/** * @brief uart_tx_flush - transmits a string of data * @param idx: string to transmit */ void uart_tx_flush(int idx) { void *base = uart_board_param.uart_dm_base; while (!(read32(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) ; }
int uart_tstc(int port) { uint32_t base = port_lookup[port]; /* Don't do anything if UART is not initialized */ if (!uart_init_flag) return -1; return (readl(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_RXRDY); }
void uart_tx_byte(int idx, unsigned char data) { int num_of_chars = 1; void *base = uart_board_param.uart_dm_base; /* Wait until transmit FIFO is empty. */ while (!(read32(MSM_BOOT_UART_DM_SR(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) udelay(1); /* * TX FIFO is ready to accept new character(s). First write number of * characters to be transmitted. */ write32(MSM_BOOT_UART_DM_NO_CHARS_FOR_TX(base), num_of_chars); /* And now write the character(s) */ write32(MSM_BOOT_UART_DM_TF(base, 0), data); }
/* * UART transmit operation */ static unsigned int msm_boot_uart_dm_write(uint32_t base, 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(base)) & MSM_BOOT_UART_DM_SR_TXEMT)) { while (!(readl(MSM_BOOT_UART_DM_ISR(base)) & 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(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; }
/* * UART Receive operation * Reads a word from the RX FIFO. */ static unsigned int msm_boot_uart_dm_read(uint32_t base, 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(base)) & 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(base)) & MSM_BOOT_UART_DM_SR_UART_OVERRUN) { writel(MSM_BOOT_UART_DM_CMD_RESET_ERR_STAT, MSM_BOOT_UART_DM_CR(base)); } /* RX FIFO is ready; read a word. */ *data = readl(MSM_BOOT_UART_DM_RF(base, 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(base)) & 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(base)); } /* 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(base))) { /* 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(base)); } /* 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(base); rx_last_snap_count = 0; rx_chars_read_since_last_xfer = 0; 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; void *base; uint32_t status_reg; base = uart_board_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; }