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP11 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP11_HALF);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_CHANMAP12 & 0xFFFF),
+ PRU_INTC_REGMAP_MASK, PRU_INTC_CHANMAP12_HALF);
+ }
+
+ /* Clear required set of system events
+ * and enable them using indexed register
+ */
+ for (int_offset = 0; int_offset < 18; int_offset++) {
+ value = 32 + int_offset;
+ pruss_idx_writel(dev, PRUSS_INTC_STATIDXCLR, value);
+ }
+
+ /* enable only the HOST to PRU interrupts and let the PRU to Host events
+ * enabled by the separate API on demand basis.
+ */
+ pruss_idx_writel(dev, PRUSS_INTC_ENIDXSET, 31);
+ pruss_idx_writel(dev, PRUSS_INTC_ENIDXSET, 32);
+ pruss_idx_writel(dev, PRUSS_INTC_ENIDXSET, 33);
+ pruss_idx_writel(dev, PRUSS_INTC_ENIDXSET, 50);
+ pruss_rmwl(dev, (u32) (PRUSS_INTC_GLBLEN & 0xFFFF), 0, 1);
+
+ /* Enable the Host interrupts for all host channels */
+ for (int_offset = 0; int_offset <= PRUSS_INTC_HOSTINTLVL_MAX;
+ int_offset++)
+ pruss_idx_writel(dev, PRUSS_INTC_HSTINTENIDXSET, int_offset);
+
+ return 0;
+}
+
+s32 suart_pru_to_host_intr_enable(struct device *dev, u16 uart_num,
+ u32 txrxmode, s32 flag)
+{
+ s32 ret_val = 0;
+ u32 offset;
+ u32 chn_num;
+ u32 value;
+ s16 retval = 0;
+
+ if (uart_num > 8)
+ return -EINVAL;
+
+ chn_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH) ||
+ (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ chn_num = (uart_num * 2) - 2;
+ if (2 == txrxmode) /* Rx mode */
+ chn_num++;
+ value = 34 + chn_num;
+ } else if ((PRU_MODE_RX_ONLY == txrxmode)
+ && (PRU0_MODE == PRU_MODE_RX_ONLY))
+ value = 34 + chn_num;
+ else if ((PRU_MODE_RX_ONLY == txrxmode)
+ && (PRU1_MODE == PRU_MODE_RX_ONLY))
+ value = 42 + chn_num;
+ else if ((PRU_MODE_TX_ONLY == txrxmode)
+ && (PRU0_MODE == PRU_MODE_TX_ONLY))
+ value = 34 + chn_num;
+ else if ((PRU_MODE_TX_ONLY == txrxmode)
+ && (PRU1_MODE == PRU_MODE_TX_ONLY))
+ value = 42 + chn_num;
+ else
+ return -1;
+
+ if (true == flag) {
+ offset = (u32) (PRUSS_INTC_ENIDXSET & 0xFFFF);
+ retval = pruss_writel(dev, offset, (u32 *)&value, 1);
+ if (retval == -1)
+ return -1;
+ } else {
+ offset = (u32) (PRUSS_INTC_ENIDXCLR & 0xFFFF);
+ retval = pruss_writel(dev, offset, (u32 *)&value, 1);
+ if (retval == -1)
+ return -1;
+ }
+ return ret_val;
+}
+
+s32 suart_intr_setmask(struct device *dev, u16 uart_num,
+ u32 txrxmode, u32 rmask)
+{
+ u32 offset;
+ u32 pru_offset;
+ u32 regval = 0;
+ u32 chn_num;
+
+ chn_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* channel starts from 0 and uart instance starts from 1 */
+ chn_num = (uart_num * SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+
+ if ((uart_num > 0) && (uart_num <= 4)) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if ((uart_num > 4) && (uart_num <= 8)) {
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ chn_num -= 8;
+ } else {
+ return -EINVAL;
+ }
+ if (2 == txrxmode) { /* rx mode */
+ chn_num++;
+ }
+ } else if (PRU0_MODE == txrxmode) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if (PRU1_MODE == txrxmode) {
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else {
+ return 0;
+ }
+ regval = 1 << chn_num;
+ if (CHN_TXRX_IE_MASK_CMPLT == (rmask & CHN_TXRX_IE_MASK_CMPLT))
+ pruss_rmww(dev, offset, regval, regval);
+
+ if ((rmask & SUART_GBL_INTR_ERR_MASK) ==
+ SUART_GBL_INTR_ERR_MASK) {
+ regval = SUART_GBL_INTR_ERR_MASK;
+ pruss_rmww(dev, offset, regval, regval);
+ }
+
+ offset = pru_offset +
+ (chn_num * SUART_NUM_OF_BYTES_PER_CHANNEL)
+ + PRU_SUART_CH_CONFIG1_OFFSET;
+ /* Framing Error Interrupt Masked */
+ if ((rmask & CHN_TXRX_IE_MASK_FE) == CHN_TXRX_IE_MASK_FE) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_FE);
+ regval |= CHN_TXRX_IE_MASK_FE;
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+
+ /* Break Indicator Interrupt Masked */
+ if (CHN_TXRX_IE_MASK_BI == (rmask & CHN_TXRX_IE_MASK_BI)) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_BI);
+ regval |= CHN_TXRX_IE_MASK_BI;
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+
+ /* Timeout error Interrupt Masked */
+ if (CHN_TXRX_IE_MASK_TIMEOUT ==
+ (rmask & CHN_TXRX_IE_MASK_TIMEOUT)) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_TIMEOUT);
+ regval |= CHN_TXRX_IE_MASK_TIMEOUT;
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+ return 0;
+}
+
+s32 suart_intr_clrmask(struct device *dev, u16 uart_num,
+ u32 txrxmode, u32 rmask)
+{
+ u32 offset;
+ u32 pru_offset;
+ u16 regval = 0;
+ u16 chn_num;
+
+ chn_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* channel starts from 0 and uart instance starts from 1 */
+ chn_num = (uart_num * SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+ if ((uart_num > 0) && (uart_num <= 4)) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if ((uart_num > 4) && (uart_num <= 8)) {
+ /* PRU1 */
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ /* First 8 channel corresponds to PRU0 */
+ chn_num -= 8;
+ } else {
+ return -EINVAL;
+ }
+ if (2 == txrxmode) { /* rx mode */
+ chn_num++;
+ }
+ } else if (PRU0_MODE == txrxmode) {
+ pru_offset = PRU_SUART_PRU0_CH0_OFFSET;
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if (PRU1_MODE == txrxmode) {
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ pru_offset = PRU_SUART_PRU1_CH0_OFFSET;
+ } else {
+ return 0;
+ }
+ regval = 1 << chn_num;
+ if (CHN_TXRX_IE_MASK_CMPLT == (rmask & CHN_TXRX_IE_MASK_CMPLT))
+ pruss_rmww(dev, offset, regval, 0);
+
+ if ((rmask & SUART_GBL_INTR_ERR_MASK) == SUART_GBL_INTR_ERR_MASK)
+ pruss_rmww(dev, offset, SUART_GBL_INTR_ERR_MASK, 0);
+
+ offset = pru_offset +
+ (chn_num * SUART_NUM_OF_BYTES_PER_CHANNEL)
+ + PRU_SUART_CH_CONFIG1_OFFSET;
+
+ /* Framing Error Interrupt Masked */
+ if ((rmask & CHN_TXRX_IE_MASK_FE) == CHN_TXRX_IE_MASK_FE) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_FE);
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+
+ /* Break Indicator Interrupt Masked */
+ if (CHN_TXRX_IE_MASK_BI == (rmask & CHN_TXRX_IE_MASK_BI)) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_BI);
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+
+ /* Timeout error Interrupt Masked */
+ if (CHN_TXRX_IE_MASK_TIMEOUT ==
+ (rmask & CHN_TXRX_IE_MASK_TIMEOUT)) {
+ regval = 0;
+ pruss_readb(dev, offset, (u8 *) ®val, 2);
+ regval &= ~(CHN_TXRX_IE_MASK_TIMEOUT);
+ pruss_writeb(dev, offset, (u8 *) ®val, 2);
+ }
+
+ return 0;
+}
+
+s32 suart_intr_getmask(struct device *dev, u16 uart_num, u32 txrxmode,
+ u32 rmask)
+{
+ u16 chn_num;
+ u32 offset;
+ u16 txrx_flag;
+ u16 regval = 1;
+
+ chn_num = uart_num - 1;
+ if ((PRU0_MODE == PRU_MODE_RX_TX_BOTH)
+ || (PRU1_MODE == PRU_MODE_RX_TX_BOTH)) {
+ /* channel starts from 0 and uart instance starts from 1 */
+ chn_num = (uart_num * SUART_NUM_OF_CHANNELS_PER_SUART) - 2;
+
+ if ((uart_num > 0) && (uart_num <= 4)) {
+
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if ((uart_num > 4) && (uart_num <= 8)) {
+ /* PRU1 */
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ /* First 8 channel corresponds to PRU0 */
+ chn_num -= 8;
+ } else {
+ return -EINVAL;
+ }
+
+ if (2 == txrxmode) { /* rx mode */
+ chn_num++;
+ }
+ } else if (PRU0_MODE == txrxmode) {
+ offset = PRU_SUART_PRU0_IMR_OFFSET;
+ } else if (PRU1_MODE == txrxmode) {
+ offset = PRU_SUART_PRU1_IMR_OFFSET;
+ } else {
+ return 0;
+ }
+ regval = regval << chn_num;
+ pruss_readb(dev, offset, (u8 *) &txrx_flag, 2);
+ txrx_flag &= regval;
+ if (0 == rmask) {
+ if (txrx_flag == 0)
+ return 1;
+ }
+ if (1 == rmask) {
+ if (txrx_flag == regval)
+ return 1;
+ }
+ return 0;
+}
new file mode 100644
@@ -0,0 +1,391 @@
+/*
+ * Copyright (C) 2010 Texas Instruments Incorporated
+ * Author: Jitendra Kumar <jitendra@mistralsolutions.com>
+ *
+ * This program is free software; you can redistribute it and/or modify it
+ * under the terms of the GNU General Public License as published by the
+ * Free Software Foundation version 2.
+ *
+ * This program is distributed "as is" WITHOUT ANY WARRANTY of any kind,
+ * whether express or implied; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * General Public License for more details.
+ */
+
+
+#include <linux/mfd/da8xx/da8xx_pru.h>
+#include "pruss_suart.h"
+
+#define SUART_TRX_DIV_CONF_SZ 4
+
+static s16 suart_mcasp_tx_baud_set(u32 tx_baud_value,
+ struct pruss_suart_iomap *pruss_ioaddr);
+static s16 suart_mcasp_rx_baud_set(u32 rx_baud_value, u32 oversampling,
+ struct pruss_suart_iomap *pruss_ioaddr);
+
+/*
+ * Lookup table for TX baud rate
+ * The divisor value is calculated using the formula
+ *
+ * ACLKX = (AUXCLK)/(CLKXDIV * HCLKXDIV)
+ *
+ * Where
+ * CLKXDIV takes values from 1-32
+ * HCLKXDIV takes values from 1-4096
+ * Here
+ * AUXCLK = 24MHz
+ */
+u32 lt_tx_baud_rate[][SUART_TRX_DIV_CONF_SZ] = {
+ /*BaudRate, Divisor, CLKXDIV,HCLKXDIV */
+ {300, 80000, 24, 3200},
+ {600, 40000, 15, 2500},
+ {1800, 13333, 10, 1212},
+ {2400, 10000, 4, 2000},
+ {4800, 5000, 1, 2500},
+ {7200, 3333, 0, 3333},
+ {9600, 2500, 0, 2500},
+ {14400, 1666, 0, 1666},
+ {19200, 1250, 0, 1250},
+ {38400, 625, 0, 625},
+ {57600, 416, 0, 416},
+ {115200, 208, 0, 208},
+ {230400, 104, 0, 104}
+};
+
+/*
+ * Lookup table for RX baud rate for 8 bit oversampling
+ * The divisor value is calculated using the formula
+ *
+ * ACLKR = (AUXCLK)/(CLKRDIV * HCLKRDIV) * Oversampling
+ *
+ * Where
+ * CLKRDIV takes values from 1-32
+ * HCLKRDIV takes values from 1-4096
+ * Here
+ * AUXCLK = 24MHz
+ */
+u32 lt_rx_8x_baud_rate[][SUART_TRX_DIV_CONF_SZ] = {
+/* BaudRate, Divisor, CLKXDIV, HCLKXDIV */
+ {300, 10000, 4, 2000},
+ {600, 5000, 1, 2500},
+ {1800, 1667, 0, 1667},
+ {2400, 1250, 0, 1250},
+ {7200, 417, 0, 417},
+ {4800, 625, 0, 625},
+ {9600, 312, 0, 312},
+ {14400, 208, 0, 208},
+ {19200, 156, 0, 156},
+ {38400, 78, 0, 78},
+ {57600, 52, 0, 52},
+ {115200, 26, 0, 26},
+ {230400, 13, 0, 13}
+};
+
+/*
+ * Lookup table for RX baud rate for 16 bit oversampling
+ * The divisor value is calculated using the formula
+ *
+ * ACLKR = (AUXCLK)/(CLKRDIV * HCLKRDIV) * Oversampling
+ *
+ * Where
+ * CLKRDIV takes values from 1-32
+ * HCLKRDIV takes values from 1-4096
+ * Here
+ * AUXCLK = 24MHz
+ */
+u32 lt_rx_16x_baud_rate[][SUART_TRX_DIV_CONF_SZ] = {
+/*BaudRate, Divisor, CLKXDIV, HCLKXDIV */
+ {300, 5000, 1, 2500},
+ {600, 2500, 0, 2500},
+ {1800, 833, 0, 833},
+ {2400, 625, 0, 625},
+ {4800, 312, 0, 312},
+ {7200, 208, 0, 208},
+ {9600, 156, 0, 156},
+ {14400, 104, 0, 104},
+ {19200, 78, 0, 78},
+ {38400, 39, 0, 39},
+ {57600, 26, 0, 26},
+ {115200, 13, 0, 13},
+ {230400, 6, 0, 6}
+};
+
+/*
+ * McASP configuration routine
+ */
+
+void suart_mcasp_reset(struct pruss_suart_iomap *pruss_ioaddr)
+{
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *) pruss_ioaddr->mcasp_io_addr;
+ /* reset mcasp. */
+ __raw_writel(MCASP_SUART_GBLCTL, &mcasp0_regs->GBLCTL);
+ __raw_writel(MCASP_SUART_RGBLCTL, &mcasp0_regs->RGBLCTL);
+ __raw_writel(MCASP_SUART_XGBLCTL, &mcasp0_regs->XGBLCTL);
+ __raw_writel(MCASP_SUART_XSTAT, &mcasp0_regs->XSTAT);
+ __raw_writel(MCASP_SUART_RSTAT, &mcasp0_regs->RSTAT);
+}
+
+void suart_mcasp_config(u32 tx_baud_value,
+ u32 rx_baud_value,
+ u32 oversampling,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *) pruss_ioaddr->mcasp_io_addr;
+ u32 temp_reg;
+
+ /* reset mcasp */
+ __raw_writel(MCASP_SUART_GBLCTL, &mcasp0_regs->GBLCTL);
+ __raw_writel(MCASP_SUART_RGBLCTL, &mcasp0_regs->RGBLCTL);
+ __raw_writel(MCASP_SUART_XGBLCTL, &mcasp0_regs->XGBLCTL);
+
+ /* configure receive registers */
+ if ((SUART_8X_OVRSMPL == oversampling) || (0 == oversampling)) {
+ __raw_writel(MCASP_SUART_RMASK_8, &mcasp0_regs->RMASK);
+ __raw_writel(MCASP_SUART_RFMT_8, &mcasp0_regs->RFMT);
+ }
+ if (SUART_16X_OVRSMPL == oversampling) {
+ __raw_writel(MCASP_SUART_RMASK_16, &mcasp0_regs->RMASK);
+ __raw_writel(MCASP_SUART_RFMT_16, &mcasp0_regs->RFMT);
+
+ }
+
+ __raw_writel(MCASP_SUART_FSRM, &mcasp0_regs->AFSRCTL);
+ __raw_writel(MCASP_SUART_CLKRM_CLKRP, &mcasp0_regs->ACLKRCTL);
+ __raw_writel(MCASP_SUART_HCLKRP, &mcasp0_regs->AHCLKRCTL);
+ suart_mcasp_rx_baud_set(rx_baud_value, oversampling, pruss_ioaddr);
+ __raw_writel(MCASP_SUART_RTDMS0, &mcasp0_regs->RTDM);
+ __raw_writel(MCASP_SUART_RSYNCERR, &mcasp0_regs->RINTCTL);
+ __raw_writel(MCASP_SUART_RMAX_RPS_256, &mcasp0_regs->RCLKCHK);
+
+ /* configure transmit registers. */
+ __raw_writel(MCASP_SUART_XMASK_0_31, &mcasp0_regs->XMASK);
+ __raw_writel(MCASP_SUART_XBUSEL_XSSZ_16_XPAD_0, &mcasp0_regs->XFMT);
+ __raw_writel(MCASP_SUART_FSXM, &mcasp0_regs->AFSXCTL);
+ __raw_writel(MCASP_SUART_CLKXM_ASYNC_CLKXP, &mcasp0_regs->ACLKXCTL);
+ __raw_writel(MCASP_SUART_HCLKXM, &mcasp0_regs->AHCLKXCTL);
+
+ suart_mcasp_tx_baud_set(tx_baud_value, pruss_ioaddr);
+ __raw_writel(MCASP_SUART_XTDMS0, &mcasp0_regs->XTDM);
+ __raw_writel(MCASP_SUART_XSYNCERR, &mcasp0_regs->XINTCTL);
+ __raw_writel(MCASP_SUART_XMAX_XPS_256, &mcasp0_regs->XCLKCHK);
+
+ /* Serializer as a transmitter */
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL0);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL1);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL2);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL3);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL4);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL5);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL6);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL7);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL8);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL9);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL10);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL11);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL12);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL13);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL14);
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL15);
+
+ /* Configure all AXR[n] as McASP pins */
+
+ /*
+ * Setting all TX MCASP AXR[n] Pin mapped to Even Serializer number
+ * (0,2,4,6,8,10,12,14) to GPIO Mode by default. During setting the
+ * serializer to TX mode in PRU assembly code, the MCASP AXR[n] Pin
+ * would get configured to MCASP mode of operation,
+ * before Actual Data Transfer
+ */
+
+ /* Setting all TX Pin to GPIO Mode by default */
+ temp_reg = (OMAPL_MCASP_PFUNC_RESETVAL) |
+ (1 << PRU_SUART0_CONFIG_TX_SER) | (1 << PRU_SUART1_CONFIG_TX_SER) |
+ (1 << PRU_SUART2_CONFIG_TX_SER) | (1 << PRU_SUART3_CONFIG_TX_SER) |
+ (1 << PRU_SUART4_CONFIG_TX_SER) | (1 << PRU_SUART5_CONFIG_TX_SER) |
+ (1 << PRU_SUART6_CONFIG_TX_SER) | (1 << PRU_SUART7_CONFIG_TX_SER);
+ __raw_writel(temp_reg, &mcasp0_regs->PFUNC);
+
+ __raw_writel(0xFFF, &mcasp0_regs->PDOUT);
+
+ /* config pin function and direction */
+ __raw_writel(0x00000000, &mcasp0_regs->PDIR);
+ temp_reg =
+ (1 << PRU_SUART0_CONFIG_TX_SER) | (1 << PRU_SUART1_CONFIG_TX_SER) |
+ (1 << PRU_SUART2_CONFIG_TX_SER) | (1 << PRU_SUART3_CONFIG_TX_SER) |
+ (1 << PRU_SUART4_CONFIG_TX_SER) | (1 << PRU_SUART5_CONFIG_TX_SER) |
+ (1 << PRU_SUART6_CONFIG_TX_SER) | (1 << PRU_SUART7_CONFIG_TX_SER) |
+ (MCASP_PDIR_VAL);
+ __raw_writel(temp_reg, &mcasp0_regs->PDIR);
+
+ __raw_writel(MCASP_SUART_DIT_DISABLE, &mcasp0_regs->DITCTL);
+ __raw_writel(MCASP_SUART_LOOPBACK_DISABLE, &mcasp0_regs->DLBCTL);
+ __raw_writel(MCASP_SUART_AMUTE_DISABLE, &mcasp0_regs->AMUTE);
+
+ __raw_writel(MCASP_SUART_XSTAT, &mcasp0_regs->XSTAT);
+ __raw_writel(MCASP_SUART_RSTAT, &mcasp0_regs->RSTAT);
+}
+
+void suart_mcasp_tx_serialzier_set(u32 serializer_num,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *) pruss_ioaddr->mcasp_io_addr;
+ u32 temp_reg;
+ temp_reg = mcasp0_regs->PFUNC | (0x1 << serializer_num);
+ __raw_writel(temp_reg, &mcasp0_regs->PFUNC);
+}
+
+/*
+ * mcasp TX buard rate setting routine
+ */
+s16 suart_mcasp_tx_baud_set(u32 tx_baud_value,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ u32 clk_div_val;
+ u32 loop_cnt;
+ s16 status = 0;
+ s16 found_val = false;
+
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *) pruss_ioaddr->mcasp_io_addr;
+ u32 temp_reg;
+
+ /* Search the supported baud rate in the table */
+ for (loop_cnt = 0; loop_cnt < SUART_NUM_OF_BAUDS_SUPPORTED;
+ loop_cnt++) {
+ if (tx_baud_value == lt_tx_baud_rate[loop_cnt][0]) {
+ found_val = true;
+ break;
+ }
+ }
+ if (found_val == true) {
+ clk_div_val = lt_tx_baud_rate[loop_cnt][2];
+ temp_reg = mcasp0_regs->ACLKXCTL |
+ clk_div_val << OMAPL_MCASP_ACLKXCTL_CLKXDIV_SHIFT;
+ __raw_writel(temp_reg, &mcasp0_regs->ACLKXCTL);
+ clk_div_val = lt_tx_baud_rate[loop_cnt][3];
+ temp_reg = mcasp0_regs->AHCLKXCTL |
+ clk_div_val << OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_SHIFT;
+ __raw_writel(temp_reg, &mcasp0_regs->AHCLKXCTL);
+ } else {
+ return -EINVAL ;
+ }
+ return status;
+}
+
+/*
+ * mcasp RX buard rate setting routine
+ */
+s16 suart_mcasp_rx_baud_set(u32 rx_baud_value,
+ u32 oversampling, struct pruss_suart_iomap *pruss_ioaddr)
+{
+ u32 clk_div_val;
+ u32 loop_cnt;
+ s16 status = 0;
+ s16 found_val = false;
+
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *) pruss_ioaddr->mcasp_io_addr;
+ u32 temp_reg;
+
+ if (oversampling == SUART_8X_OVRSMPL) {
+ for (loop_cnt = 0; loop_cnt < SUART_NUM_OF_BAUDS_SUPPORTED;
+ loop_cnt++) {
+ if (rx_baud_value == lt_rx_8x_baud_rate[loop_cnt][0]) {
+ clk_div_val = lt_rx_8x_baud_rate[loop_cnt][2];
+ temp_reg = mcasp0_regs->ACLKRCTL | (clk_div_val
+ << OMAPL_MCASP_ACLKXCTL_CLKXDIV_SHIFT);
+
+ __raw_writel(temp_reg, &mcasp0_regs->ACLKRCTL);
+
+ clk_div_val =
+ lt_rx_8x_baud_rate[loop_cnt][3] - 1;
+
+ temp_reg = mcasp0_regs->AHCLKRCTL | (clk_div_val
+ << OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_SHIFT);
+
+ __raw_writel(temp_reg, &mcasp0_regs->AHCLKRCTL);
+
+ found_val = true;
+ break;
+ }
+ }
+ } else if (oversampling == SUART_16X_OVRSMPL) {
+ for (loop_cnt = 0; loop_cnt < SUART_NUM_OF_BAUDS_SUPPORTED;
+ loop_cnt++) {
+ if (rx_baud_value == lt_rx_16x_baud_rate[loop_cnt][0]) {
+ clk_div_val = lt_rx_16x_baud_rate[loop_cnt][2];
+ temp_reg =
+ mcasp0_regs->ACLKRCTL | (clk_div_val <<
+ OMAPL_MCASP_ACLKXCTL_CLKXDIV_SHIFT);
+ __raw_writel(temp_reg, &mcasp0_regs->ACLKRCTL);
+ clk_div_val = lt_rx_16x_baud_rate[loop_cnt][3];
+ temp_reg =
+ mcasp0_regs->AHCLKRCTL | (clk_div_val <<
+ OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_SHIFT);
+ __raw_writel(temp_reg, &mcasp0_regs->AHCLKRCTL);
+ found_val = true;
+ break;
+ }
+ }
+ } else if (oversampling == 0) {
+ for (loop_cnt = 0; loop_cnt < SUART_NUM_OF_BAUDS_SUPPORTED;
+ loop_cnt++) {
+ if (rx_baud_value == lt_tx_baud_rate[loop_cnt][0]) {
+ clk_div_val = lt_tx_baud_rate[loop_cnt][2];
+ temp_reg =
+ mcasp0_regs->ACLKRCTL | (clk_div_val <<
+ OMAPL_MCASP_ACLKXCTL_CLKXDIV_SHIFT);
+ __raw_writel(temp_reg, &mcasp0_regs->ACLKRCTL);
+ clk_div_val = lt_tx_baud_rate[loop_cnt][3];
+ temp_reg =
+ mcasp0_regs->AHCLKRCTL | (clk_div_val <<
+ OMAPL_MCASP_AHCLKXCTL_HCLKXDIV_SHIFT);
+ __raw_writel(temp_reg, &mcasp0_regs->AHCLKRCTL);
+ found_val = true;
+ break;
+ }
+ }
+ } else {
+ return -EINVAL ;
+ }
+
+ if (found_val != true)
+ return -EINVAL ;
+
+ return status;
+}
+
+/*
+ * mcasp buard rate setting routine
+ */
+s16 suart_asp_baud_set(u32 tx_baud_value, u32 rx_baud_value, u32 oversampling,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ s16 status = 0;
+
+ status = suart_mcasp_tx_baud_set(tx_baud_value, pruss_ioaddr);
+ status = suart_mcasp_rx_baud_set(rx_baud_value, oversampling,
+ pruss_ioaddr);
+
+ return status;
+}
+
+/*
+ * mcasp deactivate the selected serializer
+ */
+s16 suart_asp_serializer_deactivate(u16 sr_num,
+ struct pruss_suart_iomap *pruss_ioaddr)
+{
+ s16 status = 0;
+ struct omapl_mcasp_regs_ovly *mcasp0_regs =
+ (struct omapl_mcasp_regs_ovly *)pruss_ioaddr->mcasp_io_addr;
+ if (sr_num > 15)
+ status = -EINVAL;
+ else
+ __raw_writel(MCASP_SUART_SRCTL_DISMOD, &mcasp0_regs->SRCTL0);
+
+ return status;
+}
@@ -202,6 +202,8 @@
/* VIA VT8500 SoC */
#define PORT_VT8500 97
+#define PORT_DA8XX_PRU_SUART 98
+
#ifdef __KERNEL__
#include <linux/compiler.h>