/*
* Copyright (c) 2012 The Linux Foundation. All rights reserved.
* Source : APQ8064 LK boot
*
* Copyright (c) 2011-2012, Code Aurora Forum. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Google, Inc. nor the names of its contributors
* may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <common.h>
#include <asm/arch-ipq806x/gsbi.h>
#include <asm/arch-ipq806x/clock.h>
#include <asm/arch-ipq806x/uart.h>
#include <serial.h>
#define FIFO_DATA_SIZE 4
extern board_ipq806x_params_t *gboard_param;
static unsigned int msm_boot_uart_dm_init(unsigned int uart_dm_base);
/* Received data is valid or not */
static int valid_data = 0;
/* Received data */
static unsigned int word = 0;
/**
* msm_boot_uart_dm_init_rx_transfer - Init Rx transfer
* @uart_dm_base: UART controller base address
*/
static unsigned int msm_boot_uart_dm_init_rx_transfer(unsigned int uart_dm_base)
{
/* Reset receiver */
writel(MSM_BOOT_UART_DM_CMD_RESET_RX,
MSM_BOOT_UART_DM_CR(uart_dm_base));
/* Enable receiver */
writel(MSM_BOOT_UART_DM_CR_RX_ENABLE,
MSM_BOOT_UART_DM_CR(uart_dm_base));
writel(MSM_BOOT_UART_DM_DMRX_DEF_VALUE,
MSM_BOOT_UART_DM_DMRX(uart_dm_base));
/* Clear stale event */
writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT,
MSM_BOOT_UART_DM_CR(uart_dm_base));
/* Enable stale event */
writel(MSM_BOOT_UART_DM_GCMD_ENA_STALE_EVT,
MSM_BOOT_UART_DM_CR(uart_dm_base));
return MSM_BOOT_UART_DM_E_SUCCESS;
}
/**
* msm_boot_uart_dm_read - reads a word from the RX FIFO.
* @data: location where the read data is stored
* @count: no of valid data in the FIFO
* @wait: indicates blocking call or not blocking call
*
* Reads a word from the RX FIFO. If no data is available blocks if
* @wait is true, else returns %MSM_BOOT_UART_DM_E_RX_NOT_READY.
*/
static unsigned int
msm_boot_uart_dm_read(unsigned int *data, int *count, int wait)
{
static int total_rx_data = 0;
static int rx_data_read = 0;
unsigned int base = 0;
uint32_t status_reg;
base = gboard_param->uart_dm_base;
if (data == NULL)
return MSM_BOOT_UART_DM_E_INVAL;
status_reg = readl(MSM_BOOT_UART_DM_MISR(base));
/* Check for DM_RXSTALE for RX transfer to finish */
while (!(status_reg & MSM_BOOT_UART_DM_RXSTALE)) {
status_reg = readl(MSM_BOOT_UART_DM_MISR(base));
if (!wait)
return MSM_BOOT_UART_DM_E_RX_NOT_READY;
}
/* Check for Overrun error. We'll just reset Error Status */
if (readl(MSM_BOOT_UART_DM_SR(base)) &
MSM_BOOT_UART_DM_SR_UART_OVERRUN) {
writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT,
MSM_BOOT_UART_DM_CR(base));
total_rx_data = rx_data_read = 0;
msm_boot_uart_dm_init(base);
return MSM_BOOT_UART_DM_E_RX_NOT_READY;
}
/* Read UART_DM_RX_TOTAL_SNAP for actual number of bytes received */
if (total_rx_data == 0)
total_rx_data = readl(MSM_BOOT_UART_DM_RX_TOTAL_SNAP(base));
/* Data available in FIFO; read a word. */
*data = readl(MSM_BOOT_UART_DM_RF(base, 0));
/* WAR for http://prism/CR/548280 */
if (*data == 0) {
return MSM_BOOT_UART_DM_E_RX_NOT_READY;
}
/* increment the total count of chars we've read so far */
rx_data_read += FIFO_DATA_SIZE;
/* actual count of valid data in word */
*count = ((total_rx_data < rx_data_read) ?
(FIFO_DATA_SIZE - (rx_data_read - total_rx_data)) :
FIFO_DATA_SIZE);
/* If there are still data left in FIFO we'll read them before
* initializing RX Transfer again
*/
if (rx_data_read < total_rx_data)
return MSM_BOOT_UART_DM_E_SUCCESS;
msm_boot_uart_dm_init_rx_transfer(base);
total_rx_data = rx_data_read = 0;
return MSM_BOOT_UART_DM_E_SUCCESS;
}
/**
* msm_boot_uart_replace_lr_with_cr - replaces "\n" with "\r\n"
* @data_in: characters to be converted
* @num_of_chars: no. of characters
* @data_out: location where converted chars are stored
*
* Replace linefeed char "\n" with carriage return + linefeed
* "\r\n". Currently keeping it simple than efficient.
*/
static unsigned int
msm_boot_uart_replace_lr_with_cr(char *data_in,
int num_of_chars,
char *data_out, int *num_of_chars_out)
{
int i = 0, j = 0;
if ((data_in == NULL) || (data_out == NULL) || (num_of_chars < 0))
return MSM_BOOT_UART_DM_E_INVAL;
for (i = 0, j = 0; i < num_of_chars; i++, j++) {
if (data_in[i] == '\n')
data_out[j++] = '\r';
data_out[j] = data_in[i];
}
*num_of_chars_out = j;
return MSM_BOOT_UART_DM_E_SUCCESS;
}
/**
* msm_boot_uart_dm_write - transmit data
* @data: data to transmit
* @num_of_chars: no. of bytes to transmit
*
* Writes the data to the TX FIFO. If no space is available blocks
* till space becomes available.
*/
static unsigned int
msm_boot_uart_dm_write(char *data, unsigned int num_of_chars)
{
unsigned int tx_word_count = 0;
unsigned int tx_char_left = 0, tx_char = 0;
unsigned int tx_word = 0;
int i = 0;
char *tx_data = NULL;
char new_data[1024];
unsigned int base = gboard_param->uart_dm_base;
if ((data == NULL) || (num_of_chars <= 0))
return MSM_BOOT_UART_DM_E_INVAL;
/* Replace line-feed (/n) with carriage-return + line-feed (/r/n) */
msm_boot_uart_replace_lr_with_cr(data, num_of_chars, new_data, &i);
tx_data = new_data;
num_of_chars = i;
/* Write to NO_CHARS_FOR_TX register number of characters
* to be transmitted. However, before writing TX_FIFO must
* be empty as indicated by TX_READY interrupt in IMR register
*/
/* Check if transmit FIFO is empty.
* If not we'll wait for TX_READY interrupt. */
if (!(readl(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) {
while (!(readl(MSM_BOOT_UART_DM_ISR(base)) & MSM_BOOT_UART_DM_TX_READY))
__udelay(1);
}
/* We are here. FIFO is ready to be written. */
/* Write number of characters to be written */
writel(num_of_chars, MSM_BOOT_UART_DM_NO_CHARS_FOR_TX(base));
/* Clear TX_READY interrupt */
writel(MSM_BOOT_UART_DM_GCMD_RES_TX_RDY_INT, MSM_BOOT_UART_DM_CR(base));
/* We use four-character word FIFO. So we need to divide data into
* four characters and write in UART_DM_TF register */
tx_word_count = (num_of_chars % 4) ? ((num_of_chars / 4) + 1) :
(num_of_chars / 4);
tx_char_left = num_of_chars;
for (i = 0; i < (int)tx_word_count; i++) {
tx_char = (tx_char_left < 4) ? tx_char_left : 4;
PACK_CHARS_INTO_WORDS(tx_data, tx_char, tx_word);
/* Wait till TX FIFO has space */
while (!(readl(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXRDY))
__udelay(1);
/* TX FIFO has space. Write the chars */
writel(tx_word, MSM_BOOT_UART_DM_TF(base, 0));
tx_char_left = num_of_chars - (i + 1) * 4;
tx_data = tx_data + 4;
}
return MSM_BOOT_UART_DM_E_SUCCESS;
}
/*
* msm_boot_uart_dm_reset - resets UART controller
* @base: UART controller base address
*/
static unsigned int msm_boot_uart_dm_reset(unsigned int base)
{
writel(MSM_BOOT_UART_DM_CMD_RESET_RX, MSM_BOOT_UART_DM_CR(base));
writel(MSM_BOOT_UART_DM_CMD_RESET_TX, MSM_BOOT_UART_DM_CR(base));
writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR(base));
writel(MSM_BOOT_UART_DM_CMD_RES_TX_ERR, MSM_BOOT_UART_DM_CR(base));
writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR(base));
return MSM_BOOT_UART_DM_E_SUCCESS;
}
/*
* msm_boot_uart_dm_init - initilaizes UART controller
* @uart_dm_base: UART controller base address
*/
static unsigned int msm_boot_uart_dm_init(unsigned int uart_dm_base)
{
/* Configure UART mode registers MR1 and MR2 */
/* Hardware flow control isn't supported */
writel(0x0, MSM_BOOT_UART_DM_MR1(uart_dm_base));
/* 8-N-1 configuration: 8 data bits - No parity - 1 stop bit */
writel(MSM_BOOT_UART_DM_8_N_1_MODE, MSM_BOOT_UART_DM_MR2(uart_dm_base));
/* Configure Interrupt Mask register IMR */
writel(MSM_BOOT_UART_DM_IMR_ENABLED, MSM_BOOT_UART_DM_IMR(uart_dm_base));
/*
* Configure Tx and Rx watermarks configuration registers
* TX watermark value is set to 0 - interrupt is generated when
* FIFO level is less than or equal to 0
*/
writel(MSM_BOOT_UART_DM_TFW_VALUE, MSM_BOOT_UART_DM_TFWR(uart_dm_base));
/* RX watermark value */
writel(MSM_BOOT_UART_DM_RFW_VALUE, MSM_BOOT_UART_DM_RFWR(uart_dm_base));
/* Configure Interrupt Programming Register */
/* Set initial Stale timeout value */
writel(MSM_BOOT_UART_DM_STALE_TIMEOUT_LSB,
MSM_BOOT_UART_DM_IPR(uart_dm_base));
/* Configure IRDA if required */
/* Disabling IRDA mode */
writel(0x0, MSM_BOOT_UART_DM_IRDA(uart_dm_base));
/* Configure hunt character value in HCR register */
/* Keep it in reset state */
writel(0x0, MSM_BOOT_UART_DM_HCR(uart_dm_base));
/*
* Configure Rx FIFO base address
* Both TX/RX shares same SRAM and default is half-n-half.
* Sticking with default value now.
* As such RAM size is (2^RAM_ADDR_WIDTH, 32-bit entries).
* We have found RAM_ADDR_WIDTH = 0x7f
*/
/* Issue soft reset command */
msm_boot_uart_dm_reset(uart_dm_base);
/* Enable/Disable Rx/Tx DM interfaces */
/* Data Mover not currently utilized. */
writel(0x0, MSM_BOOT_UART_DM_DMEN(uart_dm_base));
/* Enable transmitter */
writel(MSM_BOOT_UART_DM_CR_TX_ENABLE,
MSM_BOOT_UART_DM_CR(uart_dm_base));
/* Initialize Receive Path */
msm_boot_uart_dm_init_rx_transfer(uart_dm_base);
return 0;
}
/**
* uart_dm_init - initializes UART
*
* Initializes clocks, GPIO and UART controller.
*/
static int uart_dm_init(void)
{
unsigned int dm_base, gsbi_base;
dm_base = gboard_param->uart_dm_base;
gsbi_base = gboard_param->uart_gsbi_base;
ipq_configure_gpio(gboard_param->dbg_uart_gpio, NO_OF_DBG_UART_GPIOS);
/* Configure the uart clock */
uart_clock_config(gboard_param->uart_gsbi,
gboard_param->mnd_value.m_value,
gboard_param->mnd_value.n_value,
gboard_param->mnd_value.d_value,
gboard_param->clk_dummy);
writel(GSBI_PROTOCOL_CODE_I2C_UART <<
GSBI_CTRL_REG_PROTOCOL_CODE_S,
GSBI_CTRL_REG(gsbi_base));
writel(UART_DM_CLK_RX_TX_BIT_RATE, MSM_BOOT_UART_DM_CSR(dm_base));
/* Intialize UART_DM */
msm_boot_uart_dm_init(dm_base);
return 0;
}
/**
* ipq806x_serial_putc - transmits a character
* @c: character to transmit
*/
static void ipq806x_serial_putc(char c)
{
msm_boot_uart_dm_write(&c, 1);
}
/**
* ipq806x_serial_puts - transmits a string of data
* @s: string to transmit
*/
static void ipq806x_serial_puts(const char *s)
{
while (*s != '\0')
serial_putc(*s++);
}
/**
* ipq806x_serial_tstc - checks if data available for reading
*
* Returns 1 if data available, 0 otherwise
*/
static int ipq806x_serial_tstc(void)
{
/* Return if data is already read */
if (valid_data)
return 1;
/* Read data from the FIFO */
if (msm_boot_uart_dm_read(&word, &valid_data, 0) != MSM_BOOT_UART_DM_E_SUCCESS)
return 0;
return 1;
}
/**
* ipq806x_serial_getc - reads a character
*
* Returns the character read from serial port.
*/
static int ipq806x_serial_getc(void)
{
int byte;
while (!serial_tstc()) {
/* wait for incoming data */
}
byte = (int)word & 0xff;
word = word >> 8;
valid_data--;
return byte;
}
static struct serial_device ipq_serial_device = {
.name = "ipq_serial",
.start = uart_dm_init,
.getc = ipq806x_serial_getc,
.tstc = ipq806x_serial_tstc,
.putc = ipq806x_serial_putc,
.puts = ipq806x_serial_puts,
};
__weak struct serial_device *default_serial_console(void)
{
return &ipq_serial_device;
}
/**
* ipq806x_serial_init - initializes serial controller
*/
void ipq806x_serial_initialize(void)
{
serial_register(&ipq_serial_device);
}