/* Copyright (c) 2008-2018, 2020 The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ /* * SPI driver for Qualcomm MSM platforms * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "spi_qsd.h" #define SPI_MAX_BYTES_PER_WORD (4) static int msm_spi_pm_resume_runtime(struct device *device); static int msm_spi_pm_suspend_runtime(struct device *device); static inline void msm_spi_dma_unmap_buffers(struct msm_spi *dd); static int get_local_resources(struct msm_spi *dd); static void put_local_resources(struct msm_spi *dd); static inline int msm_spi_configure_gsbi(struct msm_spi *dd, struct platform_device *pdev) { struct resource *resource; unsigned long gsbi_mem_phys_addr; size_t gsbi_mem_size; void __iomem *gsbi_base; resource = platform_get_resource(pdev, IORESOURCE_MEM, 1); if (!resource) return 0; gsbi_mem_phys_addr = resource->start; gsbi_mem_size = resource_size(resource); if (!devm_request_mem_region(&pdev->dev, gsbi_mem_phys_addr, gsbi_mem_size, SPI_DRV_NAME)) return -ENXIO; gsbi_base = devm_ioremap(&pdev->dev, gsbi_mem_phys_addr, gsbi_mem_size); if (!gsbi_base) return -ENXIO; /* Set GSBI to SPI mode */ writel_relaxed(GSBI_SPI_CONFIG, gsbi_base + GSBI_CTRL_REG); return 0; } static inline void msm_spi_register_init(struct msm_spi *dd) { writel_relaxed(0x00000001, dd->base + SPI_SW_RESET); msm_spi_set_state(dd, SPI_OP_STATE_RESET); writel_relaxed(0x00000000, dd->base + SPI_OPERATIONAL); writel_relaxed(0x00000000, dd->base + SPI_CONFIG); writel_relaxed(0x00000000, dd->base + SPI_IO_MODES); if (dd->qup_ver) writel_relaxed(0x00000000, dd->base + QUP_OPERATIONAL_MASK); } static int msm_spi_pinctrl_init(struct msm_spi *dd) { dd->pinctrl = devm_pinctrl_get(dd->dev); if (IS_ERR_OR_NULL(dd->pinctrl)) { dev_err(dd->dev, "Failed to get pin ctrl\n"); return PTR_ERR(dd->pinctrl); } dd->pins_active = pinctrl_lookup_state(dd->pinctrl, SPI_PINCTRL_STATE_DEFAULT); if (IS_ERR_OR_NULL(dd->pins_active)) { dev_err(dd->dev, "Failed to lookup pinctrl default state\n"); return PTR_ERR(dd->pins_active); } dd->pins_sleep = pinctrl_lookup_state(dd->pinctrl, SPI_PINCTRL_STATE_SLEEP); if (IS_ERR_OR_NULL(dd->pins_sleep)) { dev_err(dd->dev, "Failed to lookup pinctrl sleep state\n"); return PTR_ERR(dd->pins_sleep); } return 0; } static inline int msm_spi_request_gpios(struct msm_spi *dd) { int i = 0; int result = 0; if (!dd->pdata->use_pinctrl) { for (i = 0; i < ARRAY_SIZE(spi_rsrcs); ++i) { if (dd->spi_gpios[i] >= 0) { result = gpio_request(dd->spi_gpios[i], spi_rsrcs[i]); if (result) { dev_err(dd->dev, "error %d gpio_request for pin %d\n", result, dd->spi_gpios[i]); goto error; } } } } else { result = pinctrl_select_state(dd->pinctrl, dd->pins_active); if (result) { dev_err(dd->dev, "%s: Can not set %s pins\n", __func__, SPI_PINCTRL_STATE_DEFAULT); goto error; } } return 0; error: if (!dd->pdata->use_pinctrl) { for (; --i >= 0;) { if (dd->spi_gpios[i] >= 0) gpio_free(dd->spi_gpios[i]); } } return result; } static inline void msm_spi_free_gpios(struct msm_spi *dd) { int i; int result = 0; if (!dd->pdata->use_pinctrl) { for (i = 0; i < ARRAY_SIZE(spi_rsrcs); ++i) { if (dd->spi_gpios[i] >= 0) gpio_free(dd->spi_gpios[i]); } for (i = 0; i < ARRAY_SIZE(spi_cs_rsrcs); ++i) { if (dd->cs_gpios[i].valid) { gpio_free(dd->cs_gpios[i].gpio_num); dd->cs_gpios[i].valid = 0; } } } else { result = pinctrl_select_state(dd->pinctrl, dd->pins_sleep); if (result) dev_err(dd->dev, "%s: Can not set %s pins\n", __func__, SPI_PINCTRL_STATE_SLEEP); } } static inline int msm_spi_request_cs_gpio(struct msm_spi *dd) { int cs_num; int rc; cs_num = dd->spi->chip_select; if (!(dd->spi->mode & SPI_LOOP)) { if (!dd->pdata->use_pinctrl) { if ((!(dd->cs_gpios[cs_num].valid)) && (dd->cs_gpios[cs_num].gpio_num >= 0)) { rc = gpio_request(dd->cs_gpios[cs_num].gpio_num, spi_cs_rsrcs[cs_num]); if (rc) { dev_err(dd->dev, "gpio_request for pin %d failed,error %d\n", dd->cs_gpios[cs_num].gpio_num, rc); return rc; } dd->cs_gpios[cs_num].valid = 1; } } } return 0; } static inline void msm_spi_free_cs_gpio(struct msm_spi *dd) { int cs_num; cs_num = dd->spi->chip_select; if (!dd->pdata->use_pinctrl) { if (dd->cs_gpios[cs_num].valid) { gpio_free(dd->cs_gpios[cs_num].gpio_num); dd->cs_gpios[cs_num].valid = 0; } } } /** * msm_spi_clk_max_rate: finds the nearest lower rate for a clk * @clk the clock for which to find nearest lower rate * @rate clock frequency in Hz * @return nearest lower rate or negative error value * * Public clock API extends clk_round_rate which is a ceiling function. This * function is a floor function implemented as a binary search using the * ceiling function. */ static long msm_spi_clk_max_rate(struct clk *clk, unsigned long rate) { long lowest_available, nearest_low, step_size, cur; long step_direction = -1; long guess = rate; int max_steps = 10; cur = clk_round_rate(clk, rate); if (cur == rate) return rate; /* if we got here then: cur > rate */ lowest_available = clk_round_rate(clk, 0); if (lowest_available > rate) return -EINVAL; step_size = (rate - lowest_available) >> 1; nearest_low = lowest_available; while (max_steps-- && step_size) { guess += step_size * step_direction; cur = clk_round_rate(clk, guess); if ((cur < rate) && (cur > nearest_low)) nearest_low = cur; /* * if we stepped too far, then start stepping in the other * direction with half the step size */ if (((cur > rate) && (step_direction > 0)) || ((cur < rate) && (step_direction < 0))) { step_direction = -step_direction; step_size >>= 1; } } return nearest_low; } static void msm_spi_clock_set(struct msm_spi *dd, int speed) { long rate; int rc; rate = msm_spi_clk_max_rate(dd->clk, speed); if (rate < 0) { dev_err(dd->dev, "%s: no match found for requested clock frequency:%d\n", __func__, speed); return; } rc = clk_set_rate(dd->clk, rate); if (!rc) dd->clock_speed = rate; } static void msm_spi_clk_path_vote(struct msm_spi *dd, u32 rate) { if (dd->bus_cl_hdl) { u64 ib = rate * dd->pdata->bus_width; msm_bus_scale_update_bw(dd->bus_cl_hdl, 0, ib); } } static void msm_spi_clk_path_teardown(struct msm_spi *dd) { msm_spi_clk_path_vote(dd, 0); if (dd->bus_cl_hdl) { msm_bus_scale_unregister(dd->bus_cl_hdl); dd->bus_cl_hdl = NULL; } } /** * msm_spi_clk_path_postponed_register: reg with bus-scaling after it is probed * * @return zero on success * * Workaround: SPI driver may be probed before the bus scaling driver. Calling * msm_bus_scale_register_client() will fail if the bus scaling driver is not * ready yet. Thus, this function should be called not from probe but from a * later context. Also, this function may be called more then once before * register succeed. At this case only one error message will be logged. At boot * time all clocks are on, so earlier SPI transactions should succeed. */ static int msm_spi_clk_path_postponed_register(struct msm_spi *dd) { int ret = 0; dd->bus_cl_hdl = msm_bus_scale_register(dd->pdata->master_id, MSM_BUS_SLAVE_EBI_CH0, (char *)dev_name(dd->dev), false); if (IS_ERR_OR_NULL(dd->bus_cl_hdl)) { ret = (dd->bus_cl_hdl ? PTR_ERR(dd->bus_cl_hdl) : -EAGAIN); dev_err(dd->dev, "Failed bus registration Err %d\n", ret); } return ret; } static void msm_spi_clk_path_init(struct msm_spi *dd) { /* * bail out if path voting is diabled (master_id == 0) or if it is * already registered (client_hdl != 0) */ if (!dd->pdata->master_id || dd->bus_cl_hdl) return; /* on failure try again later */ if (msm_spi_clk_path_postponed_register(dd)) return; } static int msm_spi_calculate_size(int *fifo_size, int *block_size, int block, int mult) { int words; switch (block) { case 0: words = 1; /* 4 bytes */ break; case 1: words = 4; /* 16 bytes */ break; case 2: words = 8; /* 32 bytes */ break; default: return -EINVAL; } switch (mult) { case 0: *fifo_size = words * 2; break; case 1: *fifo_size = words * 4; break; case 2: *fifo_size = words * 8; break; case 3: *fifo_size = words * 16; break; default: return -EINVAL; } *block_size = words * sizeof(u32); /* in bytes */ return 0; } static void msm_spi_calculate_fifo_size(struct msm_spi *dd) { u32 spi_iom; int block; int mult; spi_iom = readl_relaxed(dd->base + SPI_IO_MODES); block = (spi_iom & SPI_IO_M_INPUT_BLOCK_SIZE) >> INPUT_BLOCK_SZ_SHIFT; mult = (spi_iom & SPI_IO_M_INPUT_FIFO_SIZE) >> INPUT_FIFO_SZ_SHIFT; if (msm_spi_calculate_size(&dd->input_fifo_size, &dd->input_block_size, block, mult)) { goto fifo_size_err; } block = (spi_iom & SPI_IO_M_OUTPUT_BLOCK_SIZE) >> OUTPUT_BLOCK_SZ_SHIFT; mult = (spi_iom & SPI_IO_M_OUTPUT_FIFO_SIZE) >> OUTPUT_FIFO_SZ_SHIFT; if (msm_spi_calculate_size(&dd->output_fifo_size, &dd->output_block_size, block, mult)) { goto fifo_size_err; } if (dd->qup_ver == SPI_QUP_VERSION_NONE) { /* DM mode is not available for this block size */ if (dd->input_block_size == 4 || dd->output_block_size == 4) dd->use_dma = 0; if (dd->use_dma) { dd->input_burst_size = max(dd->input_block_size, DM_BURST_SIZE); dd->output_burst_size = max(dd->output_block_size, DM_BURST_SIZE); } } return; fifo_size_err: dd->use_dma = 0; pr_err("%s: invalid FIFO size, SPI_IO_MODES=0x%x\n", __func__, spi_iom); } static void msm_spi_read_word_from_fifo(struct msm_spi *dd) { u32 data_in; int i; int shift; int read_bytes = (dd->pack_words ? SPI_MAX_BYTES_PER_WORD : dd->bytes_per_word); data_in = readl_relaxed(dd->base + SPI_INPUT_FIFO); if (dd->read_buf) { for (i = 0; (i < read_bytes) && dd->rx_bytes_remaining; i++) { /* The data format depends on bytes_per_word: * 4 bytes: 0x12345678 * 3 bytes: 0x00123456 * 2 bytes: 0x00001234 * 1 byte : 0x00000012 */ shift = BITS_PER_BYTE * i; *dd->read_buf++ = (data_in & (0xFF << shift)) >> shift; dd->rx_bytes_remaining--; } } else { if (dd->rx_bytes_remaining >= read_bytes) dd->rx_bytes_remaining -= read_bytes; else dd->rx_bytes_remaining = 0; } dd->read_xfr_cnt++; } static inline bool msm_spi_is_valid_state(struct msm_spi *dd) { u32 spi_op = readl_relaxed(dd->base + SPI_STATE); return spi_op & SPI_OP_STATE_VALID; } static inline void msm_spi_udelay(unsigned int delay_usecs) { /* * For smaller values of delay, context switch time * would negate the usage of usleep */ if (delay_usecs > 20) usleep_range(delay_usecs, delay_usecs + 1); else if (delay_usecs) udelay(delay_usecs); } static inline int msm_spi_wait_valid(struct msm_spi *dd) { unsigned int delay = 0; unsigned long timeout = 0; if (dd->clock_speed == 0) return -EINVAL; /* * Based on the SPI clock speed, sufficient time * should be given for the SPI state transition * to occur */ delay = (10 * USEC_PER_SEC) / dd->clock_speed; /* * For small delay values, the default timeout would * be one jiffy */ if (delay < SPI_DELAY_THRESHOLD) delay = SPI_DELAY_THRESHOLD; /* Adding one to round off to the nearest jiffy */ timeout = jiffies + msecs_to_jiffies(delay * SPI_DEFAULT_TIMEOUT) + 1; while (!msm_spi_is_valid_state(dd)) { if (time_after(jiffies, timeout)) { if (!msm_spi_is_valid_state(dd)) { dev_err(dd->dev, "Invalid SPI operational state\n"); return -ETIMEDOUT; } else return 0; } msm_spi_udelay(delay); } return 0; } static inline int msm_spi_set_state(struct msm_spi *dd, enum msm_spi_state state) { enum msm_spi_state cur_state; if (msm_spi_wait_valid(dd)) return -EIO; cur_state = readl_relaxed(dd->base + SPI_STATE); /* Per spec: * For PAUSE_STATE to RESET_STATE, two writes of (10) are required */ if (((cur_state & SPI_OP_STATE) == SPI_OP_STATE_PAUSE) && (state == SPI_OP_STATE_RESET)) { writel_relaxed(SPI_OP_STATE_CLEAR_BITS, dd->base + SPI_STATE); writel_relaxed(SPI_OP_STATE_CLEAR_BITS, dd->base + SPI_STATE); } else { writel_relaxed((cur_state & ~SPI_OP_STATE) | state, dd->base + SPI_STATE); } if (msm_spi_wait_valid(dd)) return -EIO; return 0; } /** * msm_spi_set_bpw_and_no_io_flags: configure N, and no-input/no-output flags */ static inline void msm_spi_set_bpw_and_no_io_flags(struct msm_spi *dd, u32 *config, int n) { *config &= ~(SPI_NO_INPUT|SPI_NO_OUTPUT); if (n != (*config & SPI_CFG_N)) *config = (*config & ~SPI_CFG_N) | n; if (dd->tx_mode == SPI_BAM_MODE) { if (dd->read_buf == NULL) *config |= SPI_NO_INPUT; if (dd->write_buf == NULL) *config |= SPI_NO_OUTPUT; } } /** * msm_spi_calc_spi_config_loopback_and_input_first: Calculate the values that * should be updated into SPI_CONFIG's LOOPBACK and INPUT_FIRST flags * @return calculatd value for SPI_CONFIG */ static u32 msm_spi_calc_spi_config_loopback_and_input_first(u32 spi_config, u8 mode) { if (mode & SPI_LOOP) spi_config |= SPI_CFG_LOOPBACK; else spi_config &= ~SPI_CFG_LOOPBACK; if (mode & SPI_CPHA) spi_config &= ~SPI_CFG_INPUT_FIRST; else spi_config |= SPI_CFG_INPUT_FIRST; return spi_config; } /** * msm_spi_set_spi_config: prepares register SPI_CONFIG to process the * next transfer */ static void msm_spi_set_spi_config(struct msm_spi *dd, int bpw) { u32 spi_config = readl_relaxed(dd->base + SPI_CONFIG); spi_config = msm_spi_calc_spi_config_loopback_and_input_first( spi_config, dd->spi->mode); if (dd->qup_ver == SPI_QUP_VERSION_NONE) /* flags removed from SPI_CONFIG in QUP version-2 */ msm_spi_set_bpw_and_no_io_flags(dd, &spi_config, bpw-1); /* * HS_MODE improves signal stability for spi-clk high rates * but is invalid in LOOPBACK mode. */ if ((dd->clock_speed >= SPI_HS_MIN_RATE) && !(dd->spi->mode & SPI_LOOP)) spi_config |= SPI_CFG_HS_MODE; else spi_config &= ~SPI_CFG_HS_MODE; writel_relaxed(spi_config, dd->base + SPI_CONFIG); } /** * msm_spi_set_mx_counts: set SPI_MX_INPUT_COUNT and SPI_MX_INPUT_COUNT * for FIFO-mode. set SPI_MX_INPUT_COUNT and SPI_MX_OUTPUT_COUNT for * BAM and DMOV modes. * @n_words The number of reads/writes of size N. */ static void msm_spi_set_mx_counts(struct msm_spi *dd, u32 n_words) { /* * For FIFO mode: * - Set the MX_OUTPUT_COUNT/MX_INPUT_COUNT registers to 0 * - Set the READ/WRITE_COUNT registers to 0 (infinite mode) * or num bytes (finite mode) if less than fifo worth of data. * For Block mode: * - Set the MX_OUTPUT/MX_INPUT_COUNT registers to num xfer bytes. * - Set the READ/WRITE_COUNT registers to 0. */ if (dd->tx_mode != SPI_BAM_MODE) { if (dd->tx_mode == SPI_FIFO_MODE) { if (n_words <= dd->input_fifo_size) msm_spi_set_write_count(dd, n_words); else msm_spi_set_write_count(dd, 0); writel_relaxed(0, dd->base + SPI_MX_OUTPUT_COUNT); } else writel_relaxed(n_words, dd->base + SPI_MX_OUTPUT_COUNT); if (dd->rx_mode == SPI_FIFO_MODE) { if (n_words <= dd->input_fifo_size) writel_relaxed(n_words, dd->base + SPI_MX_READ_COUNT); else writel_relaxed(0, dd->base + SPI_MX_READ_COUNT); writel_relaxed(0, dd->base + SPI_MX_INPUT_COUNT); } else writel_relaxed(n_words, dd->base + SPI_MX_INPUT_COUNT); } else { /* must be zero for BAM and DMOV */ writel_relaxed(0, dd->base + SPI_MX_READ_COUNT); msm_spi_set_write_count(dd, 0); /* * for DMA transfers, both QUP_MX_INPUT_COUNT and * QUP_MX_OUTPUT_COUNT must be zero to all cases but one. * That case is a non-balanced transfer when there is * only a read_buf. */ if (dd->qup_ver == SPI_QUP_VERSION_BFAM) { if (dd->write_buf) writel_relaxed(0, dd->base + SPI_MX_INPUT_COUNT); else writel_relaxed(n_words, dd->base + SPI_MX_INPUT_COUNT); writel_relaxed(0, dd->base + SPI_MX_OUTPUT_COUNT); } } } static int msm_spi_bam_pipe_disconnect(struct msm_spi *dd, struct msm_spi_bam_pipe *pipe) { int ret = sps_disconnect(pipe->handle); if (ret) { dev_dbg(dd->dev, "%s disconnect bam %s pipe failed\n", __func__, pipe->name); return ret; } return 0; } static int msm_spi_bam_pipe_connect(struct msm_spi *dd, struct msm_spi_bam_pipe *pipe, struct sps_connect *config) { int ret; struct sps_register_event event = { .mode = SPS_TRIGGER_WAIT, .options = SPS_O_EOT, }; if (pipe == &dd->bam.prod) event.xfer_done = &dd->rx_transfer_complete; else if (pipe == &dd->bam.cons) event.xfer_done = &dd->tx_transfer_complete; ret = sps_connect(pipe->handle, config); if (ret) { dev_err(dd->dev, "%s: sps_connect(%s:0x%pK):%d\n", __func__, pipe->name, pipe->handle, ret); return ret; } ret = sps_register_event(pipe->handle, &event); if (ret) { dev_err(dd->dev, "%s sps_register_event(hndl:0x%pK %s):%d\n", __func__, pipe->handle, pipe->name, ret); msm_spi_bam_pipe_disconnect(dd, pipe); return ret; } pipe->teardown_required = true; return 0; } static void msm_spi_bam_pipe_flush(struct msm_spi *dd, enum msm_spi_pipe_direction pipe_dir) { struct msm_spi_bam_pipe *pipe = (pipe_dir == SPI_BAM_CONSUMER_PIPE) ? (&dd->bam.prod) : (&dd->bam.cons); struct sps_connect config = pipe->config; int ret; ret = msm_spi_bam_pipe_disconnect(dd, pipe); if (ret) return; ret = msm_spi_bam_pipe_connect(dd, pipe, &config); if (ret) return; } static void msm_spi_bam_flush(struct msm_spi *dd) { dev_dbg(dd->dev, "%s flushing bam for recovery\n", __func__); msm_spi_bam_pipe_flush(dd, SPI_BAM_CONSUMER_PIPE); msm_spi_bam_pipe_flush(dd, SPI_BAM_PRODUCER_PIPE); } static int msm_spi_bam_process_rx(struct msm_spi *dd, u32 *bytes_to_send, u32 desc_cnt) { int ret = 0; u32 data_xfr_size = 0, rem_bc = 0; u32 prod_flags = 0; rem_bc = dd->cur_rx_transfer->len - dd->bam.curr_rx_bytes_recvd; data_xfr_size = (rem_bc < *bytes_to_send) ? rem_bc : *bytes_to_send; /* * set flags for last descriptor only */ if ((desc_cnt == 1) || (*bytes_to_send == data_xfr_size)) prod_flags = (dd->write_buf) ? 0 : (SPS_IOVEC_FLAG_EOT | SPS_IOVEC_FLAG_NWD); /* * enqueue read buffer in BAM */ ret = sps_transfer_one(dd->bam.prod.handle, dd->cur_rx_transfer->rx_dma + dd->bam.curr_rx_bytes_recvd, data_xfr_size, dd, prod_flags); if (ret < 0) { dev_err(dd->dev, "%s: Failed to queue producer BAM transfer\n", __func__); return ret; } dd->bam.curr_rx_bytes_recvd += data_xfr_size; *bytes_to_send -= data_xfr_size; dd->bam.bam_rx_len -= data_xfr_size; return data_xfr_size; } static int msm_spi_bam_process_tx(struct msm_spi *dd, u32 *bytes_to_send, u32 desc_cnt) { int ret = 0; u32 data_xfr_size = 0, rem_bc = 0; u32 cons_flags = 0; rem_bc = dd->cur_tx_transfer->len - dd->bam.curr_tx_bytes_sent; data_xfr_size = (rem_bc < *bytes_to_send) ? rem_bc : *bytes_to_send; /* * set flags for last descriptor only */ if ((desc_cnt == 1) || (*bytes_to_send == data_xfr_size)) cons_flags = SPS_IOVEC_FLAG_EOT | SPS_IOVEC_FLAG_NWD; /* * enqueue write buffer in BAM */ ret = sps_transfer_one(dd->bam.cons.handle, dd->cur_tx_transfer->tx_dma + dd->bam.curr_tx_bytes_sent, data_xfr_size, dd, cons_flags); if (ret < 0) { dev_err(dd->dev, "%s: Failed to queue consumer BAM transfer\n", __func__); return ret; } dd->bam.curr_tx_bytes_sent += data_xfr_size; *bytes_to_send -= data_xfr_size; dd->bam.bam_tx_len -= data_xfr_size; return data_xfr_size; } /** * msm_spi_bam_begin_transfer: transfer dd->tx_bytes_remaining bytes * using BAM. * @brief BAM can transfer SPI_MAX_TRFR_BTWN_RESETS byte at a single * transfer. Between transfer QUP must change to reset state. A loop is * issuing a single BAM transfer at a time. * @return zero on success */ static int msm_spi_bam_begin_transfer(struct msm_spi *dd) { u32 tx_bytes_to_send = 0, rx_bytes_to_recv = 0; u32 n_words_xfr; s32 ret = 0; u32 prod_desc_cnt = SPI_BAM_MAX_DESC_NUM - 1; u32 cons_desc_cnt = SPI_BAM_MAX_DESC_NUM - 1; u32 byte_count = 0; rx_bytes_to_recv = min_t(u32, dd->bam.bam_rx_len, SPI_MAX_TRFR_BTWN_RESETS); tx_bytes_to_send = min_t(u32, dd->bam.bam_tx_len, SPI_MAX_TRFR_BTWN_RESETS); n_words_xfr = DIV_ROUND_UP(rx_bytes_to_recv, dd->bytes_per_word); msm_spi_set_mx_counts(dd, n_words_xfr); ret = msm_spi_set_state(dd, SPI_OP_STATE_RUN); if (ret < 0) { dev_err(dd->dev, "%s: Failed to set QUP state to run\n", __func__); goto xfr_err; } while ((rx_bytes_to_recv + tx_bytes_to_send) && ((cons_desc_cnt + prod_desc_cnt) > 0)) { struct spi_transfer *t = NULL; if (dd->read_buf && (prod_desc_cnt > 0)) { ret = msm_spi_bam_process_rx(dd, &rx_bytes_to_recv, prod_desc_cnt); if (ret < 0) goto xfr_err; if (!(dd->cur_rx_transfer->len - dd->bam.curr_rx_bytes_recvd)) t = dd->cur_rx_transfer; prod_desc_cnt--; } if (dd->write_buf && (cons_desc_cnt > 0)) { ret = msm_spi_bam_process_tx(dd, &tx_bytes_to_send, cons_desc_cnt); if (ret < 0) goto xfr_err; if (!(dd->cur_tx_transfer->len - dd->bam.curr_tx_bytes_sent)) t = dd->cur_tx_transfer; cons_desc_cnt--; } byte_count += ret; } dd->tx_bytes_remaining -= min_t(u32, byte_count, SPI_MAX_TRFR_BTWN_RESETS); return 0; xfr_err: return ret; } static int msm_spi_bam_next_transfer(struct msm_spi *dd) { if (dd->tx_mode != SPI_BAM_MODE) return 0; if (dd->tx_bytes_remaining > 0) { if (msm_spi_set_state(dd, SPI_OP_STATE_RESET)) return 0; if ((msm_spi_bam_begin_transfer(dd)) < 0) { dev_err(dd->dev, "%s: BAM transfer setup failed\n", __func__); return 0; } return 1; } return 0; } static int msm_spi_dma_send_next(struct msm_spi *dd) { int ret = 0; if (dd->tx_mode == SPI_BAM_MODE) ret = msm_spi_bam_next_transfer(dd); return ret; } static inline void msm_spi_ack_transfer(struct msm_spi *dd) { writel_relaxed(SPI_OP_MAX_INPUT_DONE_FLAG | SPI_OP_MAX_OUTPUT_DONE_FLAG, dd->base + SPI_OPERATIONAL); /* Ensure done flag was cleared before proceeding further */ mb(); } /* Figure which irq occurred and call the relevant functions */ static inline irqreturn_t msm_spi_qup_irq(int irq, void *dev_id) { u32 op, ret = IRQ_NONE; struct msm_spi *dd = dev_id; if (pm_runtime_suspended(dd->dev)) { dev_warn(dd->dev, "QUP: pm runtime suspend, irq:%d\n", irq); return ret; } if (readl_relaxed(dd->base + SPI_ERROR_FLAGS) || readl_relaxed(dd->base + QUP_ERROR_FLAGS)) { struct spi_master *master = dev_get_drvdata(dd->dev); ret |= msm_spi_error_irq(irq, master); } op = readl_relaxed(dd->base + SPI_OPERATIONAL); writel_relaxed(op, dd->base + SPI_OPERATIONAL); /* * Ensure service flag was cleared before further * processing of interrupt. */ mb(); if (op & SPI_OP_INPUT_SERVICE_FLAG) ret |= msm_spi_input_irq(irq, dev_id); if (op & SPI_OP_OUTPUT_SERVICE_FLAG) ret |= msm_spi_output_irq(irq, dev_id); if (dd->tx_mode != SPI_BAM_MODE) { if (!dd->rx_done) { if (dd->rx_bytes_remaining == 0) dd->rx_done = true; } if (!dd->tx_done) { if (!dd->tx_bytes_remaining && (op & SPI_OP_IP_FIFO_NOT_EMPTY)) { dd->tx_done = true; } } } if (dd->tx_done && dd->rx_done) { msm_spi_set_state(dd, SPI_OP_STATE_RESET); dd->tx_done = false; dd->rx_done = false; complete(&dd->rx_transfer_complete); complete(&dd->tx_transfer_complete); } return ret; } static irqreturn_t msm_spi_input_irq(int irq, void *dev_id) { struct msm_spi *dd = dev_id; dd->stat_rx++; if (dd->rx_mode == SPI_MODE_NONE) return IRQ_HANDLED; if (dd->rx_mode == SPI_FIFO_MODE) { while ((readl_relaxed(dd->base + SPI_OPERATIONAL) & SPI_OP_IP_FIFO_NOT_EMPTY) && (dd->rx_bytes_remaining > 0)) { msm_spi_read_word_from_fifo(dd); } } else if (dd->rx_mode == SPI_BLOCK_MODE) { int count = 0; while (dd->rx_bytes_remaining && (count < dd->input_block_size)) { msm_spi_read_word_from_fifo(dd); count += SPI_MAX_BYTES_PER_WORD; } } return IRQ_HANDLED; } static void msm_spi_write_word_to_fifo(struct msm_spi *dd) { u32 word; u8 byte; int i; int write_bytes = (dd->pack_words ? SPI_MAX_BYTES_PER_WORD : dd->bytes_per_word); word = 0; if (dd->write_buf) { for (i = 0; (i < write_bytes) && dd->tx_bytes_remaining; i++) { dd->tx_bytes_remaining--; byte = *dd->write_buf++; word |= (byte << (BITS_PER_BYTE * i)); } } else if (dd->tx_bytes_remaining > write_bytes) dd->tx_bytes_remaining -= write_bytes; else dd->tx_bytes_remaining = 0; dd->write_xfr_cnt++; writel_relaxed(word, dd->base + SPI_OUTPUT_FIFO); } static inline void msm_spi_write_rmn_to_fifo(struct msm_spi *dd) { int count = 0; if (dd->tx_mode == SPI_FIFO_MODE) { while ((dd->tx_bytes_remaining > 0) && (count < dd->input_fifo_size) && !(readl_relaxed(dd->base + SPI_OPERATIONAL) & SPI_OP_OUTPUT_FIFO_FULL)) { msm_spi_write_word_to_fifo(dd); count++; } } if (dd->tx_mode == SPI_BLOCK_MODE) { while (dd->tx_bytes_remaining && (count < dd->output_block_size)) { msm_spi_write_word_to_fifo(dd); count += SPI_MAX_BYTES_PER_WORD; } } } static irqreturn_t msm_spi_output_irq(int irq, void *dev_id) { struct msm_spi *dd = dev_id; dd->stat_tx++; if (dd->tx_mode == SPI_MODE_NONE) return IRQ_HANDLED; /* Output FIFO is empty. Transmit any outstanding write data. */ if ((dd->tx_mode == SPI_FIFO_MODE) || (dd->tx_mode == SPI_BLOCK_MODE)) msm_spi_write_rmn_to_fifo(dd); return IRQ_HANDLED; } static irqreturn_t msm_spi_error_irq(int irq, void *dev_id) { struct spi_master *master = dev_id; struct msm_spi *dd = spi_master_get_devdata(master); u32 spi_err; spi_err = readl_relaxed(dd->base + SPI_ERROR_FLAGS); if (spi_err & SPI_ERR_OUTPUT_OVER_RUN_ERR) dev_warn(master->dev.parent, "SPI output overrun error\n"); if (spi_err & SPI_ERR_INPUT_UNDER_RUN_ERR) dev_warn(master->dev.parent, "SPI input underrun error\n"); if (spi_err & SPI_ERR_OUTPUT_UNDER_RUN_ERR) dev_warn(master->dev.parent, "SPI output underrun error\n"); msm_spi_get_clk_err(dd, &spi_err); if (spi_err & SPI_ERR_CLK_OVER_RUN_ERR) dev_warn(master->dev.parent, "SPI clock overrun error\n"); if (spi_err & SPI_ERR_CLK_UNDER_RUN_ERR) dev_warn(master->dev.parent, "SPI clock underrun error\n"); msm_spi_clear_error_flags(dd); msm_spi_ack_clk_err(dd); /* Ensure clearing of QUP_ERROR_FLAGS was completed */ mb(); return IRQ_HANDLED; } static int msm_spi_bam_map_buffers(struct msm_spi *dd) { int ret = -EINVAL; struct device *dev; struct spi_transfer *xfr; void *tx_buf, *rx_buf; u32 tx_len, rx_len; dev = dd->dev; xfr = dd->cur_transfer; tx_buf = (void *)xfr->tx_buf; rx_buf = xfr->rx_buf; tx_len = rx_len = xfr->len; if (tx_buf != NULL) { xfr->tx_dma = dma_map_single(dev, tx_buf, tx_len, DMA_TO_DEVICE); if (dma_mapping_error(dev, xfr->tx_dma)) { ret = -ENOMEM; goto error; } } if (rx_buf != NULL) { xfr->rx_dma = dma_map_single(dev, rx_buf, rx_len, DMA_FROM_DEVICE); if (dma_mapping_error(dev, xfr->rx_dma)) { if (tx_buf != NULL) dma_unmap_single(dev, xfr->tx_dma, tx_len, DMA_TO_DEVICE); ret = -ENOMEM; goto error; } } return 0; error: msm_spi_dma_unmap_buffers(dd); return ret; } static int msm_spi_dma_map_buffers(struct msm_spi *dd) { int ret = 0; if (dd->tx_mode == SPI_BAM_MODE) ret = msm_spi_bam_map_buffers(dd); return ret; } static void msm_spi_bam_unmap_buffers(struct msm_spi *dd) { struct device *dev; struct spi_transfer *xfr; void *tx_buf, *rx_buf; u32 tx_len, rx_len; dev = dd->dev; xfr = dd->cur_transfer; tx_buf = (void *)xfr->tx_buf; rx_buf = xfr->rx_buf; tx_len = rx_len = xfr->len; if (tx_buf != NULL) dma_unmap_single(dev, xfr->tx_dma, tx_len, DMA_TO_DEVICE); if (rx_buf != NULL) dma_unmap_single(dev, xfr->rx_dma, rx_len, DMA_FROM_DEVICE); } static inline void msm_spi_dma_unmap_buffers(struct msm_spi *dd) { if (dd->tx_mode == SPI_BAM_MODE) msm_spi_bam_unmap_buffers(dd); } /** * msm_spi_use_dma - decides whether to use Data-Mover or BAM for * the given transfer * @dd: device * @tr: transfer * * Start using DMA if: * 1. Is supported by HW * 2. Is not diabled by platform data * 3. Transfer size is greater than 3*block size. * 4. Buffers are aligned to cache line. * 5. Bytes-per-word is 8,16 or 32. */ static inline bool msm_spi_use_dma(struct msm_spi *dd, struct spi_transfer *tr, u8 bpw) { if (!dd->use_dma) return false; /* check constraints from platform data */ if ((dd->qup_ver == SPI_QUP_VERSION_BFAM) && !dd->pdata->use_bam) return false; if (dd->cur_msg_len < 3*dd->input_block_size) return false; if ((dd->qup_ver != SPI_QUP_VERSION_BFAM) && !dd->read_len && !dd->write_len) return false; if (dd->qup_ver == SPI_QUP_VERSION_NONE) { u32 cache_line = dma_get_cache_alignment(); if (tr->tx_buf) { if (!IS_ALIGNED((size_t)tr->tx_buf, cache_line)) return 0; } if (tr->rx_buf) { if (!IS_ALIGNED((size_t)tr->rx_buf, cache_line)) return false; } if (tr->cs_change && ((bpw != 8) && (bpw != 16) && (bpw != 32))) return false; } return true; } /** * msm_spi_set_transfer_mode: Chooses optimal transfer mode. Sets dd->mode and * prepares to process a transfer. */ static void msm_spi_set_transfer_mode(struct msm_spi *dd, u8 bpw, u32 read_count) { if (msm_spi_use_dma(dd, dd->cur_transfer, bpw)) { dd->tx_mode = SPI_BAM_MODE; dd->rx_mode = SPI_BAM_MODE; } else { dd->rx_mode = SPI_FIFO_MODE; dd->tx_mode = SPI_FIFO_MODE; dd->read_len = dd->cur_transfer->len; dd->write_len = dd->cur_transfer->len; } } /** * msm_spi_set_qup_io_modes: prepares register QUP_IO_MODES to process a * transfer */ static void msm_spi_set_qup_io_modes(struct msm_spi *dd) { u32 spi_iom; spi_iom = readl_relaxed(dd->base + SPI_IO_MODES); /* Set input and output transfer mode: FIFO, DMOV, or BAM */ spi_iom &= ~(SPI_IO_M_INPUT_MODE | SPI_IO_M_OUTPUT_MODE); spi_iom = (spi_iom | (dd->tx_mode << OUTPUT_MODE_SHIFT)); spi_iom = (spi_iom | (dd->rx_mode << INPUT_MODE_SHIFT)); /* Always enable packing for the BAM mode and for non BAM mode only * if bpw is % 8 and transfer length is % 4 Bytes. */ if (dd->tx_mode == SPI_BAM_MODE || ((dd->cur_msg_len % SPI_MAX_BYTES_PER_WORD == 0) && (dd->cur_transfer->bits_per_word) && (dd->cur_transfer->bits_per_word <= 32) && (dd->cur_transfer->bits_per_word % 8 == 0))) { spi_iom |= SPI_IO_M_PACK_EN | SPI_IO_M_UNPACK_EN; dd->pack_words = true; } else { spi_iom &= ~(SPI_IO_M_PACK_EN | SPI_IO_M_UNPACK_EN); spi_iom |= SPI_IO_M_OUTPUT_BIT_SHIFT_EN; dd->pack_words = false; } writel_relaxed(spi_iom, dd->base + SPI_IO_MODES); } static u32 msm_spi_calc_spi_ioc_clk_polarity(u32 spi_ioc, u8 mode) { if (mode & SPI_CPOL) spi_ioc |= SPI_IO_C_CLK_IDLE_HIGH; else spi_ioc &= ~SPI_IO_C_CLK_IDLE_HIGH; return spi_ioc; } /** * msm_spi_set_spi_io_control: prepares register SPI_IO_CONTROL to process the * next transfer * @return the new set value of SPI_IO_CONTROL */ static u32 msm_spi_set_spi_io_control(struct msm_spi *dd) { u32 spi_ioc, spi_ioc_orig, chip_select; spi_ioc = readl_relaxed(dd->base + SPI_IO_CONTROL); spi_ioc_orig = spi_ioc; spi_ioc = msm_spi_calc_spi_ioc_clk_polarity(spi_ioc , dd->spi->mode); /* Set chip-select */ chip_select = dd->spi->chip_select << 2; if ((spi_ioc & SPI_IO_C_CS_SELECT) != chip_select) spi_ioc = (spi_ioc & ~SPI_IO_C_CS_SELECT) | chip_select; if (!dd->cur_transfer->cs_change) spi_ioc |= SPI_IO_C_MX_CS_MODE; if (spi_ioc != spi_ioc_orig) writel_relaxed(spi_ioc, dd->base + SPI_IO_CONTROL); /* * Ensure that the IO control mode register gets written * before proceeding with the transfer. */ mb(); return spi_ioc; } /** * msm_spi_set_qup_op_mask: prepares register QUP_OPERATIONAL_MASK to process * the next transfer */ static void msm_spi_set_qup_op_mask(struct msm_spi *dd) { /* mask INPUT and OUTPUT service flags in to prevent IRQs on FIFO status * change in BAM mode */ u32 mask = (dd->tx_mode == SPI_BAM_MODE) ? QUP_OP_MASK_OUTPUT_SERVICE_FLAG | QUP_OP_MASK_INPUT_SERVICE_FLAG : 0; writel_relaxed(mask, dd->base + QUP_OPERATIONAL_MASK); } static void get_transfer_length(struct msm_spi *dd) { struct spi_transfer *xfer = dd->cur_transfer; dd->cur_msg_len = 0; dd->read_len = dd->write_len = 0; dd->bam.bam_tx_len = dd->bam.bam_rx_len = 0; if (xfer->tx_buf) dd->bam.bam_tx_len = dd->write_len = xfer->len; if (xfer->rx_buf) dd->bam.bam_rx_len = dd->read_len = xfer->len; dd->cur_msg_len = xfer->len; } static int msm_spi_process_transfer(struct msm_spi *dd) { u8 bpw; u32 max_speed; u32 read_count; u32 timeout; u32 spi_ioc; u32 int_loopback = 0; int ret; int status = 0; get_transfer_length(dd); dd->cur_tx_transfer = dd->cur_transfer; dd->cur_rx_transfer = dd->cur_transfer; dd->bam.curr_rx_bytes_recvd = dd->bam.curr_tx_bytes_sent = 0; dd->write_xfr_cnt = dd->read_xfr_cnt = 0; dd->tx_bytes_remaining = dd->cur_msg_len; dd->rx_bytes_remaining = dd->cur_msg_len; dd->read_buf = dd->cur_transfer->rx_buf; dd->write_buf = dd->cur_transfer->tx_buf; dd->tx_done = false; dd->rx_done = false; init_completion(&dd->tx_transfer_complete); init_completion(&dd->rx_transfer_complete); if (dd->cur_transfer->bits_per_word) bpw = dd->cur_transfer->bits_per_word; else bpw = 8; dd->bytes_per_word = (bpw + 7) / 8; if (dd->cur_transfer->speed_hz) max_speed = dd->cur_transfer->speed_hz; else max_speed = dd->spi->max_speed_hz; if (!dd->clock_speed || max_speed != dd->clock_speed) msm_spi_clock_set(dd, max_speed); timeout = 100 * msecs_to_jiffies( DIV_ROUND_UP(dd->cur_msg_len * 8, DIV_ROUND_UP(max_speed, MSEC_PER_SEC))); read_count = DIV_ROUND_UP(dd->cur_msg_len, dd->bytes_per_word); if (dd->spi->mode & SPI_LOOP) int_loopback = 1; ret = msm_spi_set_state(dd, SPI_OP_STATE_RESET); if (ret < 0) { dev_err(dd->dev, "%s: Error setting QUP to reset-state\n", __func__); return ret; } msm_spi_set_transfer_mode(dd, bpw, read_count); msm_spi_set_mx_counts(dd, read_count); if (dd->tx_mode == SPI_BAM_MODE) { ret = msm_spi_dma_map_buffers(dd); if (ret < 0) { pr_err("%s(): Error Mapping DMA buffers\n", __func__); dd->tx_mode = SPI_MODE_NONE; dd->rx_mode = SPI_MODE_NONE; return ret; } } msm_spi_set_qup_io_modes(dd); msm_spi_set_spi_config(dd, bpw); msm_spi_set_qup_config(dd, bpw); spi_ioc = msm_spi_set_spi_io_control(dd); msm_spi_set_qup_op_mask(dd); /* The output fifo interrupt handler will handle all writes after * the first. Restricting this to one write avoids contention * issues and race conditions between this thread and the int handler */ if (dd->tx_mode != SPI_BAM_MODE) { if (msm_spi_prepare_for_write(dd)) goto transfer_end; msm_spi_start_write(dd, read_count); } else { if ((msm_spi_bam_begin_transfer(dd)) < 0) { dev_err(dd->dev, "%s: BAM transfer setup failed\n", __func__); status = -EIO; goto transfer_end; } } /* * On BAM mode, current state here is run. * Only enter the RUN state after the first word is written into * the output FIFO. Otherwise, the output FIFO EMPTY interrupt * might fire before the first word is written resulting in a * possible race condition. */ if (dd->tx_mode != SPI_BAM_MODE) if (msm_spi_set_state(dd, SPI_OP_STATE_RUN)) { dev_warn(dd->dev, "%s: Failed to set QUP to run-state. Mode:%d\n", __func__, dd->tx_mode); goto transfer_end; } /* Assume success, this might change later upon transaction result */ do { if (dd->write_buf && !wait_for_completion_timeout(&dd->tx_transfer_complete, timeout)) { dev_err(dd->dev, "%s: SPI Tx transaction timeout\n", __func__); status = -EIO; break; } if (dd->read_buf && !wait_for_completion_timeout(&dd->rx_transfer_complete, timeout)) { dev_err(dd->dev, "%s: SPI Rx transaction timeout\n", __func__); status = -EIO; break; } } while (msm_spi_dma_send_next(dd)); msm_spi_udelay(dd->xfrs_delay_usec); transfer_end: if ((dd->tx_mode == SPI_BAM_MODE) && status) msm_spi_bam_flush(dd); msm_spi_dma_unmap_buffers(dd); dd->tx_mode = SPI_MODE_NONE; dd->rx_mode = SPI_MODE_NONE; msm_spi_set_state(dd, SPI_OP_STATE_RESET); if (!dd->cur_transfer->cs_change) writel_relaxed(spi_ioc & ~SPI_IO_C_MX_CS_MODE, dd->base + SPI_IO_CONTROL); return status; } static inline void msm_spi_set_cs(struct spi_device *spi, bool set_flag) { struct msm_spi *dd = spi_master_get_devdata(spi->master); u32 spi_ioc; u32 spi_ioc_orig; int rc = 0; rc = pm_runtime_get_sync(dd->dev); if (rc < 0) { dev_err(dd->dev, "Failure during runtime get,rc=%d\n", rc); return; } if (dd->pdata->is_shared) { rc = get_local_resources(dd); if (rc) return; } msm_spi_clk_path_vote(dd, spi->max_speed_hz); if (!(spi->mode & SPI_CS_HIGH)) set_flag = !set_flag; /* Serve only under mutex lock as RT suspend may cause a race */ mutex_lock(&dd->core_lock); if (dd->suspended) { dev_err(dd->dev, "%s: SPI operational state=%d Invalid\n", __func__, dd->suspended); mutex_unlock(&dd->core_lock); return; } spi_ioc = readl_relaxed(dd->base + SPI_IO_CONTROL); spi_ioc_orig = spi_ioc; if (set_flag) spi_ioc |= SPI_IO_C_FORCE_CS; else spi_ioc &= ~SPI_IO_C_FORCE_CS; if (spi_ioc != spi_ioc_orig) writel_relaxed(spi_ioc, dd->base + SPI_IO_CONTROL); if (dd->pdata->is_shared) put_local_resources(dd); mutex_unlock(&dd->core_lock); pm_runtime_mark_last_busy(dd->dev); pm_runtime_put_autosuspend(dd->dev); } static void reset_core(struct msm_spi *dd) { u32 spi_ioc; msm_spi_register_init(dd); /* * The SPI core generates a bogus input overrun error on some targets, * when a transition from run to reset state occurs and if the FIFO has * an odd number of entries. Hence we disable the INPUT_OVER_RUN_ERR_EN * bit. */ msm_spi_enable_error_flags(dd); spi_ioc = readl_relaxed(dd->base + SPI_IO_CONTROL); spi_ioc |= SPI_IO_C_NO_TRI_STATE; writel_relaxed(spi_ioc, dd->base + SPI_IO_CONTROL); /* * Ensure that the IO control is written to before returning. */ mb(); msm_spi_set_state(dd, SPI_OP_STATE_RESET); } static void put_local_resources(struct msm_spi *dd) { msm_spi_disable_irqs(dd); clk_disable_unprepare(dd->clk); dd->clock_speed = 0; clk_disable_unprepare(dd->pclk); /* Free the spi clk, miso, mosi, cs gpio */ if (dd->pdata && dd->pdata->gpio_release) dd->pdata->gpio_release(); msm_spi_free_gpios(dd); } static int get_local_resources(struct msm_spi *dd) { int ret = -EINVAL; /* Configure the spi clk, miso, mosi and cs gpio */ if (dd->pdata->gpio_config) { ret = dd->pdata->gpio_config(); if (ret) { dev_err(dd->dev, "%s: error configuring GPIOs\n", __func__); return ret; } } ret = msm_spi_request_gpios(dd); if (ret) return ret; ret = clk_prepare_enable(dd->clk); if (ret) goto clk0_err; ret = clk_prepare_enable(dd->pclk); if (ret) goto clk1_err; msm_spi_enable_irqs(dd); return 0; clk1_err: clk_disable_unprepare(dd->clk); clk0_err: msm_spi_free_gpios(dd); return ret; } /** * msm_spi_transfer_one: To process one spi transfer at a time * @master: spi master controller reference * @msg: one multi-segment SPI transaction * @return zero on success or negative error value * */ static int msm_spi_transfer_one(struct spi_master *master, struct spi_device *spi, struct spi_transfer *xfer) { struct msm_spi *dd; unsigned long flags; u32 status_error = 0; dd = spi_master_get_devdata(master); /* Check message parameters */ if (xfer->speed_hz > dd->pdata->max_clock_speed || (xfer->bits_per_word && (xfer->bits_per_word < 4 || xfer->bits_per_word > 32)) || (xfer->tx_buf == NULL && xfer->rx_buf == NULL)) { dev_err(dd->dev, "Invalid transfer: %d Hz, %d bpw tx=%pK, rx=%pK\n", xfer->speed_hz, xfer->bits_per_word, xfer->tx_buf, xfer->rx_buf); return -EINVAL; } dd->spi = spi; dd->cur_transfer = xfer; mutex_lock(&dd->core_lock); spin_lock_irqsave(&dd->queue_lock, flags); dd->transfer_pending = 1; spin_unlock_irqrestore(&dd->queue_lock, flags); /* * get local resources for each transfer to ensure we're in a good * state and not interfering with other EE's using this device */ if (dd->pdata->is_shared) { if (get_local_resources(dd)) { mutex_unlock(&dd->core_lock); spi_finalize_current_message(master); return -EINVAL; } reset_core(dd); if (dd->use_dma) { msm_spi_bam_pipe_connect(dd, &dd->bam.prod, &dd->bam.prod.config); msm_spi_bam_pipe_connect(dd, &dd->bam.cons, &dd->bam.cons.config); } } if (dd->suspended || !msm_spi_is_valid_state(dd)) { dev_err(dd->dev, "%s: SPI operational state not valid\n", __func__); status_error = 1; } if (!status_error) status_error = msm_spi_process_transfer(dd); spin_lock_irqsave(&dd->queue_lock, flags); dd->transfer_pending = 0; spin_unlock_irqrestore(&dd->queue_lock, flags); /* * Put local resources prior to calling finalize to ensure the hw * is in a known state before notifying the calling thread (which is a * different context since we're running in the spi kthread here) to * prevent race conditions between us and any other EE's using this hw. */ if (dd->pdata->is_shared) { if (dd->use_dma) { msm_spi_bam_pipe_disconnect(dd, &dd->bam.prod); msm_spi_bam_pipe_disconnect(dd, &dd->bam.cons); } put_local_resources(dd); } mutex_unlock(&dd->core_lock); if (dd->suspended) wake_up_interruptible(&dd->continue_suspend); return status_error; } static int msm_spi_pm_get_sync(struct device *dev) { int ret; /* * Counter-part of system-suspend when runtime-pm is not enabled. * This way, resume can be left empty and device will be put in * active mode only if client requests anything on the bus */ if (!pm_runtime_enabled(dev)) { dev_info(dev, "%s: pm_runtime not enabled\n", __func__); ret = msm_spi_pm_resume_runtime(dev); } else { ret = pm_runtime_get_sync(dev); } return ret; } static int msm_spi_pm_put_sync(struct device *dev) { int ret = 0; if (!pm_runtime_enabled(dev)) { dev_info(dev, "%s: pm_runtime not enabled\n", __func__); ret = msm_spi_pm_suspend_runtime(dev); } else { pm_runtime_mark_last_busy(dev); pm_runtime_put_autosuspend(dev); } return ret; } static int msm_spi_prepare_message(struct spi_master *master, struct spi_message *spi_msg) { struct msm_spi *dd = spi_master_get_devdata(master); int resume_state; resume_state = msm_spi_pm_get_sync(dd->dev); if (resume_state < 0) return resume_state; return 0; } static int msm_spi_unprepare_message(struct spi_master *master, struct spi_message *spi_msg) { struct msm_spi *dd = spi_master_get_devdata(master); int ret; ret = msm_spi_pm_put_sync(dd->dev); if (ret < 0) return ret; return 0; } static int msm_spi_prepare_transfer_hardware(struct spi_master *master) { struct msm_spi *dd = spi_master_get_devdata(master); int resume_state; if (!dd->pdata->shared_ee) { resume_state = msm_spi_pm_get_sync(dd->dev); if (resume_state < 0) goto spi_finalize; if (dd->suspended) { resume_state = -EBUSY; goto spi_finalize; } } return 0; spi_finalize: spi_finalize_current_message(master); return resume_state; } static int msm_spi_unprepare_transfer_hardware(struct spi_master *master) { struct msm_spi *dd = spi_master_get_devdata(master); int ret; if (!dd->pdata->shared_ee) { ret = msm_spi_pm_put_sync(dd->dev); if (ret < 0) return ret; } return 0; } static int msm_spi_setup(struct spi_device *spi) { struct msm_spi *dd; int rc = 0; u32 spi_ioc; u32 spi_config; u32 mask; if (spi->bits_per_word < 4 || spi->bits_per_word > 32) { dev_err(&spi->dev, "%s: invalid bits_per_word %d\n", __func__, spi->bits_per_word); return -EINVAL; } if (spi->chip_select > SPI_NUM_CHIPSELECTS-1) { dev_err(&spi->dev, "%s, chip select %d exceeds max value %d\n", __func__, spi->chip_select, SPI_NUM_CHIPSELECTS - 1); return -EINVAL; } dd = spi_master_get_devdata(spi->master); rc = pm_runtime_get_sync(dd->dev); if (rc < 0 && !dd->is_init_complete && pm_runtime_enabled(dd->dev)) { pm_runtime_set_suspended(dd->dev); pm_runtime_put_sync(dd->dev); rc = 0; goto err_setup_exit; } else rc = 0; mutex_lock(&dd->core_lock); /* Counter-part of system-suspend when runtime-pm is not enabled. */ if (!pm_runtime_enabled(dd->dev)) { rc = msm_spi_pm_resume_runtime(dd->dev); if (rc < 0 && !dd->is_init_complete) { rc = 0; mutex_unlock(&dd->core_lock); goto err_setup_exit; } } if (dd->suspended) { rc = -EBUSY; mutex_unlock(&dd->core_lock); goto err_setup_exit; } if (dd->pdata->is_shared) { rc = get_local_resources(dd); if (rc) goto no_resources; } spi_ioc = readl_relaxed(dd->base + SPI_IO_CONTROL); mask = SPI_IO_C_CS_N_POLARITY_0 << spi->chip_select; if (spi->mode & SPI_CS_HIGH) spi_ioc |= mask; else spi_ioc &= ~mask; spi_ioc = msm_spi_calc_spi_ioc_clk_polarity(spi_ioc, spi->mode); writel_relaxed(spi_ioc, dd->base + SPI_IO_CONTROL); spi_config = readl_relaxed(dd->base + SPI_CONFIG); spi_config = msm_spi_calc_spi_config_loopback_and_input_first( spi_config, spi->mode); writel_relaxed(spi_config, dd->base + SPI_CONFIG); /* Ensure previous write completed before disabling the clocks */ mb(); if (dd->pdata->is_shared) put_local_resources(dd); /* Counter-part of system-resume when runtime-pm is not enabled. */ if (!pm_runtime_enabled(dd->dev)) msm_spi_pm_suspend_runtime(dd->dev); no_resources: mutex_unlock(&dd->core_lock); pm_runtime_mark_last_busy(dd->dev); pm_runtime_put_autosuspend(dd->dev); err_setup_exit: return rc; } #ifdef CONFIG_DEBUG_FS static int debugfs_iomem_x32_set(void *data, u64 val) { struct msm_spi_debugfs_data *reg = (struct msm_spi_debugfs_data *)data; struct msm_spi *dd = reg->dd; int ret; ret = pm_runtime_get_sync(dd->dev); if (ret < 0) return ret; writel_relaxed(val, (dd->base + reg->offset)); /* Ensure the previous write completed. */ mb(); pm_runtime_mark_last_busy(dd->dev); pm_runtime_put_autosuspend(dd->dev); return 0; } static int debugfs_iomem_x32_get(void *data, u64 *val) { struct msm_spi_debugfs_data *reg = (struct msm_spi_debugfs_data *)data; struct msm_spi *dd = reg->dd; int ret; ret = pm_runtime_get_sync(dd->dev); if (ret < 0) return ret; *val = readl_relaxed(dd->base + reg->offset); /* Ensure the previous read completed. */ mb(); pm_runtime_mark_last_busy(dd->dev); pm_runtime_put_autosuspend(dd->dev); return 0; } DEFINE_SIMPLE_ATTRIBUTE(fops_iomem_x32, debugfs_iomem_x32_get, debugfs_iomem_x32_set, "0x%08llx\n"); static void spi_debugfs_init(struct msm_spi *dd) { char dir_name[20]; scnprintf(dir_name, sizeof(dir_name), "%s_dbg", dev_name(dd->dev)); dd->dent_spi = debugfs_create_dir(dir_name, NULL); if (dd->dent_spi) { int i; for (i = 0; i < ARRAY_SIZE(debugfs_spi_regs); i++) { dd->reg_data[i].offset = debugfs_spi_regs[i].offset; dd->reg_data[i].dd = dd; dd->debugfs_spi_regs[i] = debugfs_create_file( debugfs_spi_regs[i].name, debugfs_spi_regs[i].mode, dd->dent_spi, &dd->reg_data[i], &fops_iomem_x32); } } } static void spi_debugfs_exit(struct msm_spi *dd) { if (dd->dent_spi) { int i; debugfs_remove_recursive(dd->dent_spi); dd->dent_spi = NULL; for (i = 0; i < ARRAY_SIZE(debugfs_spi_regs); i++) dd->debugfs_spi_regs[i] = NULL; } } #else static void spi_debugfs_init(struct msm_spi *dd) {} static void spi_debugfs_exit(struct msm_spi *dd) {} #endif /* ===Device attributes begin=== */ static ssize_t show_stats(struct device *dev, struct device_attribute *attr, char *buf) { struct spi_master *master = dev_get_drvdata(dev); struct msm_spi *dd = spi_master_get_devdata(master); return snprintf(buf, PAGE_SIZE, "Device %s\n" "rx fifo_size = %d spi words\n" "tx fifo_size = %d spi words\n" "use_dma ? %s\n" "rx block size = %d bytes\n" "tx block size = %d bytes\n" "input burst size = %d bytes\n" "output burst size = %d bytes\n" "DMA configuration:\n" "tx_ch=%d, rx_ch=%d, tx_crci= %d, rx_crci=%d\n" "--statistics--\n" "Rx isrs = %d\n" "Tx isrs = %d\n" "--debug--\n" "NA yet\n", dev_name(dev), dd->input_fifo_size, dd->output_fifo_size, dd->use_dma ? "yes" : "no", dd->input_block_size, dd->output_block_size, dd->input_burst_size, dd->output_burst_size, dd->tx_dma_chan, dd->rx_dma_chan, dd->tx_dma_crci, dd->rx_dma_crci, dd->stat_rx, dd->stat_tx ); } /* Reset statistics on write */ static ssize_t set_stats(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { struct msm_spi *dd = dev_get_drvdata(dev); dd->stat_rx = 0; dd->stat_tx = 0; return count; } static DEVICE_ATTR(stats, 0644, show_stats, set_stats); static struct attribute *dev_attrs[] = { &dev_attr_stats.attr, NULL, }; static struct attribute_group dev_attr_grp = { .attrs = dev_attrs, }; /* ===Device attributes end=== */ static void msm_spi_bam_pipe_teardown(struct msm_spi *dd, enum msm_spi_pipe_direction pipe_dir) { struct msm_spi_bam_pipe *pipe = (pipe_dir == SPI_BAM_CONSUMER_PIPE) ? (&dd->bam.prod) : (&dd->bam.cons); if (!pipe->teardown_required) return; msm_spi_bam_pipe_disconnect(dd, pipe); dma_free_coherent(dd->dev, pipe->config.desc.size, pipe->config.desc.base, pipe->config.desc.phys_base); sps_free_endpoint(pipe->handle); pipe->handle = NULL; pipe->teardown_required = false; } static int msm_spi_bam_pipe_init(struct msm_spi *dd, enum msm_spi_pipe_direction pipe_dir) { int rc = 0; struct sps_pipe *pipe_handle; struct msm_spi_bam_pipe *pipe = (pipe_dir == SPI_BAM_CONSUMER_PIPE) ? (&dd->bam.prod) : (&dd->bam.cons); struct sps_connect *pipe_conf = &pipe->config; pipe->name = (pipe_dir == SPI_BAM_CONSUMER_PIPE) ? "cons" : "prod"; pipe->handle = NULL; pipe_handle = sps_alloc_endpoint(); if (!pipe_handle) { dev_err(dd->dev, "%s: Failed to allocate BAM endpoint\n" , __func__); return -ENOMEM; } memset(pipe_conf, 0, sizeof(*pipe_conf)); rc = sps_get_config(pipe_handle, pipe_conf); if (rc) { dev_err(dd->dev, "%s: Failed to get BAM pipe config\n" , __func__); goto config_err; } if (pipe_dir == SPI_BAM_CONSUMER_PIPE) { pipe_conf->source = dd->bam.handle; pipe_conf->destination = SPS_DEV_HANDLE_MEM; pipe_conf->mode = SPS_MODE_SRC; pipe_conf->src_pipe_index = dd->pdata->bam_producer_pipe_index; pipe_conf->dest_pipe_index = 0; } else { pipe_conf->source = SPS_DEV_HANDLE_MEM; pipe_conf->destination = dd->bam.handle; pipe_conf->mode = SPS_MODE_DEST; pipe_conf->src_pipe_index = 0; pipe_conf->dest_pipe_index = dd->pdata->bam_consumer_pipe_index; } pipe_conf->options = SPS_O_EOT | SPS_O_AUTO_ENABLE; pipe_conf->desc.size = SPI_BAM_MAX_DESC_NUM * sizeof(struct sps_iovec); pipe_conf->desc.base = dma_alloc_coherent(dd->dev, pipe_conf->desc.size, &pipe_conf->desc.phys_base, GFP_KERNEL); if (!pipe_conf->desc.base) { dev_err(dd->dev, "%s: Failed allocate BAM pipe memory\n" , __func__); rc = -ENOMEM; goto config_err; } /* zero descriptor FIFO for convenient debugging of first descs */ memset(pipe_conf->desc.base, 0x00, pipe_conf->desc.size); pipe->handle = pipe_handle; return 0; config_err: sps_free_endpoint(pipe_handle); return rc; } static void msm_spi_bam_teardown(struct msm_spi *dd) { msm_spi_bam_pipe_teardown(dd, SPI_BAM_PRODUCER_PIPE); msm_spi_bam_pipe_teardown(dd, SPI_BAM_CONSUMER_PIPE); if (dd->bam.deregister_required) { sps_deregister_bam_device(dd->bam.handle); dd->bam.deregister_required = false; } } static int msm_spi_bam_init(struct msm_spi *dd) { struct sps_bam_props bam_props = {0}; uintptr_t bam_handle; int rc = 0; rc = sps_phy2h(dd->bam.phys_addr, &bam_handle); if (rc || !bam_handle) { bam_props.phys_addr = dd->bam.phys_addr; bam_props.virt_addr = dd->bam.base; bam_props.irq = dd->bam.irq; bam_props.manage = SPS_BAM_MGR_DEVICE_REMOTE; bam_props.summing_threshold = 0x10; rc = sps_register_bam_device(&bam_props, &bam_handle); if (rc) { dev_err(dd->dev, "%s: Failed to register BAM device\n", __func__); return rc; } dd->bam.deregister_required = true; } dd->bam.handle = bam_handle; rc = msm_spi_bam_pipe_init(dd, SPI_BAM_PRODUCER_PIPE); if (rc) { dev_err(dd->dev, "%s: Failed to init producer BAM-pipe\n", __func__); goto bam_init_error; } rc = msm_spi_bam_pipe_init(dd, SPI_BAM_CONSUMER_PIPE); if (rc) { dev_err(dd->dev, "%s: Failed to init consumer BAM-pipe\n", __func__); goto bam_init_error; } return 0; bam_init_error: msm_spi_bam_teardown(dd); return rc; } enum msm_spi_dt_entry_status { DT_REQ, /* Required: fail if missing */ DT_SGST, /* Suggested: warn if missing */ DT_OPT, /* Optional: don't warn if missing */ }; enum msm_spi_dt_entry_type { DT_U32, DT_GPIO, DT_BOOL, }; struct msm_spi_dt_to_pdata_map { const char *dt_name; void *ptr_data; enum msm_spi_dt_entry_status status; enum msm_spi_dt_entry_type type; int default_val; }; static int msm_spi_dt_to_pdata_populate(struct platform_device *pdev, struct msm_spi_platform_data *pdata, struct msm_spi_dt_to_pdata_map *itr) { int ret, err = 0; struct device_node *node = pdev->dev.of_node; for (; itr->dt_name; ++itr) { switch (itr->type) { case DT_GPIO: ret = of_get_named_gpio(node, itr->dt_name, 0); if (ret >= 0) { *((int *) itr->ptr_data) = ret; ret = 0; } break; case DT_U32: ret = of_property_read_u32(node, itr->dt_name, (u32 *) itr->ptr_data); break; case DT_BOOL: *((bool *) itr->ptr_data) = of_property_read_bool(node, itr->dt_name); ret = 0; break; default: dev_err(&pdev->dev, "%d is an unknown DT entry type\n", itr->type); ret = -EBADE; } dev_dbg(&pdev->dev, "DT entry ret:%d name:%s val:%d\n", ret, itr->dt_name, *((int *)itr->ptr_data)); if (ret) { *((int *)itr->ptr_data) = itr->default_val; if (itr->status < DT_OPT) { dev_err(&pdev->dev, "Missing '%s' DT entry\n", itr->dt_name); /* cont on err to dump all missing entries */ if (itr->status == DT_REQ && !err) err = ret; } } } return err; } /** * msm_spi_dt_to_pdata: create pdata and read gpio config from device tree */ static struct msm_spi_platform_data *msm_spi_dt_to_pdata( struct platform_device *pdev, struct msm_spi *dd) { struct msm_spi_platform_data *pdata; pdata = devm_kzalloc(&pdev->dev, sizeof(*pdata), GFP_KERNEL); if (!pdata) return NULL; if (pdata) { struct msm_spi_dt_to_pdata_map map[] = { {"spi-max-frequency", &pdata->max_clock_speed, DT_SGST, DT_U32, 0}, {"qcom,infinite-mode", &pdata->infinite_mode, DT_OPT, DT_U32, 0}, {"qcom,master-id", &pdata->master_id, DT_SGST, DT_U32, 0}, {"qcom,bus-width", &pdata->bus_width, DT_OPT, DT_U32, 8}, {"qcom,ver-reg-exists", &pdata->ver_reg_exists, DT_OPT, DT_BOOL, 0}, {"qcom,use-bam", &pdata->use_bam, DT_OPT, DT_BOOL, 0}, {"qcom,use-pinctrl", &pdata->use_pinctrl, DT_OPT, DT_BOOL, 0}, {"qcom,bam-consumer-pipe-index", &pdata->bam_consumer_pipe_index, DT_OPT, DT_U32, 0}, {"qcom,bam-producer-pipe-index", &pdata->bam_producer_pipe_index, DT_OPT, DT_U32, 0}, {"qcom,gpio-clk", &dd->spi_gpios[0], DT_OPT, DT_GPIO, -1}, {"qcom,gpio-miso", &dd->spi_gpios[1], DT_OPT, DT_GPIO, -1}, {"qcom,gpio-mosi", &dd->spi_gpios[2], DT_OPT, DT_GPIO, -1}, {"qcom,gpio-cs0", &dd->cs_gpios[0].gpio_num, DT_OPT, DT_GPIO, -1}, {"qcom,gpio-cs1", &dd->cs_gpios[1].gpio_num, DT_OPT, DT_GPIO, -1}, {"qcom,gpio-cs2", &dd->cs_gpios[2].gpio_num, DT_OPT, DT_GPIO, -1}, {"qcom,gpio-cs3", &dd->cs_gpios[3].gpio_num, DT_OPT, DT_GPIO, -1}, {"qcom,rt-priority", &pdata->rt_priority, DT_OPT, DT_BOOL, 0}, {"qcom,shared", &pdata->is_shared, DT_OPT, DT_BOOL, 0}, {"qcom,shared_ee", &pdata->shared_ee, DT_OPT, DT_BOOL, 0}, {NULL, NULL, 0, 0, 0}, }; if (msm_spi_dt_to_pdata_populate(pdev, pdata, map)) { devm_kfree(&pdev->dev, pdata); return NULL; } } if (pdata->use_bam) { if (!pdata->bam_consumer_pipe_index) { dev_warn(&pdev->dev, "missing qcom,bam-consumer-pipe-index entry in device-tree\n"); pdata->use_bam = false; } if (!pdata->bam_producer_pipe_index) { dev_warn(&pdev->dev, "missing qcom,bam-producer-pipe-index entry in device-tree\n"); pdata->use_bam = false; } } return pdata; } static int msm_spi_get_qup_hw_ver(struct device *dev, struct msm_spi *dd) { u32 data = readl_relaxed(dd->base + QUP_HARDWARE_VER); return (data >= QUP_HARDWARE_VER_2_1_1) ? SPI_QUP_VERSION_BFAM : SPI_QUP_VERSION_NONE; } static int msm_spi_bam_get_resources(struct msm_spi *dd, struct platform_device *pdev, struct spi_master *master) { struct resource *resource; size_t bam_mem_size; resource = platform_get_resource_byname(pdev, IORESOURCE_MEM, "spi_bam_physical"); if (!resource) { dev_warn(&pdev->dev, "%s: Missing spi_bam_physical entry in DT\n", __func__); return -ENXIO; } dd->bam.phys_addr = resource->start; bam_mem_size = resource_size(resource); dd->bam.base = devm_ioremap(&pdev->dev, dd->bam.phys_addr, bam_mem_size); if (!dd->bam.base) { dev_warn(&pdev->dev, "%s: Failed to ioremap(spi_bam_physical)\n", __func__); return -ENXIO; } dd->bam.irq = platform_get_irq_byname(pdev, "spi_bam_irq"); if (dd->bam.irq < 0) { dev_warn(&pdev->dev, "%s: Missing spi_bam_irq entry in DT\n", __func__); return -EINVAL; } dd->dma_init = msm_spi_bam_init; dd->dma_teardown = msm_spi_bam_teardown; return 0; } static int init_resources(struct platform_device *pdev) { struct spi_master *master = platform_get_drvdata(pdev); struct msm_spi *dd; int rc = -ENXIO; int clk_enabled = 0; int pclk_enabled = 0; dd = spi_master_get_devdata(master); if (dd->pdata && dd->pdata->use_pinctrl) { rc = msm_spi_pinctrl_init(dd); if (rc) { dev_err(&pdev->dev, "%s: pinctrl init failed\n", __func__); return rc; } } mutex_lock(&dd->core_lock); dd->clk = clk_get(&pdev->dev, "core_clk"); if (IS_ERR(dd->clk)) { dev_err(&pdev->dev, "%s: unable to get core_clk\n", __func__); rc = PTR_ERR(dd->clk); goto err_clk_get; } dd->pclk = clk_get(&pdev->dev, "iface_clk"); if (IS_ERR(dd->pclk)) { dev_err(&pdev->dev, "%s: unable to get iface_clk\n", __func__); rc = PTR_ERR(dd->pclk); goto err_pclk_get; } if (dd->pdata && dd->pdata->max_clock_speed) msm_spi_clock_set(dd, dd->pdata->max_clock_speed); rc = clk_prepare_enable(dd->clk); if (rc) { dev_err(&pdev->dev, "%s: unable to enable core_clk\n", __func__); goto err_clk_enable; } clk_enabled = 1; rc = clk_prepare_enable(dd->pclk); if (rc) { dev_err(&pdev->dev, "%s: unable to enable iface_clk\n", __func__); goto err_pclk_enable; } pclk_enabled = 1; if (dd->pdata && dd->pdata->ver_reg_exists) { enum msm_spi_qup_version ver = msm_spi_get_qup_hw_ver(&pdev->dev, dd); if (dd->qup_ver != ver) dev_warn(&pdev->dev, "%s: HW version different then assumed by probe\n", __func__); } /* GSBI dose not exists on B-family MSM-chips */ if (dd->qup_ver != SPI_QUP_VERSION_BFAM) { rc = msm_spi_configure_gsbi(dd, pdev); if (rc) goto err_config_gsbi; } msm_spi_calculate_fifo_size(dd); if (dd->use_dma) { rc = dd->dma_init(dd); if (rc) { dev_err(&pdev->dev, "%s: failed to init DMA. Disabling DMA mode\n", __func__); dd->use_dma = 0; } } msm_spi_register_init(dd); /* * The SPI core generates a bogus input overrun error on some targets, * when a transition from run to reset state occurs and if the FIFO has * an odd number of entries. Hence we disable the INPUT_OVER_RUN_ERR_EN * bit. */ msm_spi_enable_error_flags(dd); writel_relaxed(SPI_IO_C_NO_TRI_STATE, dd->base + SPI_IO_CONTROL); rc = msm_spi_set_state(dd, SPI_OP_STATE_RESET); if (rc) goto err_spi_state; clk_disable_unprepare(dd->clk); clk_disable_unprepare(dd->pclk); clk_enabled = 0; pclk_enabled = 0; dd->transfer_pending = 0; dd->tx_mode = SPI_MODE_NONE; dd->rx_mode = SPI_MODE_NONE; rc = msm_spi_request_irq(dd, pdev, master); if (rc) goto err_irq; msm_spi_disable_irqs(dd); mutex_unlock(&dd->core_lock); return 0; err_irq: err_spi_state: if (dd->use_dma && dd->dma_teardown) dd->dma_teardown(dd); err_config_gsbi: if (pclk_enabled) clk_disable_unprepare(dd->pclk); err_pclk_enable: if (clk_enabled) clk_disable_unprepare(dd->clk); err_clk_enable: clk_put(dd->pclk); err_pclk_get: clk_put(dd->clk); err_clk_get: mutex_unlock(&dd->core_lock); return rc; } static int msm_spi_probe(struct platform_device *pdev) { struct spi_master *master; struct msm_spi *dd; struct resource *resource; int i = 0; int rc = -ENXIO; struct msm_spi_platform_data *pdata; master = spi_alloc_master(&pdev->dev, sizeof(struct msm_spi)); if (!master) { rc = -ENOMEM; dev_err(&pdev->dev, "master allocation failed\n"); goto err_probe_exit; } master->bus_num = pdev->id; master->mode_bits = SPI_SUPPORTED_MODES; master->num_chipselect = SPI_NUM_CHIPSELECTS; master->set_cs = msm_spi_set_cs; master->setup = msm_spi_setup; master->prepare_transfer_hardware = msm_spi_prepare_transfer_hardware; master->transfer_one = msm_spi_transfer_one; master->unprepare_transfer_hardware = msm_spi_unprepare_transfer_hardware; platform_set_drvdata(pdev, master); dd = spi_master_get_devdata(master); if (pdev->dev.of_node) { dd->qup_ver = SPI_QUP_VERSION_BFAM; master->dev.of_node = pdev->dev.of_node; pdata = msm_spi_dt_to_pdata(pdev, dd); if (!pdata) { dev_err(&pdev->dev, "platform data allocation failed\n"); rc = -ENOMEM; goto err_probe_exit; } rc = of_alias_get_id(pdev->dev.of_node, "spi"); if (rc < 0) dev_warn(&pdev->dev, "using default bus_num %d\n", pdev->id); else master->bus_num = pdev->id = rc; } else { pdata = pdev->dev.platform_data; dd->qup_ver = SPI_QUP_VERSION_NONE; for (i = 0; i < ARRAY_SIZE(spi_rsrcs); ++i) { resource = platform_get_resource(pdev, IORESOURCE_IO, i); dd->spi_gpios[i] = resource ? resource->start : -1; } for (i = 0; i < ARRAY_SIZE(spi_cs_rsrcs); ++i) { resource = platform_get_resource(pdev, IORESOURCE_IO, i + ARRAY_SIZE(spi_rsrcs)); dd->cs_gpios[i].gpio_num = resource ? resource->start : -1; } } for (i = 0; i < ARRAY_SIZE(spi_cs_rsrcs); ++i) dd->cs_gpios[i].valid = 0; dd->pdata = pdata; resource = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!resource) { rc = -ENXIO; goto err_probe_res; } dd->mem_phys_addr = resource->start; dd->mem_size = resource_size(resource); dd->dev = &pdev->dev; if (pdata) { master->rt = pdata->rt_priority; if (pdata->dma_config) { rc = pdata->dma_config(); if (rc) { dev_warn(&pdev->dev, "%s: DM mode not supported\n", __func__); dd->use_dma = 0; goto skip_dma_resources; } } if (!dd->pdata->use_bam) goto skip_dma_resources; rc = msm_spi_bam_get_resources(dd, pdev, master); if (rc) { dev_warn(dd->dev, "%s: Failed to get BAM resources\n", __func__); goto skip_dma_resources; } dd->use_dma = 1; } spi_dma_mask(&pdev->dev); skip_dma_resources: spin_lock_init(&dd->queue_lock); mutex_init(&dd->core_lock); init_waitqueue_head(&dd->continue_suspend); if (!devm_request_mem_region(&pdev->dev, dd->mem_phys_addr, dd->mem_size, SPI_DRV_NAME)) { rc = -ENXIO; goto err_probe_reqmem; } dd->base = devm_ioremap(&pdev->dev, dd->mem_phys_addr, dd->mem_size); if (!dd->base) { rc = -ENOMEM; goto err_probe_reqmem; } /* This property is required for Dual EE use case of spi */ if (dd->pdata->shared_ee) { master->prepare_message = msm_spi_prepare_message; master->unprepare_message = msm_spi_unprepare_message; } pm_runtime_set_autosuspend_delay(&pdev->dev, MSEC_PER_SEC); pm_runtime_use_autosuspend(&pdev->dev); pm_runtime_enable(&pdev->dev); dd->suspended = 1; rc = spi_register_master(master); if (rc) goto err_probe_reg_master; rc = sysfs_create_group(&(dd->dev->kobj), &dev_attr_grp); if (rc) { dev_err(&pdev->dev, "failed to create dev. attrs : %d\n", rc); goto err_attrs; } spi_debugfs_init(dd); return 0; err_attrs: spi_unregister_master(master); err_probe_reg_master: pm_runtime_disable(&pdev->dev); err_probe_reqmem: err_probe_res: spi_master_put(master); err_probe_exit: return rc; } static int msm_spi_pm_suspend_runtime(struct device *device) { struct platform_device *pdev = to_platform_device(device); struct spi_master *master = platform_get_drvdata(pdev); struct msm_spi *dd; unsigned long flags; dev_dbg(device, "pm_runtime: suspending...\n"); if (!master) goto suspend_exit; dd = spi_master_get_devdata(master); if (!dd) goto suspend_exit; if (dd->suspended) return 0; /* * Make sure nothing is added to the queue while we're * suspending */ spin_lock_irqsave(&dd->queue_lock, flags); dd->suspended = 1; spin_unlock_irqrestore(&dd->queue_lock, flags); /* Wait for transactions to end, or time out */ wait_event_interruptible(dd->continue_suspend, !dd->transfer_pending); mutex_lock(&dd->core_lock); if (dd->pdata && !dd->pdata->is_shared && dd->use_dma) { msm_spi_bam_pipe_disconnect(dd, &dd->bam.prod); msm_spi_bam_pipe_disconnect(dd, &dd->bam.cons); } if (dd->pdata && !dd->pdata->is_shared) put_local_resources(dd); if (dd->pdata) msm_spi_clk_path_vote(dd, 0); mutex_unlock(&dd->core_lock); suspend_exit: return 0; } static int msm_spi_pm_resume_runtime(struct device *device) { struct platform_device *pdev = to_platform_device(device); struct spi_master *master = platform_get_drvdata(pdev); struct msm_spi *dd; int ret = 0; dev_dbg(device, "pm_runtime: resuming...\n"); if (!master) goto resume_exit; dd = spi_master_get_devdata(master); if (!dd) goto resume_exit; if (!dd->suspended) return 0; if (!dd->is_init_complete) { ret = init_resources(pdev); if (ret != 0) return ret; dd->is_init_complete = true; } msm_spi_clk_path_init(dd); msm_spi_clk_path_vote(dd, dd->pdata->max_clock_speed); if (!dd->pdata->is_shared) { ret = get_local_resources(dd); if (ret) return ret; } if (!dd->pdata->is_shared && dd->use_dma) { msm_spi_bam_pipe_connect(dd, &dd->bam.prod, &dd->bam.prod.config); msm_spi_bam_pipe_connect(dd, &dd->bam.cons, &dd->bam.cons.config); } dd->suspended = 0; resume_exit: return 0; } #ifdef CONFIG_PM_SLEEP static int msm_spi_suspend(struct device *device) { if (!pm_runtime_enabled(device) || !pm_runtime_suspended(device)) { struct platform_device *pdev = to_platform_device(device); struct spi_master *master = platform_get_drvdata(pdev); struct msm_spi *dd; dev_dbg(device, "system suspend\n"); if (!master) goto suspend_exit; dd = spi_master_get_devdata(master); if (!dd) goto suspend_exit; msm_spi_pm_suspend_runtime(device); /* * set the device's runtime PM status to 'suspended' */ pm_runtime_disable(device); pm_runtime_set_suspended(device); pm_runtime_enable(device); } suspend_exit: return 0; } static int msm_spi_resume(struct device *device) { /* * Rely on runtime-PM to call resume in case it is enabled * Even if it's not enabled, rely on 1st client transaction to do * clock ON and gpio configuration */ dev_dbg(device, "system resume\n"); return 0; } #else #define msm_spi_suspend NULL #define msm_spi_resume NULL #endif static int msm_spi_remove(struct platform_device *pdev) { struct spi_master *master = platform_get_drvdata(pdev); struct msm_spi *dd = spi_master_get_devdata(master); spi_debugfs_exit(dd); sysfs_remove_group(&pdev->dev.kobj, &dev_attr_grp); if (dd->dma_teardown) dd->dma_teardown(dd); pm_runtime_disable(&pdev->dev); pm_runtime_set_suspended(&pdev->dev); clk_put(dd->clk); clk_put(dd->pclk); msm_spi_clk_path_teardown(dd); platform_set_drvdata(pdev, NULL); spi_unregister_master(master); spi_master_put(master); return 0; } static const struct of_device_id msm_spi_dt_match[] = { { .compatible = "qcom,spi-qup-v2", }, {} }; static const struct dev_pm_ops msm_spi_dev_pm_ops = { SET_SYSTEM_SLEEP_PM_OPS(msm_spi_suspend, msm_spi_resume) SET_RUNTIME_PM_OPS(msm_spi_pm_suspend_runtime, msm_spi_pm_resume_runtime, NULL) }; static struct platform_driver msm_spi_driver = { .driver = { .name = SPI_DRV_NAME, .owner = THIS_MODULE, .pm = &msm_spi_dev_pm_ops, .of_match_table = msm_spi_dt_match, }, .probe = msm_spi_probe, .remove = msm_spi_remove, }; module_platform_driver(msm_spi_driver); MODULE_LICENSE("GPL v2"); MODULE_ALIAS("platform:"SPI_DRV_NAME);