/* * 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 #include #include #include #include #include #include #include #include #include #include #define FIFO_DATA_SIZE 4 typedef struct { unsigned uart_dm_base; unsigned uart_gsbi_base; unsigned uart_gsbi; uart_clk_mnd_t mnd_value; gpio_func_data_t dbg_uart_gpio[NO_OF_DBG_UART_GPIOS]; } uart_params_t; /* * All constants lifted from u-boot's * board/qcom/ipq806x_cdp/ipq806x_board_param.h */ static const uart_params_t uart_board_param = { .uart_dm_base = UART4_DM_BASE, .uart_gsbi_base = UART_GSBI4_BASE, .uart_gsbi = GSBI_4, .mnd_value = { 12, 625, 313 }, .dbg_uart_gpio = { { .gpio = 10, .func = 1, .dir = GPIO_OUTPUT, .pull = GPIO_NO_PULL, .drvstr = GPIO_12MA, .enable = GPIO_DISABLE }, { .gpio = 11, .func = 1, .dir = GPIO_INPUT, .pull = GPIO_NO_PULL, .drvstr = GPIO_12MA, .enable = GPIO_DISABLE }, } }; 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_i(MSM_BOOT_UART_DM_CMD_RESET_RX, MSM_BOOT_UART_DM_CR(uart_dm_base)); /* Enable receiver */ writel_i(MSM_BOOT_UART_DM_CR_RX_ENABLE, MSM_BOOT_UART_DM_CR(uart_dm_base)); writel_i(MSM_BOOT_UART_DM_DMRX_DEF_VALUE, MSM_BOOT_UART_DM_DMRX(uart_dm_base)); /* Clear stale event */ writel_i(MSM_BOOT_UART_DM_CMD_RES_STALE_INT, MSM_BOOT_UART_DM_CR(uart_dm_base)); /* Enable stale event */ writel_i(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. */ #if 0 /* Not used yet */ 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 = uart_board_param.uart_dm_base; if (data == NULL) return MSM_BOOT_UART_DM_E_INVAL; status_reg = readl_i(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_i(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_i(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_UART_OVERRUN) { writel_i(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_i(MSM_BOOT_UART_DM_RX_TOTAL_SNAP(base)); /* Data available in FIFO; read a word. */ *data = readl_i(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; } #endif /** * 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(unsigned 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(unsigned 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 = uart_board_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_i(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) { while (!(readl_i(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_i(num_of_chars, MSM_BOOT_UART_DM_NO_CHARS_FOR_TX(base)); /* Clear TX_READY interrupt */ writel_i(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_i(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXRDY)) udelay(1); /* TX FIFO has space. Write the chars */ writel_i(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_i(MSM_BOOT_UART_DM_CMD_RESET_RX, MSM_BOOT_UART_DM_CR(base)); writel_i(MSM_BOOT_UART_DM_CMD_RESET_TX, MSM_BOOT_UART_DM_CR(base)); writel_i(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR(base)); writel_i(MSM_BOOT_UART_DM_CMD_RES_TX_ERR, MSM_BOOT_UART_DM_CR(base)); writel_i(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_i(0x0, MSM_BOOT_UART_DM_MR1(uart_dm_base)); /* 8-N-1 configuration: 8 data bits - No parity - 1 stop bit */ writel_i(MSM_BOOT_UART_DM_8_N_1_MODE, MSM_BOOT_UART_DM_MR2(uart_dm_base)); /* Configure Interrupt Mask register IMR */ writel_i(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_i(MSM_BOOT_UART_DM_TFW_VALUE, MSM_BOOT_UART_DM_TFWR(uart_dm_base)); /* RX watermark value */ writel_i(MSM_BOOT_UART_DM_RFW_VALUE, MSM_BOOT_UART_DM_RFWR(uart_dm_base)); /* Configure Interrupt Programming Register */ /* Set initial Stale timeout value */ writel_i(MSM_BOOT_UART_DM_STALE_TIMEOUT_LSB, MSM_BOOT_UART_DM_IPR(uart_dm_base)); /* Configure IRDA if required */ /* Disabling IRDA mode */ writel_i(0x0, MSM_BOOT_UART_DM_IRDA(uart_dm_base)); /* Configure hunt character value in HCR register */ /* Keep it in reset state */ writel_i(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_i(0x0, MSM_BOOT_UART_DM_DMEN(uart_dm_base)); /* Enable transmitter */ writel_i(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_init - initializes UART * * Initializes clocks, GPIO and UART controller. */ void uart_init(int idx) { /* Note int idx isn't used in this driver. */ unsigned int dm_base, gsbi_base; dm_base = uart_board_param.uart_dm_base; gsbi_base = uart_board_param.uart_gsbi_base; ipq_configure_gpio(uart_board_param.dbg_uart_gpio, NO_OF_DBG_UART_GPIOS); /* Configure the uart clock */ uart_clock_config(uart_board_param.uart_gsbi, uart_board_param.mnd_value.m_value, uart_board_param.mnd_value.n_value, uart_board_param.mnd_value.d_value, 0); writel_i(GSBI_PROTOCOL_CODE_I2C_UART << GSBI_CTRL_REG_PROTOCOL_CODE_S, GSBI_CTRL_REG(gsbi_base)); writel_i(UART_DM_CLK_RX_TX_BIT_RATE, MSM_BOOT_UART_DM_CSR(dm_base)); /* Intialize UART_DM */ msm_boot_uart_dm_init(dm_base); } #if 0 /* Not used yet */ uint32_t uartmem_getbaseaddr(void) { return uart_board_param.uart_dm_base; } #endif /** * uart_tx_byte - transmits a character * @c: character to transmit */ void uart_tx_byte(int idx, unsigned char c) { msm_boot_uart_dm_write(&c, 1); } /** * uart_tx_flush - transmits a string of data * @s: string to transmit */ void uart_tx_flush(int idx) { unsigned int base = uart_board_param.uart_dm_base; while (!(readl_i(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) ; } /** * uart_can_rx_byte - checks if data available for reading * * Returns 1 if data available, 0 otherwise */ #if 0 /* Not used yet */ int uart_can_rx_byte(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; } #endif /** * ipq806x_serial_getc - reads a character * * Returns the character read from serial port. */ uint8_t uart_rx_byte(int idx) { uint8_t byte; #if 0 /* Not used yet */ while (!uart_can_rx_byte()) { /* wait for incoming data */ } #endif byte = (uint8_t)(word & 0xff); word = word >> 8; valid_data--; return byte; } #ifndef __PRE_RAM__ /* TODO: Implement fuction */ void uart_fill_lb(void *data) { } #endif