platform/msm_shared/uart_dm.c - kernel/lk - Gitiles

 /* Copyright (c) 2010, 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 Code Aurora Forum, 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 "AS IS" AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
  * 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 <string.h>
 #include <stdlib.h>
 #include <debug.h>
 #include <reg.h>
 #include <platform/iomap.h>
 #include <platform/irqs.h>
 #include <platform/interrupts.h>
 #include <platform/gpio_hw.h>
 #include <dev/uart.h>
 #include "uart_dm.h"


 #ifndef NULL
 #define NULL        0
 #endif

 /* Note:
  * This is a basic implementation of UART_DM protocol. More focus has been
  * given on simplicity than efficiency. Few of the things to be noted are:
  * - RX path may not be suitable for multi-threaded scenaraio because of the
  *   use of static variables. TX path shouldn't have any problem though. If
  *   multi-threaded support is required, a simple data-structure can
  *   be maintained for each thread.
  * - Right now we are using polling method than interrupt based.
  * - We are using legacy UART protocol without Data Mover.
  * - Not all interrupts and error events are handled.
  * - While waiting Watchdog hasn't been taken into consideration.
  */


 #define PACK_CHARS_INTO_WORDS(a, cnt, word)  {                                 \
                                                word = 0;                       \
                                                for(int j=0; j < (int)cnt; j++) \
                                                {                               \
                                                    word |= (a[j] & 0xff)       \
                                                                << (j * 8);     \
                                                }                               \
                                               }


 /* Static Function Prototype Declarations */
 static unsigned int msm_boot_uart_config_gpios(void);
 static unsigned int msm_boot_uart_dm_config_clock(void);
 static unsigned int msm_boot_uart_dm_gsbi_init(void);
 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);
 static unsigned int msm_boot_uart_dm_init(void);
 static unsigned int msm_boot_uart_dm_read(unsigned int* data,
                                           int wait);
 static unsigned int msm_boot_uart_dm_write(char* data,
                                            unsigned int num_of_chars);
 static unsigned int msm_boot_uart_dm_init_rx_transfer(void);
 static unsigned int msm_boot_uart_dm_reset(void);


 /* Extern functions */
 void clock_config(unsigned int ns, unsigned int md,
                   unsigned int ns_addr, unsigned int md_addr);

 void gpio_tlmm_config(uint32_t gpio, uint8_t func,
                       uint8_t dir, uint8_t pull,
                       uint8_t drvstr, uint32_t enable );

 void udelay(unsigned usecs);


 /*
  * Helper function to replace Line Feed char "\n" with
  * Carriage Return "\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;
 }


 static unsigned int msm_boot_uart_dm_config_gpios(void)
 {
     /* GPIO Pin: MSM_BOOT_UART_DM_RX_GPIO (117)
        Function: 2
        Direction: IN
        Pull: No PULL
        Drive Strength: 8 ma
        Output Enable: Disable
     */
     gpio_tlmm_config(MSM_BOOT_UART_DM_RX_GPIO, 2, GPIO_INPUT,
                      GPIO_NO_PULL, GPIO_8MA, GPIO_DISABLE);

     /* GPIO Pin: MSM_BOOT_UART_DM_TX_GPIO (118)
        Function: 2
        Direction: OUT
        Pull: No PULL
        Drive Strength: 8 ma
        Output Enable: Disable
     */
     gpio_tlmm_config(MSM_BOOT_UART_DM_TX_GPIO, 2, GPIO_OUTPUT,
                      GPIO_NO_PULL, GPIO_8MA, GPIO_DISABLE);

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 static unsigned int msm_boot_uart_dm_config_clock(void)
 {
     unsigned int curr_value = 0;

     /* Vote for PLL8 to be enabled */
     curr_value = readl(MSM_BOOT_PLL_ENABLE_SC0);
     curr_value |= (1 << 8);
     writel(curr_value, MSM_BOOT_PLL_ENABLE_SC0);

     /* Proceed only after PLL is enabled */
     while (!(readl(MSM_BOOT_PLL8_STATUS) & (1<<16)));

     /* PLL8 is enabled. Enable gsbi_uart_clk */

     /* GSBI clock frequencies for UART protocol
      * Operating mode          gsbi_uart_clk
      * UART up to 115.2 Kbps   1.8432 MHz
      * UART up to 460.8 Kbps   7.3728 MHz
      * UART up to 4 Mbit/s     64 MHz
      *

      * Choosing lowest supported value
      * Rate (KHz)   NS          MD
      * 3686400	    0xFD940043	0x0006FD8E
      */

     clock_config(0xFD940043, 0x0006FD8E,
                  MSM_BOOT_UART_DM_APPS_NS,
                  MSM_BOOT_UART_DM_APPS_MD);

     /* Enable gsbi_pclk */
     writel(0x10, MSM_BOOT_UART_DM_GSBI_HCLK_CTL);

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 /*
  * Initialize and configure GSBI for operation
  */
 static unsigned int msm_boot_uart_dm_gsbi_init(void)
 {
     /* Configure the clock block */
     msm_boot_uart_dm_config_clock();

     /* Configure TLMM/GPIO to provide connectivity between GSBI
        product ports and chip pads */
     msm_boot_uart_dm_config_gpios();


     /* Configure Data Mover for GSBI operation.
      * Currently not supported. */

     /* Configure GSBI for UART_DM protocol.
      * I2C on 2 ports, UART (without HS flow control) on the other 2. */
     writel(0x60,  MSM_BOOT_GSBI_CTRL_REG);

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }

 /*
  * Reset the UART
  */
 static unsigned int msm_boot_uart_dm_reset(void)
 {
     writel(MSM_BOOT_UART_DM_CMD_RESET_RX, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CMD_RESET_TX, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CMD_RES_TX_ERR, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 /*
  * Initialize UART_DM - configure clock and required registers.
  */
 static unsigned int msm_boot_uart_dm_init(void)
 {
     /* Configure GSB12 for uart dm */
     msm_boot_uart_dm_gsbi_init();


     /* Configure clock selection register for tx and rx rates.
      * Selecting 115.2k for both RX and TX */
     writel(MSM_BOOT_UART_DM_RX_TX_BIT_RATE, MSM_BOOT_UART_DM_CSR);

     /* Configure UART mode registers MR1 and MR2 */
     /* Hardware flow control isn't supported */
     writel(0x0, MSM_BOOT_UART_DM_MR1);

     /* 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);

     /* Configure Interrupt Mask register IMR */
     writel(MSM_BOOT_UART_DM_IMR_ENABLED, MSM_BOOT_UART_DM_IMR);

     /* 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);

     /* RX watermark value*/
     writel(MSM_BOOT_UART_DM_RFW_VALUE, MSM_BOOT_UART_DM_RFWR);

     /* Configure Interrupt Programming Register*/
     /* Set initial Stale timeout value*/
     writel(MSM_BOOT_UART_DM_STALE_TIMEOUT_LSB, MSM_BOOT_UART_DM_IPR);

     /* Configure IRDA if required */
     /* Disabling IRDA mode */
     writel(0x0, MSM_BOOT_UART_DM_IRDA);

     /* Configure and enable sim interface if required */

     /* Configure hunt character value in HCR register */
     /* Keep it in reset state */
     writel(0x0, MSM_BOOT_UART_DM_HCR);

     /* 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();

     /* Enable/Disable Rx/Tx DM interfaces */
     /* Data Mover not currently utilized. */
     writel(0x0, MSM_BOOT_UART_DM_DMEN);


     /* Enable transmitter and receiver */
     writel(MSM_BOOT_UART_DM_CR_RX_ENABLE, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CR_TX_ENABLE, MSM_BOOT_UART_DM_CR);

     /* Initialize Receive Path */
     msm_boot_uart_dm_init_rx_transfer();

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 /*
  * Initialize Receive Path
  */
 static unsigned int msm_boot_uart_dm_init_rx_transfer(void)
 {
     writel(MSM_BOOT_UART_DM_GCMD_DIS_STALE_EVT, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);
     writel(MSM_BOOT_UART_DM_DMRX_DEF_VALUE, MSM_BOOT_UART_DM_DMRX);
     writel(MSM_BOOT_UART_DM_GCMD_ENA_STALE_EVT, MSM_BOOT_UART_DM_CR);

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }

 /*
  * UART Receive operation
  * Reads a word from the RX FIFO.
  */
 static unsigned int msm_boot_uart_dm_read(unsigned int* data, int wait)
 {
     static int rx_last_snap_count = 0;
     static int rx_chars_read_since_last_xfer = 0;

     if (data == NULL)
     {
         return MSM_BOOT_UART_DM_E_INVAL;
     }


     /* We will be polling RXRDY status bit */
     while (!(readl(MSM_BOOT_UART_DM_SR) & MSM_BOOT_UART_DM_SR_RXRDY))
     {
         /* if this is not a blocking call, we'll just return */
         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) & MSM_BOOT_UART_DM_SR_UART_OVERRUN)
     {
         writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR);
     }

     /* RX FIFO is ready; read a word. */
     *data = readl(MSM_BOOT_UART_DM_RF(0));

     /* increment the total count of chars we've read so far */
     rx_chars_read_since_last_xfer += 4;

      /* Rx transfer ends when one of the conditions is met:
      * - The number of characters received since the end of the previous xfer
      *   equals the value written to DMRX at Transfer Initialization
      * - A stale event occurred
      */

     /* If RX transfer has not ended yet */
     if (rx_last_snap_count == 0)
     {
         /* Check if we've received stale event */
         if (readl(MSM_BOOT_UART_DM_MISR) & MSM_BOOT_UART_DM_RXSTALE)
         {
             /* Send command to reset stale interrupt */
             writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);
         }

         /* Check if we haven't read more than DMRX value */
         else if ((unsigned int)rx_chars_read_since_last_xfer <
                   readl(MSM_BOOT_UART_DM_DMRX))
         {
             /* We can still continue reading before initializing RX transfer */
             return MSM_BOOT_UART_DM_E_SUCCESS;
         }

         /* If we've reached here it means RX xfer end conditions been met */

         /* Read UART_DM_RX_TOTAL_SNAP register to know how many valid chars
          * we've read so far since last transfer */
         rx_last_snap_count = readl(MSM_BOOT_UART_DM_RX_TOTAL_SNAP);

     }

     /* If there are still data left in FIFO we'll read them before
      * initializing RX Transfer again */
     if ((rx_last_snap_count - rx_chars_read_since_last_xfer) >= 0 )
     {
         return MSM_BOOT_UART_DM_E_SUCCESS;
     }

     msm_boot_uart_dm_init_rx_transfer();
     rx_last_snap_count = 0;
     rx_chars_read_since_last_xfer = 0;

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 /*
  * UART transmit operation
  */
 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];

     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) & MSM_BOOT_UART_DM_SR_TXEMT))
     {
         while (!(readl(MSM_BOOT_UART_DM_ISR) & MSM_BOOT_UART_DM_TX_READY))
         {
             udelay(1);
             /* Kick watchdog? */
         }
     }

     /* 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);

     /* Clear TX_READY interrupt */
     writel(MSM_BOOT_UART_DM_GCMD_RES_TX_RDY_INT, MSM_BOOT_UART_DM_CR);

     /* 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) & MSM_BOOT_UART_DM_SR_TXRDY))
         {
             udelay(1);
         }

         /* TX FIFO has space. Write the chars */
         writel(tx_word, MSM_BOOT_UART_DM_TF(0));
         tx_char_left = num_of_chars - (i+1)*4;
         tx_data = tx_data + 4;
     }

     return MSM_BOOT_UART_DM_E_SUCCESS;
 }


 /* Defining functions that's exposed to outside world and in coformance to
  * existing uart implemention. These functions are being called to initialize
  * UART and print debug messages in bootloader. */

 void uart_init(void)
 {
     char *data = "Android Bootloader - UART_DM Initialized!!!\n";

     msm_boot_uart_dm_init();
     msm_boot_uart_dm_write(data, 44);

 }

 /* UART_DM uses four character word FIFO where as UART core
  * uses a character FIFO. so it's really inefficient to try
  * to write single character. But that's how dprintf has been
  * implemented.
  */
 int uart_putc(int port, char c)
 {

     msm_boot_uart_dm_write(&c, 1);

     return 0;
 }

 /* UART_DM uses four character word FIFO whereas uart_getc
  * is supposed to read only one character. So we need to
  * read a word and keep track of each character in the word.
  */
 int uart_getc(int port, bool wait)
 {
     int byte;
     static unsigned int word = 0;

     if (!word)
     {
         /* Read from FIFO only if it's a first read or all the four
          * characters out of a word have been read */
         if (msm_boot_uart_dm_read( &word, wait) != MSM_BOOT_UART_DM_E_SUCCESS)
         {
             return -1;
         }

     }

     byte = (int) word & 0xff;
     word = word >> 8;

     return byte;
 }
	/* Copyright (c) 2010, 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 Code Aurora Forum, 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 "AS IS" AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
	* 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 <string.h>
	#include <stdlib.h>
	#include <debug.h>
	#include <reg.h>
	#include <platform/iomap.h>
	#include <platform/irqs.h>
	#include <platform/interrupts.h>
	#include <platform/gpio_hw.h>
	#include <dev/uart.h>
	#include "uart_dm.h"


	#ifndef NULL
	#define NULL 0
	#endif

	/* Note:
	* This is a basic implementation of UART_DM protocol. More focus has been
	* given on simplicity than efficiency. Few of the things to be noted are:
	* - RX path may not be suitable for multi-threaded scenaraio because of the
	* use of static variables. TX path shouldn't have any problem though. If
	* multi-threaded support is required, a simple data-structure can
	* be maintained for each thread.
	* - Right now we are using polling method than interrupt based.
	* - We are using legacy UART protocol without Data Mover.
	* - Not all interrupts and error events are handled.
	* - While waiting Watchdog hasn't been taken into consideration.
	*/


	#define PACK_CHARS_INTO_WORDS(a, cnt, word) { \
	word = 0; \
	for(int j=0; j < (int)cnt; j++) \
	{ \
	word \|= (a[j] & 0xff) \
	<< (j * 8); \
	} \
	}


	/* Static Function Prototype Declarations */
	static unsigned int msm_boot_uart_config_gpios(void);
	static unsigned int msm_boot_uart_dm_config_clock(void);
	static unsigned int msm_boot_uart_dm_gsbi_init(void);
	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);
	static unsigned int msm_boot_uart_dm_init(void);
	static unsigned int msm_boot_uart_dm_read(unsigned int* data,
	int wait);
	static unsigned int msm_boot_uart_dm_write(char* data,
	unsigned int num_of_chars);
	static unsigned int msm_boot_uart_dm_init_rx_transfer(void);
	static unsigned int msm_boot_uart_dm_reset(void);


	/* Extern functions */
	void clock_config(unsigned int ns, unsigned int md,
	unsigned int ns_addr, unsigned int md_addr);

	void gpio_tlmm_config(uint32_t gpio, uint8_t func,
	uint8_t dir, uint8_t pull,
	uint8_t drvstr, uint32_t enable );

	void udelay(unsigned usecs);


	/*
	* Helper function to replace Line Feed char "\n" with
	* Carriage Return "\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;
	}


	static unsigned int msm_boot_uart_dm_config_gpios(void)
	{
	/* GPIO Pin: MSM_BOOT_UART_DM_RX_GPIO (117)
	Function: 2
	Direction: IN
	Pull: No PULL
	Drive Strength: 8 ma
	Output Enable: Disable
	*/
	gpio_tlmm_config(MSM_BOOT_UART_DM_RX_GPIO, 2, GPIO_INPUT,
	GPIO_NO_PULL, GPIO_8MA, GPIO_DISABLE);

	/* GPIO Pin: MSM_BOOT_UART_DM_TX_GPIO (118)
	Function: 2
	Direction: OUT
	Pull: No PULL
	Drive Strength: 8 ma
	Output Enable: Disable
	*/
	gpio_tlmm_config(MSM_BOOT_UART_DM_TX_GPIO, 2, GPIO_OUTPUT,
	GPIO_NO_PULL, GPIO_8MA, GPIO_DISABLE);

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}



	static unsigned int msm_boot_uart_dm_config_clock(void)
	{
	unsigned int curr_value = 0;

	/* Vote for PLL8 to be enabled */
	curr_value = readl(MSM_BOOT_PLL_ENABLE_SC0);
	curr_value \|= (1 << 8);
	writel(curr_value, MSM_BOOT_PLL_ENABLE_SC0);

	/* Proceed only after PLL is enabled */
	while (!(readl(MSM_BOOT_PLL8_STATUS) & (1<<16)));

	/* PLL8 is enabled. Enable gsbi_uart_clk */

	/* GSBI clock frequencies for UART protocol
	* Operating mode gsbi_uart_clk
	* UART up to 115.2 Kbps 1.8432 MHz
	* UART up to 460.8 Kbps 7.3728 MHz
	* UART up to 4 Mbit/s 64 MHz
	*

	* Choosing lowest supported value
	* Rate (KHz) NS MD
	* 3686400 0xFD940043 0x0006FD8E
	*/

	clock_config(0xFD940043, 0x0006FD8E,
	MSM_BOOT_UART_DM_APPS_NS,
	MSM_BOOT_UART_DM_APPS_MD);

	/* Enable gsbi_pclk */
	writel(0x10, MSM_BOOT_UART_DM_GSBI_HCLK_CTL);

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}


	/*
	* Initialize and configure GSBI for operation
	*/
	static unsigned int msm_boot_uart_dm_gsbi_init(void)
	{
	/* Configure the clock block */
	msm_boot_uart_dm_config_clock();

	/* Configure TLMM/GPIO to provide connectivity between GSBI
	product ports and chip pads */
	msm_boot_uart_dm_config_gpios();


	/* Configure Data Mover for GSBI operation.
	* Currently not supported. */

	/* Configure GSBI for UART_DM protocol.
	* I2C on 2 ports, UART (without HS flow control) on the other 2. */
	writel(0x60, MSM_BOOT_GSBI_CTRL_REG);

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}

	/*
	* Reset the UART
	*/
	static unsigned int msm_boot_uart_dm_reset(void)
	{
	writel(MSM_BOOT_UART_DM_CMD_RESET_RX, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CMD_RESET_TX, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CMD_RES_TX_ERR, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}


	/*
	* Initialize UART_DM - configure clock and required registers.
	*/
	static unsigned int msm_boot_uart_dm_init(void)
	{
	/* Configure GSB12 for uart dm */
	msm_boot_uart_dm_gsbi_init();


	/* Configure clock selection register for tx and rx rates.
	* Selecting 115.2k for both RX and TX */
	writel(MSM_BOOT_UART_DM_RX_TX_BIT_RATE, MSM_BOOT_UART_DM_CSR);

	/* Configure UART mode registers MR1 and MR2 */
	/* Hardware flow control isn't supported */
	writel(0x0, MSM_BOOT_UART_DM_MR1);

	/* 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);

	/* Configure Interrupt Mask register IMR */
	writel(MSM_BOOT_UART_DM_IMR_ENABLED, MSM_BOOT_UART_DM_IMR);

	/* 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);

	/* RX watermark value*/
	writel(MSM_BOOT_UART_DM_RFW_VALUE, MSM_BOOT_UART_DM_RFWR);

	/* Configure Interrupt Programming Register*/
	/* Set initial Stale timeout value*/
	writel(MSM_BOOT_UART_DM_STALE_TIMEOUT_LSB, MSM_BOOT_UART_DM_IPR);

	/* Configure IRDA if required */
	/* Disabling IRDA mode */
	writel(0x0, MSM_BOOT_UART_DM_IRDA);

	/* Configure and enable sim interface if required */

	/* Configure hunt character value in HCR register */
	/* Keep it in reset state */
	writel(0x0, MSM_BOOT_UART_DM_HCR);

	/* 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();

	/* Enable/Disable Rx/Tx DM interfaces */
	/* Data Mover not currently utilized. */
	writel(0x0, MSM_BOOT_UART_DM_DMEN);


	/* Enable transmitter and receiver */
	writel(MSM_BOOT_UART_DM_CR_RX_ENABLE, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CR_TX_ENABLE, MSM_BOOT_UART_DM_CR);

	/* Initialize Receive Path */
	msm_boot_uart_dm_init_rx_transfer();

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}


	/*
	* Initialize Receive Path
	*/
	static unsigned int msm_boot_uart_dm_init_rx_transfer(void)
	{
	writel(MSM_BOOT_UART_DM_GCMD_DIS_STALE_EVT, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);
	writel(MSM_BOOT_UART_DM_DMRX_DEF_VALUE, MSM_BOOT_UART_DM_DMRX);
	writel(MSM_BOOT_UART_DM_GCMD_ENA_STALE_EVT, MSM_BOOT_UART_DM_CR);

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}

	/*
	* UART Receive operation
	* Reads a word from the RX FIFO.
	*/
	static unsigned int msm_boot_uart_dm_read(unsigned int* data, int wait)
	{
	static int rx_last_snap_count = 0;
	static int rx_chars_read_since_last_xfer = 0;

	if (data == NULL)
	{
	return MSM_BOOT_UART_DM_E_INVAL;
	}



	/* We will be polling RXRDY status bit */
	while (!(readl(MSM_BOOT_UART_DM_SR) & MSM_BOOT_UART_DM_SR_RXRDY))
	{
	/* if this is not a blocking call, we'll just return */
	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) & MSM_BOOT_UART_DM_SR_UART_OVERRUN)
	{
	writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR);
	}

	/* RX FIFO is ready; read a word. */
	*data = readl(MSM_BOOT_UART_DM_RF(0));

	/* increment the total count of chars we've read so far */
	rx_chars_read_since_last_xfer += 4;

	/* Rx transfer ends when one of the conditions is met:
	* - The number of characters received since the end of the previous xfer
	* equals the value written to DMRX at Transfer Initialization
	* - A stale event occurred
	*/

	/* If RX transfer has not ended yet */
	if (rx_last_snap_count == 0)
	{
	/* Check if we've received stale event */
	if (readl(MSM_BOOT_UART_DM_MISR) & MSM_BOOT_UART_DM_RXSTALE)
	{
	/* Send command to reset stale interrupt */
	writel(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR);
	}

	/* Check if we haven't read more than DMRX value */
	else if ((unsigned int)rx_chars_read_since_last_xfer <
	readl(MSM_BOOT_UART_DM_DMRX))
	{
	/* We can still continue reading before initializing RX transfer */
	return MSM_BOOT_UART_DM_E_SUCCESS;
	}

	/* If we've reached here it means RX xfer end conditions been met */

	/* Read UART_DM_RX_TOTAL_SNAP register to know how many valid chars
	* we've read so far since last transfer */
	rx_last_snap_count = readl(MSM_BOOT_UART_DM_RX_TOTAL_SNAP);

	}

	/* If there are still data left in FIFO we'll read them before
	* initializing RX Transfer again */
	if ((rx_last_snap_count - rx_chars_read_since_last_xfer) >= 0 )
	{
	return MSM_BOOT_UART_DM_E_SUCCESS;
	}

	msm_boot_uart_dm_init_rx_transfer();
	rx_last_snap_count = 0;
	rx_chars_read_since_last_xfer = 0;

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}


	/*
	* UART transmit operation
	*/
	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];

	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) & MSM_BOOT_UART_DM_SR_TXEMT))
	{
	while (!(readl(MSM_BOOT_UART_DM_ISR) & MSM_BOOT_UART_DM_TX_READY))
	{
	udelay(1);
	/* Kick watchdog? */
	}
	}

	/* 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);

	/* Clear TX_READY interrupt */
	writel(MSM_BOOT_UART_DM_GCMD_RES_TX_RDY_INT, MSM_BOOT_UART_DM_CR);

	/* 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) & MSM_BOOT_UART_DM_SR_TXRDY))
	{
	udelay(1);
	}

	/* TX FIFO has space. Write the chars */
	writel(tx_word, MSM_BOOT_UART_DM_TF(0));
	tx_char_left = num_of_chars - (i+1)*4;
	tx_data = tx_data + 4;
	}

	return MSM_BOOT_UART_DM_E_SUCCESS;
	}


	/* Defining functions that's exposed to outside world and in coformance to
	* existing uart implemention. These functions are being called to initialize
	* UART and print debug messages in bootloader. */

	void uart_init(void)
	{
	char *data = "Android Bootloader - UART_DM Initialized!!!\n";

	msm_boot_uart_dm_init();
	msm_boot_uart_dm_write(data, 44);

	}

	/* UART_DM uses four character word FIFO where as UART core
	* uses a character FIFO. so it's really inefficient to try
	* to write single character. But that's how dprintf has been
	* implemented.
	*/
	int uart_putc(int port, char c)
	{

	msm_boot_uart_dm_write(&c, 1);

	return 0;
	}

	/* UART_DM uses four character word FIFO whereas uart_getc
	* is supposed to read only one character. So we need to
	* read a word and keep track of each character in the word.
	*/
	int uart_getc(int port, bool wait)
	{
	int byte;
	static unsigned int word = 0;

	if (!word)
	{
	/* Read from FIFO only if it's a first read or all the four
	* characters out of a word have been read */
	if (msm_boot_uart_dm_read( &word, wait) != MSM_BOOT_UART_DM_E_SUCCESS)
	{
	return -1;
	}

	}

	byte = (int) word & 0xff;
	word = word >> 8;

	return byte;
	}