diff options
Diffstat (limited to '')
-rw-r--r-- | drivers/brcm/emmc/emmc_chal_sd.c | 1017 | ||||
-rw-r--r-- | drivers/brcm/emmc/emmc_csl_sdcard.c | 1089 | ||||
-rw-r--r-- | drivers/brcm/emmc/emmc_csl_sdcmd.c | 842 | ||||
-rw-r--r-- | drivers/brcm/emmc/emmc_pboot_hal_memory_drv.c | 621 |
4 files changed, 3569 insertions, 0 deletions
diff --git a/drivers/brcm/emmc/emmc_chal_sd.c b/drivers/brcm/emmc/emmc_chal_sd.c new file mode 100644 index 0000000..34d761c --- /dev/null +++ b/drivers/brcm/emmc/emmc_chal_sd.c @@ -0,0 +1,1017 @@ +/* + * Copyright (c) 2016 - 2020, Broadcom + * + * SPDX-License-Identifier: BSD-3-Clause + */ + +#include <assert.h> +#include <string.h> + +#include <lib/mmio.h> + +#include <platform_def.h> + +#include "bcm_emmc.h" +#include "emmc_chal_types.h" +#include "emmc_chal_sd.h" +#include "emmc_pboot_hal_memory_drv.h" + +extern void emmc_soft_reset(void); + +#define SD_VDD_WINDOW_1_6_TO_1_7 0x00000010 // 1.6 V to 1.7 Volts +#define SD_VDD_WINDOW_1_7_TO_1_8 0x00000020 // 1.7 V to 1.8 Volts +#define SD_VDD_WINDOW_1_8_TO_1_9 0x00000040 // 1.8 V to 1.9 Volts +#define SD_VDD_WINDOW_1_9_TO_2_0 0x00000080 // 1.9 V to 2.0 Volts +#define SD_VDD_WINDOW_2_0_TO_2_1 0x00000100 // 2.0 V to 2.1 Volts +#define SD_VDD_WINDOW_2_1_TO_2_2 0x00000200 // 2.1 V to 2.2 Volts +#define SD_VDD_WINDOW_2_2_TO_2_3 0x00000400 // 2.2 V to 2.3 Volts +#define SD_VDD_WINDOW_2_3_TO_2_4 0x00000800 // 2.3 V to 2.4 Volts +#define SD_VDD_WINDOW_2_4_TO_2_5 0x00001000 // 2.4 V to 2.5 Volts +#define SD_VDD_WINDOW_2_5_TO_2_6 0x00002000 // 2.5 V to 2.6 Volts +#define SD_VDD_WINDOW_2_6_TO_2_7 0x00004000 // 2.6 V to 2.7 Volts +#define SD_VDD_WINDOW_2_7_TO_2_8 0x00008000 // 2.7 V to 2.8 Volts +#define SD_VDD_WINDOW_2_8_TO_2_9 0x00010000 // 2.8 V to 2.9 Volts +#define SD_VDD_WINDOW_2_9_TO_3_0 0x00020000 // 2.9 V to 3.0 Volts +#define SD_VDD_WINDOW_3_0_TO_3_1 0x00040000 // 3.0 V to 3.1 Volts +#define SD_VDD_WINDOW_3_1_TO_3_2 0x00080000 // 3.1 V to 3.2 Volts +#define SD_VDD_WINDOW_3_2_TO_3_3 0x00100000 // 3.2 V to 3.3 Volts +#define SD_VDD_WINDOW_3_3_TO_3_4 0x00200000 // 3.3 V to 3.4 Volts +#define SD_VDD_WINDOW_3_4_TO_3_5 0x00400000 // 3.4 V to 3.5 Volts +#define SD_VDD_WINDOW_3_5_TO_3_6 0x00800000 // 3.5 V to 3.6 Volts + +#define SD_VDD_WINDOW_1_6_TO_2_6 (SD_VDD_WINDOW_1_6_TO_1_7 | \ + SD_VDD_WINDOW_1_7_TO_1_8 | \ + SD_VDD_WINDOW_1_8_TO_1_9 | \ + SD_VDD_WINDOW_1_9_TO_2_0 | \ + SD_VDD_WINDOW_2_0_TO_2_1 | \ + SD_VDD_WINDOW_2_1_TO_2_2 | \ + SD_VDD_WINDOW_2_2_TO_2_3 | \ + SD_VDD_WINDOW_2_3_TO_2_4 | \ + SD_VDD_WINDOW_2_4_TO_2_5 | \ + SD_VDD_WINDOW_2_5_TO_2_6) + +#define SD_VDD_WINDOW_2_6_TO_3_2 (SD_VDD_WINDOW_2_6_TO_2_7 | \ + SD_VDD_WINDOW_2_7_TO_2_8 | \ + SD_VDD_WINDOW_2_8_TO_2_9 | \ + SD_VDD_WINDOW_2_9_TO_3_0 | \ + SD_VDD_WINDOW_3_0_TO_3_1 | \ + SD_VDD_WINDOW_3_1_TO_3_2) + +#define SD_VDD_WINDOW_3_2_TO_3_6 (SD_VDD_WINDOW_3_2_TO_3_3 | \ + SD_VDD_WINDOW_3_3_TO_3_4 | \ + SD_VDD_WINDOW_3_4_TO_3_5 | \ + SD_VDD_WINDOW_3_5_TO_3_6) + + +static int32_t chal_sd_set_power(struct sd_dev *handle, + uint32_t voltage, uint32_t state); + +static void chal_sd_set_dma_boundary(struct sd_dev *handle, uint32_t boundary); + +static int32_t chal_sd_setup_handler(struct sd_dev *handle, + uint32_t sdBbase, uint32_t hostBase); + +/* + * Configure host controller pwr settings, + * to match voltage requirements by SD Card + */ +static int32_t chal_sd_set_power(struct sd_dev *handle, + uint32_t voltage, uint32_t state) +{ + int32_t rc, rval = SD_FAIL; + uint32_t time = 0; + + if (handle == NULL) + return SD_INVALID_HANDLE; + + mmio_clrsetbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET, + (SD4_EMMC_TOP_CTRL_SDVSELVDD1_MASK | + SD4_EMMC_TOP_CTRL_SDPWR_MASK), + (voltage << 9)); + + /* + * Long delay is required here in emulation. Without this, the initial + * commands sent to the eMMC card timeout. We don't know if this + * delay is necessary with silicon, leaving in for safety. + * It is observed that 403ms on emulation system and as per the clock + * calculations it is expected to complete with in 1ms on chip + */ + do { + rc = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET); + + if ((rc & SD4_EMMC_TOP_INTR_CRDINS_MASK) == + SD4_EMMC_TOP_INTR_CRDINS_MASK) + break; + + mdelay(1); + } while (time++ < EMMC_CARD_DETECT_TIMEOUT_MS); + + if (time >= EMMC_CARD_DETECT_TIMEOUT_MS) { + ERROR("EMMC: Card insert event detection timeout\n"); + return rval; + } + + VERBOSE("EMMC: Card detection delay: %dms\n", time); + + if (state) + mmio_setbits_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL_OFFSET, + SD4_EMMC_TOP_CTRL_SDPWR_MASK); + + /* dummy write & ack to verify if the sdio is ready to send commads */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_ARG_OFFSET, 0); + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CMD_OFFSET, 0); + + /* + * 63ms observed on emulation system, As per clock calculations + * it will complete < 1ms on chip. + */ + time = 0; + do { + rc = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET); + + if (rc & SD4_EMMC_TOP_INTR_ERRIRQ_MASK) + break; + + if ((rc & SD4_EMMC_TOP_INTR_CMDDONE_MASK) == + SD4_EMMC_TOP_INTR_CMDDONE_MASK) + break; + + mdelay(1); + } while (time++ < EMMC_CMD_TIMEOUT_MS); + + if (time >= EMMC_CMD_TIMEOUT_MS) { + WARN("%s %d Initial dummy command timeout is happened\n", + __func__, __LINE__); + return rval; + } + + VERBOSE("EMMC: Dummy Command delay: %dms\n", time); + + return SD_OK; +} + +/* + * Configure DMA Boundaries + */ +static void chal_sd_set_dma_boundary(struct sd_dev *handle, uint32_t boundary) +{ + if (handle == NULL) + return; + + mmio_clrsetbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BLOCK_OFFSET, + SD4_EMMC_TOP_BLOCK_HSBS_MASK, boundary); +} + +static int32_t chal_sd_setup_handler(struct sd_dev *handle, uint32_t sdBase, + uint32_t hostBase) +{ + if (handle == NULL) + return SD_INVALID_HANDLE; + + handle->ctrl.sdRegBaseAddr = sdBase; + handle->ctrl.hostRegBaseAddr = hostBase; + handle->ctrl.present = 0; + handle->ctrl.rca = 0; + handle->ctrl.blkGapEnable = 0; + handle->ctrl.cmdStatus = 0; + + return SD_OK; +} + +/* + * Initialize SD Host controller + */ +int32_t chal_sd_init(CHAL_HANDLE *sd_handle) +{ + uint32_t cap_val_l = 0; + uint32_t ctl_val, voltage; + uint32_t timeout_val; + struct sd_dev *handle; + uint32_t reg_val; + int32_t rval = SD_FAIL; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *)sd_handle; + + /* + * Set SDIO Host Controller capabilities register + */ + EMMC_TRACE("Set Host Controller Capabilities register\n"); + + reg_val = 0; + reg_val |= (1 << ICFG_SDIO0_CAP0__SLOT_TYPE_R); + reg_val |= (0 << ICFG_SDIO0_CAP0__INT_MODE_R); + reg_val |= (0 << ICFG_SDIO0_CAP0__SYS_BUS_64BIT_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_1P8V_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_3P0V_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__VOLTAGE_3P3V_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__SUSPEND_RESUME_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__SDMA_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__HIGH_SPEED_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__ADMA2_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__EXTENDED_MEDIA_R); + reg_val |= (2 << ICFG_SDIO0_CAP0__MAX_BLOCK_LEN_R); + reg_val |= (0xd0 << ICFG_SDIO0_CAP0__BASE_CLK_FREQ_R); + reg_val |= (1 << ICFG_SDIO0_CAP0__TIMEOUT_UNIT_R); + reg_val |= (0x30 << ICFG_SDIO0_CAP0__TIMEOUT_CLK_FREQ_R); + + mmio_write_32(ICFG_SDIO0_CAP0, reg_val); + + reg_val = 0; + reg_val |= (1 << ICFG_SDIO0_CAP1__SPI_BLOCK_MODE_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__SPI_MODE_R); + reg_val |= (0 << ICFG_SDIO0_CAP1__CLK_MULT_R); + reg_val |= (0 << ICFG_SDIO0_CAP1__RETUNING_MODE_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__TUNE_SDR50_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__TIME_RETUNE_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_D_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_C_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__DRIVER_A_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__DDR50_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__SDR104_R); + reg_val |= (1 << ICFG_SDIO0_CAP1__SDR50_R); + + mmio_write_32(ICFG_SDIO0_CAP1, reg_val); + + /* Reset the SDIO controller */ + chal_sd_stop(); + + /* Turn on SD clock */ + chal_sd_set_clock(sd_handle, + chal_sd_freq_2_div_ctrl_setting(INIT_CLK_FREQ), 1); + + /* program data time out value to the max */ + timeout_val = SD_HOST_CORE_TIMEOUT; + + ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + ctl_val |= ((timeout_val & 0xf) << SD4_EMMC_TOP_CTRL1_DTCNT_SHIFT); + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET, + ctl_val); + + /* enable all interrupt status */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN1_OFFSET, + 0); + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN2_OFFSET, + 0); + + SD_US_DELAY(100); + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN1_OFFSET, + SD_NOR_INTERRUPTS | SD_ERR_INTERRUPTS); + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_INTREN2_OFFSET, + SD_NOR_INTERRUPTS | SD_ERR_INTERRUPTS); + + /* Select SD bus voltage */ + cap_val_l = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CAPABILITIES1_OFFSET); + handle->cfg.voltage = 0; + voltage = 0x7; + + if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V33_MASK) { + handle->cfg.voltage |= SD_VDD_WINDOW_3_3_TO_3_4; + voltage = 0x7; + } else if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V3_MASK) { + handle->cfg.voltage |= SD_VDD_WINDOW_3_0_TO_3_1; + voltage = 0x6; + } else if (cap_val_l & SD4_EMMC_TOP_CAPABILITIES1_V18_MASK) { + handle->cfg.voltage |= SD_VDD_WINDOW_1_8_TO_1_9; + voltage = 0x5; + } + + rval = chal_sd_set_power(handle, voltage, SD4_EMMC_TOP_CTRL_SDPWR_MASK); + + ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_HCVERSIRQ_OFFSET); + handle->ctrl.version = ((ctl_val >> 16) & 0xFF); + + return rval; +} + +void chal_sd_set_speed(CHAL_HANDLE *sd_handle, uint32_t speed) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return; + + handle = (struct sd_dev *) sd_handle; + + if (speed) { + EMMC_TRACE("enable HighSpeed\n"); + mmio_setbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET, + SD4_EMMC_TOP_CTRL_HSEN_MASK); + } else { + EMMC_TRACE("disable HighSpeed\n"); + mmio_clrbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET, + SD4_EMMC_TOP_CTRL_HSEN_MASK); + } +} + +int32_t chal_sd_stop(void) +{ + uintptr_t idm_rst_ctrl_addr = EMMC_IDM_RESET_CTRL_ADDR; + + /* Configure IO pins */ + emmc_soft_reset(); + + /* Reset the SDIO controller */ + mmio_write_32(idm_rst_ctrl_addr, 1); + SD_US_DELAY(100); + mmio_write_32(idm_rst_ctrl_addr, 0); + SD_US_DELAY(100); + + return SD_OK; +} + +/* + * Check if host supports specified capability + * returns -ve val on error, 0 if capability not supported else 1. + */ +int32_t chal_sd_check_cap(CHAL_HANDLE *sd_handle, uint32_t caps) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + if (caps & mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CAPABILITIES1_OFFSET)) + return 1; + else + return 0; +} + +int32_t chal_sd_start(CHAL_HANDLE *sd_handle, + uint32_t mode, uint32_t sd_base, uint32_t host_base) +{ + + struct sd_dev *handle; + int32_t rval = SD_FAIL; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + handle->cfg.mode = SD_PIO_MODE; /* set to PIO mode first for init */ + handle->cfg.dma = SD_DMA_OFF; + + chal_sd_setup_handler(handle, sd_base, host_base); + + /* init and start hw */ + rval = chal_sd_init(sd_handle); + if (rval != SD_OK) + return rval; + + chal_sd_clear_pending_irq(sd_handle); + + handle->ctrl.eventList = 0; + handle->cfg.mode = mode; + + return SD_OK; +} + +/* + * Function to check 8bits of err generated from auto CMD12 + */ +int32_t chal_sd_get_atuo12_error(CHAL_HANDLE *sd_handle) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + return (mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_ERRSTAT_OFFSET) & 0xFF); +} + +/* + * Read present state register + */ +uint32_t chal_sd_get_present_status(CHAL_HANDLE *sd_handle) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + return mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_PSTATE_OFFSET); +} + +/* + * Set SD bus width + */ +int32_t chal_sd_config_bus_width(CHAL_HANDLE *sd_handle, int32_t width) +{ + uint32_t ctl_val; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *)sd_handle; + + ctl_val = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET); + + switch (width) { +#ifdef DRIVER_EMMC_ENABLE_DATA_WIDTH_8BIT + case SD_BUS_DATA_WIDTH_8BIT: + ctl_val &= ~SD_BUS_DATA_WIDTH_4BIT; + ctl_val |= SD_BUS_DATA_WIDTH_8BIT; + break; +#endif + case SD_BUS_DATA_WIDTH_4BIT: + ctl_val &= ~SD_BUS_DATA_WIDTH_8BIT; + ctl_val |= SD_BUS_DATA_WIDTH_4BIT; + break; + case SD_BUS_DATA_WIDTH_1BIT: + ctl_val &= ~(SD_BUS_DATA_WIDTH_4BIT | SD_BUS_DATA_WIDTH_8BIT); + break; + default: + return SD_INV_DATA_WIDTH; + }; + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL_OFFSET, + ctl_val); + + return SD_OK; +} + +/* + * Function to enable or disable DMA control. + */ +int32_t chal_sd_set_dma(CHAL_HANDLE *sd_handle, uint32_t mode) +{ + uint32_t val; + struct sd_dev *handle; + int32_t rc; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *)sd_handle; + + if (mode) { + rc = chal_sd_check_cap(sd_handle, + SD4_EMMC_TOP_CAPABILITIES1_SDMA_MASK | + SD4_EMMC_TOP_CAPABILITIES1_ADMA2_MASK); + if (rc < 0) + return rc; + + if (rc) { + + handle->cfg.dma = mode; + val = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET); + val &= ~(SD4_EMMC_TOP_CTRL_DMASEL_MASK); + val |= handle->cfg.dma - 1; + mmio_write_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL_OFFSET, val); + return SD_OK; + } + } + handle->cfg.dma = 0; + + return SD_FAIL; +} + +/* + * Get current DMA address. + * Called only when there is no data transaction activity. + */ +uintptr_t chal_sd_get_dma_addr(CHAL_HANDLE *sd_handle) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + if (handle->cfg.dma == SD_DMA_OFF) + return 0; + + return (uintptr_t)mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_SYSADDR_OFFSET); +} + +int32_t chal_sd_send_cmd(CHAL_HANDLE *sd_handle, uint32_t cmd_idx, + uint32_t argument, uint32_t options) +{ + uint32_t cmd_mode_reg = 0; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + EMMC_TRACE("%s %d cmd:%d argReg:%x options:%x\n", + __func__, __LINE__, cmd_idx, argument, options); + + /* Configure the value for command and mode registers */ + cmd_mode_reg = (cmd_idx << 24) | options; + + /* + * 1. Write block size reg & block count reg, + * this is done in the tx or rx setup + */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_BLOCK_OFFSET, + handle->ctrl.blkReg); + + /* 2. Write argument reg */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_ARG_OFFSET, + argument); + handle->ctrl.argReg = argument; + + /* + * 3. Write transfer mode reg & command reg, check the DMA bit which is + * set before this function call if it is selected. + */ + if (cmd_idx == 24 || cmd_idx == 25 || cmd_idx == 18 || cmd_idx == 17 || + cmd_idx == 42 || cmd_idx == 51 || cmd_idx == 53) + cmd_mode_reg |= ((handle->cfg.dma) ? 1 : 0); + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CMD_OFFSET, + cmd_mode_reg); + + handle->ctrl.cmdIndex = cmd_idx; + + return SD_OK; +} + +int32_t chal_sd_set_dma_addr(CHAL_HANDLE *sd_handle, uintptr_t address) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + if (handle->cfg.dma == SD_DMA_OFF) + return SD_FAIL; + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_SYSADDR_OFFSET, + address); + return SD_OK; +} + +uint32_t chal_sd_freq_2_div_ctrl_setting(uint32_t desired_freq) +{ + /* + * Divider control setting represents 1/2 of the actual divider value. + * + * DesiredFreq = BaseClockFreq / (2 * div_ctrl_setting) + * + * ==> div_ctrl_setting = BaseClockFreq / (2 * DesiredFreq) + */ + uint32_t div_ctrl_setting; + uint32_t actual_freq; + + assert(desired_freq != 0); + + /* Special case, 0 = divider of 1. */ + if (desired_freq >= BASE_CLK_FREQ) + return 0; + + /* Normal case, desired_freq < BASE_CLK_FREQ */ + div_ctrl_setting = BASE_CLK_FREQ / (2 * desired_freq); + + actual_freq = BASE_CLK_FREQ / (2 * div_ctrl_setting); + + if (actual_freq > desired_freq) { + /* + * Division does not result in exact freqency match. + * Make sure resulting frequency does not exceed requested freq. + */ + div_ctrl_setting++; + } + + return div_ctrl_setting; +} + +int32_t chal_sd_set_clock(CHAL_HANDLE *sd_handle, uint32_t div_ctrl_setting, + uint32_t on) +{ + uint32_t value; + struct sd_dev *handle; + uint32_t time; + uint32_t clk_sel_high_byte = 0xFF & (div_ctrl_setting >> 8); + uint32_t clk_sel_low_byte = 0xFF & div_ctrl_setting; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + EMMC_TRACE("set_clock(div_ctrl_setting=%d,on=%d)\n", + div_ctrl_setting, on); + + handle = (struct sd_dev *) sd_handle; + + /* Read control register content. */ + value = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + + /* Disable Clock */ + value &= ~(SD4_EMMC_TOP_CTRL1_SDCLKEN_MASK); + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET, + value); + + /* Clear bits of interest. */ + value &= ~(SD4_EMMC_TOP_CTRL1_SDCLKSEL_MASK | + SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_MASK); + + /* Set bits of interest to new value. */ + value |= (SD4_EMMC_TOP_CTRL1_SDCLKSEL_MASK & + (clk_sel_low_byte << SD4_EMMC_TOP_CTRL1_SDCLKSEL_SHIFT)); + value |= (SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_MASK & + (clk_sel_high_byte << SD4_EMMC_TOP_CTRL1_SDCLKSEL_UP_SHIFT)); + value |= SD4_EMMC_TOP_CTRL1_ICLKEN_MASK; + + /* Write updated value back to control register. */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET, + value); + + time = 0; + do { + value = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + + if ((value & SD4_EMMC_TOP_CTRL1_ICLKSTB_MASK) == + SD4_EMMC_TOP_CTRL1_ICLKSTB_MASK) + break; + + mdelay(1); + } while (time++ < EMMC_CLOCK_SETTING_TIMEOUT_MS); + + if (time >= EMMC_CLOCK_SETTING_TIMEOUT_MS) + WARN("%s %d clock settings timeout happenedi (%dms)\n", + __func__, __LINE__, time); + + VERBOSE("EMMC: clock settings delay: %dms\n", time); + + value = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + + if (on) + value |= SD4_EMMC_TOP_CTRL1_SDCLKEN_MASK; + + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET, + value); + + return SD_OK; +} + +/* + * function to setup DMA buffer and data length, calculates block + * size and the number of blocks to be transferred and return + * the DMA buffer address. + */ +int32_t chal_sd_setup_xfer(CHAL_HANDLE *sd_handle, + uint8_t *data, uint32_t length, int32_t dir) +{ + uint32_t blocks = 0; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + if (length <= handle->cfg.blockSize) { + handle->ctrl.blkReg = length | handle->cfg.dmaBoundary; + } else { + blocks = length / handle->cfg.blockSize; + handle->ctrl.blkReg = (blocks << 16) | handle->cfg.blockSize | + handle->cfg.dmaBoundary; + } + + if (handle->cfg.dma != SD_DMA_OFF) { + /* For DMA target address setting, physical address should be used */ + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_SYSADDR_OFFSET, + (uintptr_t)data); + } + + return SD_OK; +} + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE +/* + * function to write one block data directly to the + * host controller's FIFO which is 1K uint8_t or + * 2K uint8_t in size. + * It is used in Non-DMA mode for data transmission. + */ +int32_t chal_sd_write_buffer(CHAL_HANDLE *sd_handle, uint32_t length, + uint8_t *data) +{ + uint32_t i, leftOver = 0, blockSize, size, value = 0; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + blockSize = handle->cfg.blockSize; + + if (length == 0) + return SD_OK; + + /* PIO mode, push into fifo word by word */ + if (length >= blockSize) { + size = blockSize; + } else { + size = ((length >> 2) << 2); + leftOver = length % 4; + } + + for (i = 0; i < size; i += 4) { + value = *(uint32_t *)(data + i); + mmio_write_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BUFDAT_OFFSET, value); + } +/* + * BUG ALERT: + * This implementation has TWO issues that must be addressed before you + * can safely INCLUDE_EMMC_DRIVER_WRITE_CODE. + * + * (1) For the last leftOver bytes, driver writes full word, which means + * some of the eMMC content (i.e. "4 - leftOver" will be erroneously + * overwritten). + * (2) eMMC is a block device. What happens when less than a full block of + * data is submitted??? + */ + if (leftOver > 0) { + value = ((*(uint32_t *)(data + i)) << (4 - leftOver)); + mmio_write_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BUFDAT_OFFSET, value); + } + + return SD_OK; +} +#endif /* INCLUDE_EMMC_DRIVER_WRITE_CODE */ + +/* + * Function to read maximal one block data directly + * from the data port of the host controller (FIFO). It is used + * in Non-DMA mode for data transmission. + */ +int32_t chal_sd_read_buffer(CHAL_HANDLE *sd_handle, uint32_t length, + uint8_t *data) +{ + uint32_t i, size, leftOver, blockSize, value; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *)sd_handle; + + value = 0; + + blockSize = handle->cfg.blockSize; + + /* PIO mode, extract fifo word by word */ + if (length >= blockSize) { + size = blockSize; + leftOver = 0; + } else { + leftOver = length % 4; + size = ((length >> 2) << 2); + } + + for (i = 0; i < size; i += 4) { + value = + mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BUFDAT_OFFSET); + memcpy((void *)(data + i), &value, sizeof(uint32_t)); + } + + if (leftOver > 0) { + value = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BUFDAT_OFFSET); + + /* + * Copy remaining non-full word bytes. + * (We run ARM as Little Endian) + */ + uint8_t j = 0; + + for (j = 0; j < leftOver; j++) { + data[i + j] = (value >> (j * 8)) & 0xFF; + } + } + + return SD_OK; +} + +/* + * Resets both DAT or CMD line. + */ +int32_t chal_sd_reset_line(CHAL_HANDLE *sd_handle, uint32_t line) +{ + uint32_t control, flag; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + flag = SD4_EMMC_TOP_CTRL1_CMDRST_MASK | SD4_EMMC_TOP_CTRL1_DATRST_MASK; + + if (flag != (line | flag)) + return SD_FAIL; + + control = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + control |= line; + mmio_write_32(handle->ctrl.sdRegBaseAddr + SD4_EMMC_TOP_CTRL1_OFFSET, + control); + + /* reset CMD and DATA line should always work, no need to timed out */ + do { + control = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_CTRL1_OFFSET); + } while (control & line); + + return SD_OK; +} + +/* + * Function to be called once a SD command is done to read + * back it's response data. + */ +int32_t chal_sd_get_response(CHAL_HANDLE *sd_handle, uint32_t *resp) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + resp[0] = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_RESP0_OFFSET); + resp[1] = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_RESP2_OFFSET); + resp[2] = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_RESP4_OFFSET); + resp[3] = mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_RESP6_OFFSET); + + return SD_OK; +} + +/* + * The function is called to clean all the pending interrupts. + */ +int32_t chal_sd_clear_pending_irq(CHAL_HANDLE *sd_handle) +{ + uint32_t status = SD_OK; + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *)sd_handle; + + /* Make sure clean all interrupts */ + do { + mmio_write_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET, 0xFFFFFFFF); + SD_US_DELAY(10); + } while (mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET)); + + return status; +} + +/* + * The function returns interrupt status register value. + */ +int32_t chal_sd_get_irq_status(CHAL_HANDLE *sd_handle) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + return (mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET)); +} + +/* + * The function clears interrupt(s) specified in the mask. + */ +int32_t chal_sd_clear_irq(CHAL_HANDLE *sd_handle, uint32_t mask) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + /* Make sure clean masked interrupts */ + do { + mmio_write_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET, mask); + SD_US_DELAY(10); + } while (mask & + mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTR_OFFSET)); + + return SD_OK; +} + +/* + * Description: The function configures the SD host controller. + */ +int32_t chal_sd_config(CHAL_HANDLE *sd_handle, uint32_t speed, uint32_t retry, + uint32_t boundary, uint32_t blkSize, uint32_t dma) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return SD_INVALID_HANDLE; + + handle = (struct sd_dev *) sd_handle; + + handle->cfg.speedMode = speed; + handle->cfg.retryLimit = retry; + handle->cfg.dmaBoundary = boundary; + handle->cfg.blockSize = blkSize; + + chal_sd_set_dma(sd_handle, dma); + SD_US_DELAY(100); + chal_sd_set_dma_boundary(handle, boundary); + SD_US_DELAY(100); + + chal_sd_set_speed(sd_handle, speed); + + SD_US_DELAY(100); + return SD_OK; +} + +/* + * Cleans up HC FIFO. + */ +void chal_sd_dump_fifo(CHAL_HANDLE *sd_handle) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return; + + handle = (struct sd_dev *)sd_handle; + + /* in case there still data in the host buffer */ + while (mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_PSTATE_OFFSET) & 0x800) { + mmio_read_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_BUFDAT_OFFSET); + }; +} + +/* + * Enable or disable a SD interrupt signal. + */ +void chal_sd_set_irq_signal(CHAL_HANDLE *sd_handle, uint32_t mask, + uint32_t state) +{ + struct sd_dev *handle; + + if (sd_handle == NULL) + return; + + handle = (struct sd_dev *)sd_handle; + + if (state) + mmio_setbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTREN2_OFFSET, mask); + else + mmio_clrbits_32(handle->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_INTREN2_OFFSET, mask); +} diff --git a/drivers/brcm/emmc/emmc_csl_sdcard.c b/drivers/brcm/emmc/emmc_csl_sdcard.c new file mode 100644 index 0000000..9e2c618 --- /dev/null +++ b/drivers/brcm/emmc/emmc_csl_sdcard.c @@ -0,0 +1,1089 @@ +/* + * Copyright (c) 2016 - 2020, Broadcom + * + * SPDX-License-Identifier: BSD-3-Clause + */ + +#include <inttypes.h> +#include <stddef.h> +#include <stdint.h> +#include <stdlib.h> +#include <string.h> + +#include <arch_helpers.h> +#include <lib/mmio.h> + +#include "bcm_emmc.h" +#include "emmc_chal_types.h" +#include "emmc_csl_sdprot.h" +#include "emmc_chal_sd.h" +#include "emmc_csl_sdcmd.h" +#include "emmc_csl_sd.h" +#include "emmc_pboot_hal_memory_drv.h" + +#define SD_CARD_BUSY 0x80000000 +#define SD_CARD_RETRY_LIMIT 1000 +#define SD_CARD_HIGH_SPEED_PS 13 +#define SD_CHK_HIGH_SPEED_MODE 0x00FFFFF1 +#define SD_SET_HIGH_SPEED_MODE 0x80FFFFF1 +#define SD_MMC_ENABLE_HIGH_SPEED 0x03b90100 //0x03b90103 +#define SD_MMC_8BIT_MODE 0x03b70200 +#define SD_MMC_4BIT_MODE 0x03b70100 +#define SD_MMC_1BIT_MODE 0x03b70000 + +#define SD_MMC_BOOT_8BIT_MODE 0x03b10200 +#define SD_MMC_BOOT_4BIT_MODE 0x03b10100 +#define SD_MMC_BOOT_1BIT_MODE 0x03b10000 +#define SDIO_HW_EMMC_EXT_CSD_BOOT_CNF 0X03B30000 + +#ifdef USE_EMMC_FIP_TOC_CACHE +/* + * Cache size mirrors the size of the global eMMC temp buffer + * which is used for non-image body reads such as headers, ToC etc. + */ +#define CACHE_SIZE ((EMMC_BLOCK_SIZE) * 2) +#define PARTITION_BLOCK_ADDR ((PLAT_FIP_ATTEMPT_OFFSET)/(EMMC_BLOCK_SIZE)) + +static uint32_t cached_partition_block; +static uint8_t cached_block[CACHE_SIZE]; +#endif + +static int set_card_data_width(struct sd_handle *handle, int width); +static int abort_err(struct sd_handle *handle); +static int err_recovery(struct sd_handle *handle, uint32_t errors); +static int xfer_data(struct sd_handle *handle, uint32_t mode, uint32_t addr, + uint32_t length, uint8_t *base); + +int set_boot_config(struct sd_handle *handle, uint32_t config) +{ + return mmc_cmd6(handle, SDIO_HW_EMMC_EXT_CSD_BOOT_CNF | config); +} + +void process_csd_mmc_speed(struct sd_handle *handle, uint32_t csd_mmc_speed) +{ + uint32_t div_ctrl_setting; + + /* CSD field TRAN_SPEED: + * Bits [2:0] 0 = 100 KHz + * 1 = 1 MHz + * 2 = 10 MHz + * 3 = 100 MHz + * 4...7 Reserved. + * Bits [6:3] 0 = Reserved + * 1 = 1.0 + * 2 = 1.2 + * 3 = 1.3 + * 4 = 1.5 + * 5 = 2.0 + * 6 = 2.6 + * 7 = 3.0 + * 8 = 3.5 + * 9 = 4.0 + * A = 4.5 + * B = 5.2 + * C = 5.5 + * D = 6.0 + * E = 7.0 + * F = 8.0 + * For cards supporting version 4.0, 4.1, and 4.2 of the standard, + * the value shall be 20 MHz (0x2A). + * For cards supporting version 4.3 , the value shall be 26 MHz (0x32) + */ + + switch (csd_mmc_speed & 0x7F) { + case 0x2A: + EMMC_TRACE("Speeding up eMMC clock to 20MHz\n"); + div_ctrl_setting = + chal_sd_freq_2_div_ctrl_setting(20 * 1000 * 1000); + break; + case 0x32: + EMMC_TRACE("Speeding up eMMC clock to 26MHz\n"); + div_ctrl_setting = + chal_sd_freq_2_div_ctrl_setting(26 * 1000 * 1000); + break; + default: + /* Unknown */ + return; + } + + chal_sd_set_clock((CHAL_HANDLE *) handle->device, div_ctrl_setting, 0); + + chal_sd_set_clock((CHAL_HANDLE *) handle->device, div_ctrl_setting, 1); + + SD_US_DELAY(1000); +} + + +/* + * The function changes SD/SDIO/MMC card data width if + * the card support configurable data width. The host controller + * and the card has to be in the same bus data width. + */ +int set_card_data_width(struct sd_handle *handle, int width) +{ + uint32_t data_width = 0; + int is_valid_arg = 1; + int rc = SD_FAIL; + char *bitwidth_str = " "; + char *result_str = "failed"; + + switch (width) { +#ifdef DRIVER_EMMC_ENABLE_DATA_WIDTH_8BIT + case SD_BUS_DATA_WIDTH_8BIT: + data_width = SD_MMC_8BIT_MODE; +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + bitwidth_str = "8_BIT"; +#endif + break; +#endif + case SD_BUS_DATA_WIDTH_4BIT: + data_width = SD_MMC_4BIT_MODE; +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + bitwidth_str = "4_BIT"; +#endif + break; + + case SD_BUS_DATA_WIDTH_1BIT: + data_width = SD_MMC_1BIT_MODE; +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + bitwidth_str = "1_BIT"; +#endif + break; + + default: + is_valid_arg = 0; +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + bitwidth_str = "unknown"; +#endif + break; + } + + if (is_valid_arg) { + rc = mmc_cmd6(handle, data_width); + if (rc == SD_OK) { +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + result_str = "succeeded"; +#endif + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + width); + } else { +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + result_str = "failed"; +#endif + } + } else { + rc = SD_FAIL; +#if LOG_LEVEL >= LOG_LEVEL_VERBOSE + result_str = "ignored"; +#endif + } + + VERBOSE("SDIO Data Width(%s) %s.\n", bitwidth_str, result_str); + + return rc; +} + + +/* + * Error handling routine. Does abort data + * transmission if error is found. + */ +static int abort_err(struct sd_handle *handle) +{ + uint32_t present, options, event, rel = 0; + struct sd_resp cmdRsp; + + handle->device->ctrl.argReg = 0; + handle->device->ctrl.cmdIndex = SD_CMD_STOP_TRANSMISSION; + + options = (SD_CMD_STOP_TRANSMISSION << 24) | + (SD_CMDR_RSP_TYPE_R1b_5b << SD_CMDR_RSP_TYPE_S) | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + chal_sd_send_cmd((CHAL_HANDLE *) handle->device, + handle->device->ctrl.cmdIndex, + handle->device->ctrl.argReg, options); + + event = wait_for_event(handle, + SD4_EMMC_TOP_INTR_CMDDONE_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (event & SD_CMD_ERROR_INT) { + rel = SD_ERROR_NON_RECOVERABLE; + } else { + if (event & SD_DAT_TIMEOUT) { + return SD_ERROR_NON_RECOVERABLE; + } + + chal_sd_get_response((CHAL_HANDLE *) handle->device, + (uint32_t *)&cmdRsp); + + process_cmd_response(handle, handle->device->ctrl.cmdIndex, + cmdRsp.data.r2.rsp1, cmdRsp.data.r2.rsp2, + cmdRsp.data.r2.rsp3, cmdRsp.data.r2.rsp4, + &cmdRsp); + + SD_US_DELAY(2000); + + present = + chal_sd_get_present_status((CHAL_HANDLE *) handle->device); + + if ((present & 0x00F00000) == 0x00F00000) + rel = SD_ERROR_RECOVERABLE; + else + rel = SD_ERROR_NON_RECOVERABLE; + } + + return rel; +} + + +/* + * The function handles real data transmission on both DMA and + * none DMA mode, In None DMA mode the data transfer starts + * when the command is sent to the card, data has to be written + * into the host contollers buffer at this time one block + * at a time. + * In DMA mode, the real data transfer is done by the DMA engine + * and this functions just waits for the data transfer to complete. + * + */ +int process_data_xfer(struct sd_handle *handle, uint8_t *buffer, uint32_t addr, + uint32_t length, int dir) +{ + if (dir == SD_XFER_HOST_TO_CARD) { +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE + if (handle->device->cfg.dma == SD_DMA_OFF) { + /* + * In NON DMA mode, the real data xfer starts from here + */ + if (write_buffer(handle, length, buffer)) + return SD_WRITE_ERROR; + } else { + wait_for_event(handle, + SD4_EMMC_TOP_INTR_TXDONE_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus == SD_OK) + return SD_OK; + + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_WRITE_ERROR; + } +#else + return SD_WRITE_ERROR; +#endif + } else { /* SD_XFER_CARD_TO_HOST */ + + if (handle->device->cfg.dma == SD_DMA_OFF) { + /* In NON DMA mode, the real data + * transfer starts from here + */ + if (read_buffer(handle, length, buffer)) + return SD_READ_ERROR; + + } else { /* for DMA mode */ + + /* + * once the data transmission is done + * copy data to the host buffer. + */ + wait_for_event(handle, + SD4_EMMC_TOP_INTR_TXDONE_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus == SD_OK) + return SD_OK; + + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_READ_ERROR; + } + } + return SD_OK; +} + + +/* + * The function sets block size for the next SD/SDIO/MMC + * card read/write command. + */ +int select_blk_sz(struct sd_handle *handle, uint16_t size) +{ + return sd_cmd16(handle, size); +} + + +/* + * The function initalizes the SD/SDIO/MMC/CEATA and detects + * the card according to the flag of detection. + * Once this function is called, the card is put into ready state + * so application can do data transfer to and from the card. + */ +int init_card(struct sd_handle *handle, int detection) +{ + /* + * After Reset, eMMC comes up in 1 Bit Data Width by default. + * Set host side to match. + */ + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + SD_BUS_DATA_WIDTH_1BIT); + +#ifdef USE_EMMC_FIP_TOC_CACHE + cached_partition_block = 0; +#endif + handle->device->ctrl.present = 0; /* init card present to be no card */ + + init_mmc_card(handle); + + handle->device->ctrl.present = 1; /* card is detected */ + + /* switch the data width back */ + if (handle->card->type != SD_CARD_MMC) + return SD_FAIL; + + /* + * Dynamically set Data Width to highest supported value. + * Try different data width settings (highest to lowest). + * Verify each setting by reading EXT_CSD and comparing + * against the EXT_CSD contents previously read in call to + * init_mmc_card() earlier. Stop at first verified data width + * setting. + */ + { +#define EXT_CSD_PROPERTIES_SECTION_START_INDEX 192 +#define EXT_CSD_PROPERTIES_SECTION_END_INDEX 511 + uint8_t buffer[EXT_CSD_SIZE]; +#ifdef DRIVER_EMMC_ENABLE_DATA_WIDTH_8BIT + /* Try 8 Bit Data Width */ + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + SD_BUS_DATA_WIDTH_8BIT); + if ((!set_card_data_width(handle, SD_BUS_DATA_WIDTH_8BIT)) && + (!mmc_cmd8(handle, buffer)) && + (!memcmp(&buffer[EXT_CSD_PROPERTIES_SECTION_START_INDEX], + &(emmc_global_buf_ptr->u.Ext_CSD_storage[EXT_CSD_PROPERTIES_SECTION_START_INDEX]), + EXT_CSD_PROPERTIES_SECTION_END_INDEX - EXT_CSD_PROPERTIES_SECTION_START_INDEX + 1))) + + return SD_OK; +#endif + /* Fall back to 4 Bit Data Width */ + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + SD_BUS_DATA_WIDTH_4BIT); + if ((!set_card_data_width(handle, SD_BUS_DATA_WIDTH_4BIT)) && + (!mmc_cmd8(handle, buffer)) && + (!memcmp(&buffer[EXT_CSD_PROPERTIES_SECTION_START_INDEX], + &(emmc_global_buf_ptr->u.Ext_CSD_storage[EXT_CSD_PROPERTIES_SECTION_START_INDEX]), + EXT_CSD_PROPERTIES_SECTION_END_INDEX - EXT_CSD_PROPERTIES_SECTION_START_INDEX + 1))) + + return SD_OK; + + /* Fall back to 1 Bit Data Width */ + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + SD_BUS_DATA_WIDTH_1BIT); + /* Just use 1 Bit Data Width then. */ + if (!set_card_data_width(handle, SD_BUS_DATA_WIDTH_1BIT)) + return SD_OK; + + } + return SD_CARD_INIT_ERROR; +} + + +/* + * The function handles MMC/CEATA card initalization. + */ +int init_mmc_card(struct sd_handle *handle) +{ + uint32_t ocr = 0, newOcr, rc, limit = 0; + uint32_t cmd1_option = 0x40300000; + uint32_t sec_count; + + handle->card->type = SD_CARD_MMC; + + do { + SD_US_DELAY(1000); + newOcr = 0; + ocr = 0; + rc = sd_cmd1(handle, cmd1_option, &newOcr); + limit++; + + if (rc == SD_OK) + ocr = newOcr; + + } while (((ocr & SD_CARD_BUSY) == 0) && (limit < SD_CARD_RETRY_LIMIT)); + + if (limit >= SD_CARD_RETRY_LIMIT) { + handle->card->type = SD_CARD_UNKNOWN; + EMMC_TRACE("CMD1 Timeout: Device is not ready\n"); + return SD_CARD_UNKNOWN; + } + + /* Save the ocr register */ + handle->device->ctrl.ocr = ocr; + + /* Ready State */ + rc = sd_cmd2(handle); + if (rc != SD_OK) { + handle->card->type = SD_CARD_UNKNOWN; + return SD_CARD_UNKNOWN; + } + + rc = sd_cmd3(handle); + if (rc != SD_OK) { + handle->card->type = SD_CARD_UNKNOWN; + return SD_CARD_UNKNOWN; + } + /* read CSD */ + rc = sd_cmd9(handle, &emmc_global_vars_ptr->cardData); + if (rc != SD_OK) { + handle->card->type = SD_CARD_UNKNOWN; + return SD_CARD_UNKNOWN; + } + + /* Increase clock frequency according to what the card advertises */ + EMMC_TRACE("From CSD... cardData.csd.mmc.speed = 0x%X\n", + emmc_global_vars_ptr->cardData.csd.mmc.speed); + process_csd_mmc_speed(handle, + emmc_global_vars_ptr->cardData.csd.mmc.speed); + + /* goto transfer mode */ + rc = sd_cmd7(handle, handle->device->ctrl.rca); + if (rc != SD_OK) { + handle->card->type = SD_CARD_UNKNOWN; + return SD_CARD_UNKNOWN; + } + + rc = mmc_cmd8(handle, emmc_global_buf_ptr->u.Ext_CSD_storage); + if (rc == SD_OK) { + /* calcul real capacity */ + sec_count = emmc_global_buf_ptr->u.Ext_CSD_storage[212] | + emmc_global_buf_ptr->u.Ext_CSD_storage[213] << 8 | + emmc_global_buf_ptr->u.Ext_CSD_storage[214] << 16 | + emmc_global_buf_ptr->u.Ext_CSD_storage[215] << 24; + + EMMC_TRACE("Device density = %ldMBytes\n", + handle->card->size / (1024 * 1024)); + + if (sec_count > 0) { + handle->card->size = (uint64_t)sec_count * 512; + + EMMC_TRACE("Updated Device density = %ldMBytes\n", + handle->card->size / (1024 * 1024)); + } + + if (sec_count > (2u * 1024 * 1024 * 1024) / 512) { + handle->device->ctrl.ocr |= SD_CARD_HIGH_CAPACITY; + handle->device->cfg.blockSize = 512; + } + + if (handle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) + EMMC_TRACE("Sector addressing\n"); + else + EMMC_TRACE("Byte addressing\n"); + + EMMC_TRACE("Ext_CSD_storage[162]: 0x%02X Ext_CSD_storage[179]: 0x%02X\n", + emmc_global_buf_ptr->u.Ext_CSD_storage[162], + emmc_global_buf_ptr->u.Ext_CSD_storage[179]); + } + + return handle->card->type; +} + + +/* + * The function send reset command to the card. + * The card will be in ready status after the reset. + */ +int reset_card(struct sd_handle *handle) +{ + int res = SD_OK; + + /* on reset, card's RCA should return to 0 */ + handle->device->ctrl.rca = 0; + + res = sd_cmd0(handle); + + if (res != SD_OK) + return SD_RESET_ERROR; + + return res; +} + + +/* + * The function sends command to the card and starts + * data transmission. + */ +static int xfer_data(struct sd_handle *handle, + uint32_t mode, + uint32_t addr, uint32_t length, uint8_t *base) +{ + int rc = SD_OK; + + VERBOSE("XFER: dest: 0x%" PRIx64 ", addr: 0x%x, size: 0x%x bytes\n", + (uint64_t)base, addr, length); + + if ((length / handle->device->cfg.blockSize) > 1) { + if (mode == SD_OP_READ) { + inv_dcache_range((uintptr_t)base, (uint64_t)length); + rc = sd_cmd18(handle, addr, length, base); + } else { +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE + flush_dcache_range((uintptr_t)base, (uint64_t)length); + rc = sd_cmd25(handle, addr, length, base); +#else + rc = SD_DATA_XFER_ERROR; +#endif + } + } else { + if (mode == SD_OP_READ) { + inv_dcache_range((uintptr_t)base, (uint64_t)length); + rc = sd_cmd17(handle, addr, + handle->device->cfg.blockSize, base); + } else { +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE + flush_dcache_range((uintptr_t)base, (uint64_t)length); + rc = sd_cmd24(handle, addr, + handle->device->cfg.blockSize, base); +#else + rc = SD_DATA_XFER_ERROR; +#endif + } + } + + if (rc != SD_OK) + return SD_DATA_XFER_ERROR; + + return SD_OK; +} + +#ifdef INCLUDE_EMMC_DRIVER_ERASE_CODE +int erase_card(struct sd_handle *handle, uint32_t addr, uint32_t blocks) +{ + uint32_t end_addr; + + INFO("ERASE: addr: 0x%x, num of sectors: 0x%x\n", addr, blocks); + + if (sd_cmd35(handle, addr) != SD_OK) + return SD_FAIL; + + end_addr = addr + blocks - 1; + if (sd_cmd36(handle, end_addr) != SD_OK) + return SD_FAIL; + + if (sd_cmd38(handle) != SD_OK) + return SD_FAIL; + + return SD_OK; +} +#endif + +/* + * The function reads block data from a card. + */ +#ifdef USE_EMMC_FIP_TOC_CACHE +int read_block(struct sd_handle *handle, + uint8_t *dst, uint32_t addr, uint32_t len) +{ + int rel = SD_OK; + + /* + * Avoid doing repeated reads of the partition block + * by caching. + */ + if (cached_partition_block && + addr == PARTITION_BLOCK_ADDR && + len == CACHE_SIZE) { + memcpy(dst, cached_block, len); + } else { + rel = xfer_data(handle, SD_OP_READ, addr, len, dst); + + if (len == CACHE_SIZE && addr == PARTITION_BLOCK_ADDR) { + cached_partition_block = 1; + memcpy(cached_block, dst, len); + } + } + + return rel; +} +#else +int read_block(struct sd_handle *handle, + uint8_t *dst, uint32_t addr, uint32_t len) +{ + return xfer_data(handle, SD_OP_READ, addr, len, dst); +} +#endif + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE + +/* + * The function writes block data to a card. + */ +int write_block(struct sd_handle *handle, + uint8_t *src, uint32_t addr, uint32_t len) +{ + int rel = SD_OK; + + /* + * Current HC has problem to get response of cmd16 after cmd12, + * the delay is necessary to sure the next cmd16 will not be timed out. + * The delay has to be at least 4 ms. + * The code removed cmd16 and use cmd13 to get card status before + * sending cmd18 or cmd25 to make sure the card is ready and thus + * no need to have delay here. + */ + + rel = xfer_data(handle, SD_OP_WRITE, addr, len, src); + + EMMC_TRACE("wr_blk addr:0x%08X src:0x%08X len:0x%08X result:%d\n", + addr, src, len, rel); + + return rel; +} + + +/* + * The function is called to write one block data directly to + * a card's data buffer. + * it is used in Non-DMA mode for card data transmission. + */ +int write_buffer(struct sd_handle *handle, uint32_t length, uint8_t *data) +{ + uint32_t rem, blockSize, event; + uint8_t *pData = data; + + blockSize = handle->device->cfg.blockSize; + rem = length; + + if (rem == 0) + return SD_OK; + + while (rem > 0) { + + event = wait_for_event(handle, + SD4_EMMC_TOP_INTR_BWRDY_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus) { + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_WRITE_ERROR; + } + + if (rem >= blockSize) + chal_sd_write_buffer((CHAL_HANDLE *) handle->device, + blockSize, pData); + else + chal_sd_write_buffer((CHAL_HANDLE *) handle->device, + rem, pData); + + if (rem > blockSize) { + rem -= blockSize; + pData += blockSize; + } else { + pData += rem; + rem = 0; + } + } + + if ((event & SD4_EMMC_TOP_INTR_TXDONE_MASK) != + SD4_EMMC_TOP_INTR_TXDONE_MASK) { + event = wait_for_event(handle, + SD4_EMMC_TOP_INTR_TXDONE_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus != SD_OK) { + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_WRITE_ERROR; + } + } else { + handle->device->ctrl.eventList &= ~SD4_EMMC_TOP_INTR_TXDONE_MASK; + } + + return SD_OK; +} +#endif /* INCLUDE_EMMC_DRIVER_WRITE_CODE */ + + +/* + * The function is called to read maximal one block data + * directly from a card + * It is used in Non-DMA mode for card data transmission. + */ +int read_buffer(struct sd_handle *handle, uint32_t length, uint8_t *data) +{ + uint32_t rem, blockSize, event = 0; + uint8_t *pData = data; + + blockSize = handle->device->cfg.blockSize; + rem = length; + + if (rem == 0) + return SD_OK; + + while (rem > 0) { + event = wait_for_event(handle, + SD4_EMMC_TOP_INTR_BRRDY_MASK | + SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus) { + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_READ_ERROR; + } + + if (rem >= blockSize) + chal_sd_read_buffer((CHAL_HANDLE *) handle->device, + blockSize, pData); + else + chal_sd_read_buffer((CHAL_HANDLE *) handle->device, rem, + pData); + + if (rem > blockSize) { + rem -= blockSize; + pData += blockSize; + } else { + pData += rem; + rem = 0; + } + } + + /* In case, there are extra data in the SD FIFO, just dump them. */ + chal_sd_dump_fifo((CHAL_HANDLE *) handle->device); + + if ((event & SD4_EMMC_TOP_INTR_TXDONE_MASK) != + SD4_EMMC_TOP_INTR_TXDONE_MASK) { + event = wait_for_event(handle, SD4_EMMC_TOP_INTR_TXDONE_MASK, + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus) { + check_error(handle, handle->device->ctrl.cmdStatus); + return SD_READ_ERROR; + } + } else { + handle->device->ctrl.eventList &= ~SD4_EMMC_TOP_INTR_TXDONE_MASK; + } + + return SD_OK; +} + + +/* + * Error handling routine. + * The function just reset the DAT + * and CMD line if an error occures during data transmission. + */ +int check_error(struct sd_handle *handle, uint32_t ints) +{ + uint32_t rel; + + chal_sd_set_irq_signal((CHAL_HANDLE *) handle->device, + SD_ERR_INTERRUPTS, 0); + + if (ints & SD4_EMMC_TOP_INTR_CMDERROR_MASK) { + + chal_sd_reset_line((CHAL_HANDLE *) handle->device, + SD4_EMMC_TOP_CTRL1_CMDRST_MASK); + rel = abort_err(handle); + + chal_sd_reset_line((CHAL_HANDLE *) handle->device, + SD4_EMMC_TOP_CTRL1_DATRST_MASK); + chal_sd_set_irq_signal((CHAL_HANDLE *) handle->device, + SD_ERR_INTERRUPTS, 1); + + return (rel == SD_ERROR_NON_RECOVERABLE) ? + SD_ERROR_NON_RECOVERABLE : SD_ERROR_RECOVERABLE; + } else { + rel = err_recovery(handle, ints); + } + + chal_sd_set_irq_signal((CHAL_HANDLE *) handle->device, + SD_ERR_INTERRUPTS, 1); + + return rel; +} + + +/* + * Error recovery routine. + * Try to recover from the error. + */ +static int err_recovery(struct sd_handle *handle, uint32_t errors) +{ + uint32_t rel = 0; + + /* + * In case of timeout error, the cmd line and data line maybe + * still active or stuck at atcitve so it is needed to reset + * either data line or cmd line to make sure a new cmd can be sent. + */ + + if (errors & SD_CMD_ERROR_INT) + chal_sd_reset_line((CHAL_HANDLE *) handle->device, + SD4_EMMC_TOP_CTRL1_CMDRST_MASK); + + if (errors & SD_DAT_ERROR_INT) + chal_sd_reset_line((CHAL_HANDLE *) handle->device, + SD4_EMMC_TOP_CTRL1_DATRST_MASK); + + /* Abort transaction by sending out stop command */ + if ((handle->device->ctrl.cmdIndex == 18) || + (handle->device->ctrl.cmdIndex == 25)) + rel = abort_err(handle); + + return rel; +} + + +/* + * The function is called to read one block data directly from a card. + * It is used in Non-DMA mode for card data transmission. + */ +int process_cmd_response(struct sd_handle *handle, + uint32_t cmdIndex, + uint32_t rsp0, + uint32_t rsp1, + uint32_t rsp2, uint32_t rsp3, struct sd_resp *resp) +{ + int result = SD_OK; + + /* R6 */ + uint32_t rca = (rsp0 >> 16) & 0xffff; + uint32_t cardStatus = rsp0; + + /* R4 */ + uint32_t cBit = (rsp0 >> 31) & 0x1; + uint32_t funcs = (rsp0 >> 28) & 0x7; + uint32_t memPresent = (rsp0 >> 27) & 0x1; + + resp->r1 = 0x3f; + resp->cardStatus = cardStatus; + + if (cmdIndex == SD_CMD_IO_SEND_OP_COND) { + resp->data.r4.cardReady = cBit; + resp->data.r4.funcs = funcs; + resp->data.r4.memPresent = memPresent; + resp->data.r4.ocr = cardStatus; + } + + if (cmdIndex == SD_CMD_MMC_SET_RCA) { + resp->data.r6.rca = rca; + resp->data.r6.cardStatus = cardStatus & 0xFFFF; + } + + if (cmdIndex == SD_CMD_SELECT_DESELECT_CARD) { + resp->data.r7.rca = rca; + } + + if (cmdIndex == SD_CMD_IO_RW_DIRECT) { + if (((rsp0 >> 16) & 0xffff) != 0) + result = SD_CMD_ERR_INVALID_RESPONSE; + + resp->data.r5.data = rsp0 & 0xff; + } + + if (cmdIndex == SD_CMD_IO_RW_EXTENDED) { + if (((rsp0 >> 16) & 0xffff) != 0) + result = SD_CMD_ERR_INVALID_RESPONSE; + + resp->data.r5.data = rsp0 & 0xff; + } + + if (cmdIndex == SD_ACMD_SD_SEND_OP_COND || + cmdIndex == SD_CMD_SEND_OPCOND) + resp->data.r3.ocr = cardStatus; + + if (cmdIndex == SD_CMD_SEND_CSD || + cmdIndex == SD_CMD_SEND_CID || + cmdIndex == SD_CMD_ALL_SEND_CID) { + resp->data.r2.rsp4 = rsp3; + resp->data.r2.rsp3 = rsp2; + resp->data.r2.rsp2 = rsp1; + resp->data.r2.rsp1 = rsp0; + } + + if ((cmdIndex == SD_CMD_READ_EXT_CSD) && + (handle->card->type == SD_CARD_SD)) { + if ((resp->cardStatus & 0xAA) != 0xAA) { + result = SD_CMD_ERR_INVALID_RESPONSE; + } + } + + return result; +} + + +/* + * The function sets DMA buffer and data length, process + * block size and the number of blocks to be transferred. + * It returns the DMA buffer address. + * It copies dma data from user buffer to the DMA buffer + * if the operation is to write data to the SD card. + */ +void data_xfer_setup(struct sd_handle *handle, uint8_t *data, uint32_t length, + int dir) +{ + chal_sd_setup_xfer((CHAL_HANDLE *)handle->device, data, length, dir); +} + + +/* + * The function does soft reset the host SD controller. After + * the function call all host controller's register are reset + * to default vallue; + * + * Note This function only resets the host controller it does not + * reset the controller's handler. + */ +int reset_host_ctrl(struct sd_handle *handle) +{ + chal_sd_stop(); + + return SD_OK; +} + +static void pstate_log(struct sd_handle *handle) +{ + ERROR("PSTATE: 0x%x\n", mmio_read_32 + (handle->device->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_PSTATE_SD4_OFFSET)); + ERROR("ERRSTAT: 0x%x\n", mmio_read_32 + (handle->device->ctrl.sdRegBaseAddr + + SD4_EMMC_TOP_ERRSTAT_OFFSET)); +} + +/* + * The function waits for one or a group of interrupts specified + * by mask. The function returns if any one the interrupt status + * is set. If interrupt mode is not enabled then it will poll + * the interrupt status register until a interrupt status is set + * an error interrupt happens. If interrupt mode is enabled then + * this function should be called after the interrupt + * is received by ISR routine. + */ +uint32_t wait_for_event(struct sd_handle *handle, + uint32_t mask, uint32_t retry) +{ + uint32_t regval, cmd12, time = 0; + + handle->device->ctrl.cmdStatus = 0; /* no error */ + EMMC_TRACE("%s %d mask:0x%x timeout:%d irq_status:0x%x\n", + __func__, __LINE__, mask, retry, + chal_sd_get_irq_status((CHAL_HANDLE *)handle->device)); + + /* Polling mode */ + do { + regval = chal_sd_get_irq_status((CHAL_HANDLE *)handle->device); + + if (regval & SD4_EMMC_TOP_INTR_DMAIRQ_MASK) { + chal_sd_set_dma_addr((CHAL_HANDLE *)handle->device, + (uintptr_t) + chal_sd_get_dma_addr((CHAL_HANDLE *) + handle->device)); + chal_sd_clear_irq((CHAL_HANDLE *)handle->device, + SD4_EMMC_TOP_INTR_DMAIRQ_MASK); + } + + if (time++ > retry) { + ERROR("EMMC: No response (cmd%d) after %dus.\n", + handle->device->ctrl.cmdIndex, + time * EMMC_WFE_RETRY_DELAY_US); + handle->device->ctrl.cmdStatus = SD_CMD_MISSING; + pstate_log(handle); + ERROR("EMMC: INT[0x%x]\n", regval); + break; + } + + if (regval & SD4_EMMC_TOP_INTR_CTOERR_MASK) { + ERROR("EMMC: Cmd%d timeout INT[0x%x]\n", + handle->device->ctrl.cmdIndex, regval); + handle->device->ctrl.cmdStatus = + SD4_EMMC_TOP_INTR_CTOERR_MASK; + pstate_log(handle); + break; + } + if (regval & SD_CMD_ERROR_FLAGS) { + ERROR("EMMC: Cmd%d error INT[0x%x]\n", + handle->device->ctrl.cmdIndex, regval); + handle->device->ctrl.cmdStatus = SD_CMD_ERROR_FLAGS; + pstate_log(handle); + break; + } + + cmd12 = chal_sd_get_atuo12_error((CHAL_HANDLE *)handle->device); + if (cmd12) { + ERROR("EMMC: Cmd%d auto cmd12 err:0x%x\n", + handle->device->ctrl.cmdIndex, cmd12); + handle->device->ctrl.cmdStatus = cmd12; + pstate_log(handle); + break; + } + + if (SD_DATA_ERROR_FLAGS & regval) { + ERROR("EMMC: Data for cmd%d error, INT[0x%x]\n", + handle->device->ctrl.cmdIndex, regval); + handle->device->ctrl.cmdStatus = + (SD_DATA_ERROR_FLAGS & regval); + pstate_log(handle); + break; + } + + if ((regval & mask) == 0) + udelay(EMMC_WFE_RETRY_DELAY_US); + + } while ((regval & mask) == 0); + + /* clear the interrupt since it is processed */ + chal_sd_clear_irq((CHAL_HANDLE *)handle->device, (regval & mask)); + + return (regval & mask); +} + +int32_t set_config(struct sd_handle *handle, uint32_t speed, uint32_t retry, + uint32_t dma, uint32_t dmaBound, uint32_t blkSize, + uint32_t wfe_retry) +{ + int32_t rel = 0; + + if (handle == NULL) + return SD_FAIL; + + handle->device->cfg.wfe_retry = wfe_retry; + + rel = chal_sd_config((CHAL_HANDLE *)handle->device, speed, retry, + dmaBound, blkSize, dma); + return rel; + +} + +int mmc_cmd1(struct sd_handle *handle) +{ + uint32_t newOcr, res; + uint32_t cmd1_option = MMC_OCR_OP_VOLT | MMC_OCR_SECTOR_ACCESS_MODE; + + /* + * After Reset, eMMC comes up in 1 Bit Data Width by default. + * Set host side to match. + */ + chal_sd_config_bus_width((CHAL_HANDLE *) handle->device, + SD_BUS_DATA_WIDTH_1BIT); + +#ifdef USE_EMMC_FIP_TOC_CACHE + cached_partition_block = 0; +#endif + handle->device->ctrl.present = 0; /* init card present to be no card */ + + handle->card->type = SD_CARD_MMC; + + res = sd_cmd1(handle, cmd1_option, &newOcr); + + if (res != SD_OK) { + EMMC_TRACE("CMD1 Timeout: Device is not ready\n"); + res = SD_CARD_UNKNOWN; + } + return res; +} diff --git a/drivers/brcm/emmc/emmc_csl_sdcmd.c b/drivers/brcm/emmc/emmc_csl_sdcmd.c new file mode 100644 index 0000000..c62886c --- /dev/null +++ b/drivers/brcm/emmc/emmc_csl_sdcmd.c @@ -0,0 +1,842 @@ +/* + * Copyright (c) 2016 - 2020, Broadcom + * + * SPDX-License-Identifier: BSD-3-Clause + */ + +#include <stdlib.h> +#include <stddef.h> + +#include "bcm_emmc.h" +#include "emmc_chal_types.h" +#include "emmc_chal_sd.h" +#include "emmc_csl_sdprot.h" +#include "emmc_csl_sdcmd.h" +#include "emmc_csl_sd.h" +#include "emmc_chal_sd.h" +#include "emmc_pboot_hal_memory_drv.h" + +int sd_cmd0(struct sd_handle *handle) +{ + int res; + uint32_t argument = 0x0; /* Go to IDLE state. */ + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_GO_IDLE_STATE, argument, 0, NULL); + + if (res == SD_OK) { + /* Clear all other interrupts */ + chal_sd_clear_irq((void *)handle->device, 0xffffffff); + } + + return res; +} + +int sd_cmd1(struct sd_handle *handle, uint32_t ocr, uint32_t *ocr_output) +{ + int res; + uint32_t options; + struct sd_resp resp; + + options = SD_CMDR_RSP_TYPE_R3_4 << SD_CMDR_RSP_TYPE_S; + + if (ocr_output == NULL) { + EMMC_TRACE("Invalid args\n"); + return SD_FAIL; + } + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_SEND_OPCOND, ocr, options, &resp); + + if (res == SD_OK) + *ocr_output = resp.data.r3.ocr; + + return res; +} + +int sd_cmd2(struct sd_handle *handle) +{ + uint32_t options; + struct sd_resp resp; + + /* send cmd and parse result */ + options = SD_CMDR_RSP_TYPE_R2 << SD_CMDR_RSP_TYPE_S; + + return send_cmd(handle, SD_CMD_ALL_SEND_CID, 0, options, &resp); +} + +int sd_cmd3(struct sd_handle *handle) +{ + int res; + uint32_t options = 0; + uint32_t argument; + struct sd_resp resp; + + /* use non zero and non 0x1 value for rca */ + handle->device->ctrl.rca = 0x5; + argument = handle->device->ctrl.rca << SD_CMD7_ARG_RCA_SHIFT; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | + SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_MMC_SET_RCA, argument, options, &resp); + + if (res != SD_OK) + handle->device->ctrl.rca = 0; + + return res; +} + +int sd_cmd7(struct sd_handle *handle, uint32_t rca) +{ + int res; + uint32_t argument, options; + struct sd_resp resp; + + argument = (rca << SD_CMD7_ARG_RCA_SHIFT); + + /* + * Response to CMD7 is: + * R1 while selectiing from Stand-By State to Transfer State + * R1b while selecting from Disconnected State to Programming State. + * + * In this driver, we only issue a CMD7 once, to go to transfer mode + * during init_mmc_card(). + */ + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | + SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_SELECT_DESELECT_CARD, argument, options, + &resp); + + if (res == SD_OK) + /* Clear all other interrupts */ + chal_sd_clear_irq((void *)handle->device, 0xffffffff); + + return res; +} + + +/* + * CMD8 Get CSD_EXT + */ +int mmc_cmd8(struct sd_handle *handle, uint8_t *extCsdReg) +{ + uint32_t res, options; + struct sd_resp resp; + + data_xfer_setup(handle, extCsdReg, CEATA_EXT_CSDBLOCK_SIZE, + SD_XFER_CARD_TO_HOST); + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_DPS_MASK | SD4_EMMC_TOP_CMD_DTDS_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_READ_EXT_CSD, 0, options, &resp); + + if (res == SD_OK) + res = process_data_xfer(handle, extCsdReg, 0, + CEATA_EXT_CSDBLOCK_SIZE, + SD_XFER_CARD_TO_HOST); + + return res; +} + +int sd_cmd9(struct sd_handle *handle, struct sd_card_data *card) +{ + int res; + uint32_t argument, options, iBlkNum, multiFactor = 1; + uint32_t maxReadBlockLen = 1, maxWriteBlockLen = 1; + struct sd_resp resp; + + argument = handle->device->ctrl.rca << SD_CMD7_ARG_RCA_SHIFT; + + options = SD_CMDR_RSP_TYPE_R2 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_SEND_CSD, argument, options, &resp); + + if (res != SD_OK) + return res; + + if (handle->card->type == SD_CARD_MMC) { + card->csd.mmc.structure = (resp.data.r2.rsp4 >> 22) & 0x3; + card->csd.mmc.csdSpecVer = (resp.data.r2.rsp4 >> 18) & 0x0f; + card->csd.mmc.taac = (resp.data.r2.rsp4 >> 8) & 0xff; + card->csd.mmc.nsac = resp.data.r2.rsp4 & 0xff; + card->csd.mmc.speed = resp.data.r2.rsp3 >> 24; + card->csd.mmc.classes = (resp.data.r2.rsp3 >> 12) & 0xfff; + card->csd.mmc.rdBlkLen = (resp.data.r2.rsp3 >> 8) & 0xf; + card->csd.mmc.rdBlkPartial = (resp.data.r2.rsp3 >> 7) & 0x01; + card->csd.mmc.wrBlkMisalign = (resp.data.r2.rsp3 >> 6) & 0x1; + card->csd.mmc.rdBlkMisalign = (resp.data.r2.rsp3 >> 5) & 0x1; + card->csd.mmc.dsr = (resp.data.r2.rsp2 >> 4) & 0x01; + card->csd.mmc.size = + ((resp.data.r2.rsp3 & 0x3) << 10) + + ((resp.data.r2.rsp2 >> 22) & 0x3ff); + card->csd.mmc.vddRdCurrMin = (resp.data.r2.rsp2 >> 19) & 0x7; + card->csd.mmc.vddRdCurrMax = (resp.data.r2.rsp2 >> 16) & 0x7; + card->csd.mmc.vddWrCurrMin = (resp.data.r2.rsp2 >> 13) & 0x7; + card->csd.mmc.vddWrCurrMax = (resp.data.r2.rsp2 >> 10) & 0x7; + card->csd.mmc.devSizeMulti = (resp.data.r2.rsp2 >> 7) & 0x7; + card->csd.mmc.eraseGrpSize = (resp.data.r2.rsp2 >> 2) & 0x1f; + card->csd.mmc.eraseGrpSizeMulti = + ((resp.data.r2.rsp2 & 0x3) << 3) + + ((resp.data.r2.rsp1 >> 29) & 0x7); + card->csd.mmc.wrProtGroupSize = + ((resp.data.r2.rsp1 >> 24) & 0x1f); + card->csd.mmc.wrProtGroupEnable = + (resp.data.r2.rsp1 >> 23) & 0x1; + card->csd.mmc.manuDefEcc = (resp.data.r2.rsp1 >> 21) & 0x3; + card->csd.mmc.wrSpeedFactor = (resp.data.r2.rsp1 >> 18) & 0x7; + card->csd.mmc.wrBlkLen = (resp.data.r2.rsp1 >> 14) & 0xf; + card->csd.mmc.wrBlkPartial = (resp.data.r2.rsp1 >> 13) & 0x1; + card->csd.mmc.protAppl = (resp.data.r2.rsp1 >> 8) & 0x1; + card->csd.mmc.copyFlag = (resp.data.r2.rsp1 >> 7) & 0x1; + card->csd.mmc.permWrProt = (resp.data.r2.rsp1 >> 6) & 0x1; + card->csd.mmc.tmpWrProt = (resp.data.r2.rsp1 >> 5) & 0x1; + card->csd.mmc.fileFormat = (resp.data.r2.rsp1 >> 4) & 0x03; + card->csd.mmc.eccCode = resp.data.r2.rsp1 & 0x03; + maxReadBlockLen <<= card->csd.mmc.rdBlkLen; + maxWriteBlockLen <<= card->csd.mmc.wrBlkLen; + + iBlkNum = card->csd.mmc.size + 1; + multiFactor = (1 << (card->csd.mmc.devSizeMulti + 2)); + + handle->card->size = + iBlkNum * multiFactor * (1 << card->csd.mmc.rdBlkLen); + } + + handle->card->maxRdBlkLen = maxReadBlockLen; + handle->card->maxWtBlkLen = maxWriteBlockLen; + + if (handle->card->size < 0xA00000) { + /* + * 10MB Too small size mean, cmd9 response is wrong, + * Use default value 1G + */ + handle->card->size = 0x40000000; + handle->card->maxRdBlkLen = 512; + handle->card->maxWtBlkLen = 512; + } + + if ((handle->card->maxRdBlkLen > 512) || + (handle->card->maxWtBlkLen > 512)) { + handle->card->maxRdBlkLen = 512; + handle->card->maxWtBlkLen = 512; + } else if ((handle->card->maxRdBlkLen == 0) || + (handle->card->maxWtBlkLen == 0)) { + handle->card->maxRdBlkLen = 512; + handle->card->maxWtBlkLen = 512; + } + + handle->device->cfg.blockSize = handle->card->maxRdBlkLen; + + return res; +} + +int sd_cmd13(struct sd_handle *handle, uint32_t *status) +{ + int res; + uint32_t argument, options; + struct sd_resp resp; + + argument = handle->device->ctrl.rca << SD_CMD7_ARG_RCA_SHIFT; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | + SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_SEND_STATUS, argument, options, &resp); + + if (res == SD_OK) { + *status = resp.cardStatus; + } + + return res; +} + +int sd_cmd16(struct sd_handle *handle, uint32_t length) +{ + int res; + uint32_t argument, options, ntry; + struct sd_resp resp; + + argument = length; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + ntry = 0; + do { + res = sd_cmd13(handle, &resp.cardStatus); + if (res != SD_OK) { + EMMC_TRACE( + "cmd13 failed before cmd16: rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, resp.cardStatus); + return res; + } + + if (resp.cardStatus & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd16\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + + } while (1); + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_SET_BLOCKLEN, argument, options, &resp); + + return res; +} + +int sd_cmd17(struct sd_handle *handle, + uint32_t addr, uint32_t len, uint8_t *buffer) +{ + int res; + uint32_t argument, options, ntry; + struct sd_resp resp; + + ntry = 0; + do { + res = sd_cmd13(handle, &resp.cardStatus); + if (res != SD_OK) { + EMMC_TRACE( + "cmd 13 failed before cmd17: rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, resp.cardStatus); + return res; + } + + if (resp.cardStatus & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd17\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + + } while (1); + + data_xfer_setup(handle, buffer, len, SD_XFER_CARD_TO_HOST); + + /* send cmd and parse result */ + argument = addr; + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_DPS_MASK | SD4_EMMC_TOP_CMD_DTDS_MASK | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + res = send_cmd(handle, SD_CMD_READ_SINGLE_BLOCK, argument, options, + &resp); + + if (res != SD_OK) + return res; + + res = process_data_xfer(handle, buffer, addr, len, SD_XFER_CARD_TO_HOST); + + return res; +} + +int sd_cmd18(struct sd_handle *handle, + uint32_t addr, uint32_t len, uint8_t *buffer) +{ + int res; + uint32_t argument, options, ntry; + struct sd_resp resp; + + ntry = 0; + do { + res = sd_cmd13(handle, &resp.cardStatus); + if (res != SD_OK) { + EMMC_TRACE( + "cmd 13 failed before cmd18: rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, resp.cardStatus); + return res; + } + + if (resp.cardStatus & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd18\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + } while (1); + + data_xfer_setup(handle, buffer, len, SD_XFER_CARD_TO_HOST); + + argument = addr; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_DPS_MASK | SD4_EMMC_TOP_CMD_DTDS_MASK | + SD4_EMMC_TOP_CMD_MSBS_MASK | SD4_EMMC_TOP_CMD_CCHK_EN_MASK | + SD4_EMMC_TOP_CMD_BCEN_MASK | SD4_EMMC_TOP_CMD_CRC_EN_MASK | + BIT(SD4_EMMC_TOP_CMD_ACMDEN_SHIFT); + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_READ_MULTIPLE_BLOCK, argument, options, + &resp); + + if (res != SD_OK) + return res; + + res = process_data_xfer(handle, buffer, addr, len, SD_XFER_CARD_TO_HOST); + + return res; +} + +#ifdef INCLUDE_EMMC_DRIVER_ERASE_CODE +static int card_sts_resp(struct sd_handle *handle, uint32_t *status) +{ + int res; + uint32_t ntry = 0; + + do { + res = sd_cmd13(handle, status); + if (res != SD_OK) { + EMMC_TRACE( + "cmd 13 failed before cmd35: rca 0x%0x, return %d\n", + handle->device->ctrl.rca, res); + return res; + } + + if (*status & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd35\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + } while (1); + + return SD_OK; +} + +int sd_cmd35(struct sd_handle *handle, uint32_t start) +{ + int res; + uint32_t argument, options; + struct sd_resp resp; + + res = card_sts_resp(handle, &resp.cardStatus); + if (res != SD_OK) + return res; + + argument = start; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_ERASE_GROUP_START, + argument, options, &resp); + + if (res != SD_OK) + return res; + + return res; +} + +int sd_cmd36(struct sd_handle *handle, uint32_t end) +{ + int res; + uint32_t argument, options; + struct sd_resp resp; + + res = card_sts_resp(handle, &resp.cardStatus); + if (res != SD_OK) + return res; + + argument = end; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_ERASE_GROUP_END, + argument, options, &resp); + + if (res != SD_OK) + return res; + + return res; +} + +int sd_cmd38(struct sd_handle *handle) +{ + int res; + uint32_t argument, options; + struct sd_resp resp; + + res = card_sts_resp(handle, &resp.cardStatus); + if (res != SD_OK) + return res; + + argument = 0; + + options = (SD_CMDR_RSP_TYPE_R1b_5b << SD_CMDR_RSP_TYPE_S) | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_ERASE, argument, options, &resp); + + if (res != SD_OK) + return res; + + return res; +} +#endif + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE + +int sd_cmd24(struct sd_handle *handle, + uint32_t addr, uint32_t len, uint8_t *buffer) +{ + int res; + uint32_t argument, options, ntry; + struct sd_resp resp; + + ntry = 0; + do { + res = sd_cmd13(handle, &resp.cardStatus); + if (res != SD_OK) { + EMMC_TRACE( + "cmd 13 failed before cmd24: rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, &resp.cardStatus); + return res; + } + + if (resp.cardStatus & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd24\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + + } while (1); + + data_xfer_setup(handle, buffer, len, SD_XFER_HOST_TO_CARD); + + argument = addr; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_DPS_MASK | SD4_EMMC_TOP_CMD_CRC_EN_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK; + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_WRITE_BLOCK, argument, options, &resp); + + if (res != SD_OK) + return res; + + res = process_data_xfer(handle, buffer, addr, len, SD_XFER_HOST_TO_CARD); + + return res; +} + +int sd_cmd25(struct sd_handle *handle, + uint32_t addr, uint32_t len, uint8_t *buffer) +{ + int res = SD_OK; + uint32_t argument, options, ntry; + struct sd_resp resp; + + ntry = 0; + do { + res = sd_cmd13(handle, &resp.cardStatus); + if (res != SD_OK) { + EMMC_TRACE( + "cmd 13 failed before cmd25: rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, &resp.cardStatus); + return res; + } + + if (resp.cardStatus & 0x100) + break; + + EMMC_TRACE("cmd13 rsp:0x%08x before cmd25\n", resp.cardStatus); + + if (ntry > handle->device->cfg.retryLimit) { + EMMC_TRACE("cmd13 retry reach limit %d\n", + handle->device->cfg.retryLimit); + return SD_CMD_TIMEOUT; + } + + ntry++; + EMMC_TRACE("cmd13 retry %d\n", ntry); + + SD_US_DELAY(1000); + } while (1); + + data_xfer_setup(handle, buffer, len, SD_XFER_HOST_TO_CARD); + + argument = addr; + + options = SD_CMDR_RSP_TYPE_R1_5_6 << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_DPS_MASK | SD4_EMMC_TOP_CMD_MSBS_MASK | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | SD4_EMMC_TOP_CMD_BCEN_MASK | + SD4_EMMC_TOP_CMD_CRC_EN_MASK | + BIT(SD4_EMMC_TOP_CMD_ACMDEN_SHIFT); + + /* send cmd and parse result */ + res = send_cmd(handle, SD_CMD_WRITE_MULTIPLE_BLOCK, + argument, options, &resp); + + if (res != SD_OK) + return res; + + res = process_data_xfer(handle, buffer, addr, len, SD_XFER_HOST_TO_CARD); + + return res; +} +#endif /* INCLUDE_EMMC_DRIVER_WRITE_CODE */ + +int mmc_cmd6(struct sd_handle *handle, uint32_t argument) +{ + int res; + uint32_t options; + struct sd_resp resp; + + options = SD_CMDR_RSP_TYPE_R1b_5b << SD_CMDR_RSP_TYPE_S | + SD4_EMMC_TOP_CMD_CCHK_EN_MASK | SD4_EMMC_TOP_CMD_CRC_EN_MASK; + + EMMC_TRACE("Sending CMD6 with argument 0x%X\n", argument); + + /* send cmd and parse result */ + res = send_cmd(handle, SD_ACMD_SET_BUS_WIDTH, argument, options, &resp); + + /* + * For R1b type response: + * controller issues a COMMAND COMPLETE interrupt when the R1 + * response is received, + * then controller monitors DAT0 for busy status, + * controller issues a TRANSFER COMPLETE interrupt when busy signal + * clears. + */ + wait_for_event(handle, + SD4_EMMC_TOP_INTR_TXDONE_MASK | SD_ERR_INTERRUPTS, + handle->device->cfg.wfe_retry); + + if (res == SD_OK) { + /* Check result of Cmd6 using Cmd13 to check card status */ + + /* Check status using Cmd13 */ + res = sd_cmd13(handle, &resp.cardStatus); + + if (res == SD_OK) { + /* Check bit 7 (SWITCH_ERROR) in card status */ + if ((resp.cardStatus & 0x80) != 0) { + EMMC_TRACE("cmd6 failed: SWITCH_ERROR\n"); + res = SD_FAIL; + } + } else { + EMMC_TRACE("cmd13 failed after cmd6: "); + EMMC_TRACE("rca 0x%0x, return %d, response 0x%0x\n", + handle->device->ctrl.rca, res, resp.cardStatus); + } + } + + return res; +} + + +#define SD_BUSY_CHECK 0x00203000 +#define DAT0_LEVEL_MASK 0x100000 /* bit20 in PSTATE */ +#define DEV_BUSY_TIMEOUT 600000 /* 60 Sec : 600000 * 100us */ + +int send_cmd(struct sd_handle *handle, uint32_t cmdIndex, uint32_t argument, + uint32_t options, struct sd_resp *resp) +{ + int status = SD_OK; + uint32_t event = 0, present, timeout = 0, retry = 0, mask = 3; + uint32_t temp_resp[4]; + + if (handle == NULL) { + EMMC_TRACE("Invalid handle for cmd%d\n", cmdIndex); + return SD_INVALID_HANDLE; + } + + mask = (SD_BUSY_CHECK & options) ? 3 : 1; + +RETRY_WRITE_CMD: + do { + /* Make sure it is ok to send command */ + present = + chal_sd_get_present_status((CHAL_HANDLE *) handle->device); + timeout++; + + if (present & mask) + SD_US_DELAY(1000); + else + break; + + } while (timeout < EMMC_BUSY_CMD_TIMEOUT_MS); + + if (timeout >= EMMC_BUSY_CMD_TIMEOUT_MS) { + status = SD_CMD_MISSING; + EMMC_TRACE("cmd%d timedout %dms\n", cmdIndex, timeout); + } + + /* Reset both DAT and CMD line if only of them are stuck */ + if (present & mask) + check_error(handle, SD4_EMMC_TOP_INTR_CMDERROR_MASK); + + handle->device->ctrl.argReg = argument; + chal_sd_send_cmd((CHAL_HANDLE *) handle->device, cmdIndex, + handle->device->ctrl.argReg, options); + + handle->device->ctrl.cmdIndex = cmdIndex; + + event = wait_for_event(handle, + (SD4_EMMC_TOP_INTR_CMDDONE_MASK | + SD_ERR_INTERRUPTS), + handle->device->cfg.wfe_retry); + + if (handle->device->ctrl.cmdStatus == SD_CMD_MISSING) { + retry++; + + if (retry >= handle->device->cfg.retryLimit) { + status = SD_CMD_MISSING; + EMMC_TRACE("cmd%d retry reaches the limit %d\n", + cmdIndex, retry); + } else { + /* reset both DAT & CMD line if one of them is stuck */ + present = chal_sd_get_present_status((CHAL_HANDLE *) + handle->device); + + if (present & mask) + check_error(handle, + SD4_EMMC_TOP_INTR_CMDERROR_MASK); + + EMMC_TRACE("cmd%d retry %d PSTATE[0x%08x]\n", + cmdIndex, retry, + chal_sd_get_present_status((CHAL_HANDLE *) + handle->device)); + goto RETRY_WRITE_CMD; + } + } + + if (handle->device->ctrl.cmdStatus == SD_OK) { + if (resp != NULL) { + status = + chal_sd_get_response((CHAL_HANDLE *) handle->device, + temp_resp); + process_cmd_response(handle, + handle->device->ctrl.cmdIndex, + temp_resp[0], temp_resp[1], + temp_resp[2], temp_resp[3], resp); + } + + /* Check Device busy after CMD */ + if ((cmdIndex == 5) || (cmdIndex == 6) || (cmdIndex == 7) || + (cmdIndex == 28) || (cmdIndex == 29) || (cmdIndex == 38)) { + + timeout = 0; + do { + present = + chal_sd_get_present_status((CHAL_HANDLE *) + handle->device); + + timeout++; + + /* Dat[0]:bit20 low means device busy */ + if ((present & DAT0_LEVEL_MASK) == 0) { + EMMC_TRACE("Device busy: "); + EMMC_TRACE( + "cmd%d arg:0x%08x: PSTATE[0x%08x]\n", + cmdIndex, argument, present); + SD_US_DELAY(100); + } else { + break; + } + } while (timeout < DEV_BUSY_TIMEOUT); + } + } else if (handle->device->ctrl.cmdStatus && + handle->device->ctrl.cmdStatus != SD_CMD_MISSING) { + retry++; + status = check_error(handle, handle->device->ctrl.cmdStatus); + + EMMC_TRACE( + "cmd%d error: cmdStatus:0x%08x error_status:0x%08x\n", + cmdIndex, handle->device->ctrl.cmdStatus, status); + + if ((handle->device->ctrl.cmdIndex == 1) || + (handle->device->ctrl.cmdIndex == 5)) { + status = event; + } else if ((handle->device->ctrl.cmdIndex == 7) || + (handle->device->ctrl.cmdIndex == 41)) { + status = event; + } else if ((status == SD_ERROR_RECOVERABLE) && + (retry < handle->device->cfg.retryLimit)) { + EMMC_TRACE("cmd%d recoverable error ", cmdIndex); + EMMC_TRACE("retry %d PSTATE[0x%08x].\n", retry, + chal_sd_get_present_status((CHAL_HANDLE *) + handle->device)); + goto RETRY_WRITE_CMD; + } else { + EMMC_TRACE("cmd%d retry reaches the limit %d\n", + cmdIndex, retry); + status = event; + } + } + + handle->device->ctrl.blkReg = 0; + /* clear error status for next command */ + handle->device->ctrl.cmdStatus = 0; + + return status; +} diff --git a/drivers/brcm/emmc/emmc_pboot_hal_memory_drv.c b/drivers/brcm/emmc/emmc_pboot_hal_memory_drv.c new file mode 100644 index 0000000..68f93e7 --- /dev/null +++ b/drivers/brcm/emmc/emmc_pboot_hal_memory_drv.c @@ -0,0 +1,621 @@ +/* + * Copyright (c) 2016 - 2020, Broadcom + * + * SPDX-License-Identifier: BSD-3-Clause + */ + +#include <string.h> + +#include <emmc_api.h> +#include <cmn_plat_util.h> + +#define MAX_CMD_RETRY 10 + +#if EMMC_USE_DMA +#define USE_DMA 1 +#else +#define USE_DMA 0 +#endif + +struct emmc_global_buffer emmc_global_buf; +struct emmc_global_buffer *emmc_global_buf_ptr = &emmc_global_buf; + +struct emmc_global_vars emmc_global_vars; +struct emmc_global_vars *emmc_global_vars_ptr = &emmc_global_vars; + +static struct sd_handle *sdio_gethandle(void); +static uint32_t sdio_idle(struct sd_handle *p_sdhandle); + +static uint32_t sdio_read(struct sd_handle *p_sdhandle, + uintptr_t mem_addr, + uintptr_t storage_addr, + size_t storage_size, + size_t bytes_to_read); + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE +static uint32_t sdio_write(struct sd_handle *p_sdhandle, + uintptr_t mem_addr, + uintptr_t data_addr, + size_t bytes_to_write); +#endif + +static struct sd_handle *sdio_init(void); +static int32_t bcm_emmc_card_ready_state(struct sd_handle *p_sdhandle); + +static void init_globals(void) +{ + memset((void *)emmc_global_buf_ptr, 0, sizeof(*emmc_global_buf_ptr)); + memset((void *)emmc_global_vars_ptr, 0, sizeof(*emmc_global_vars_ptr)); +} + +/* + * This function is used to change partition + */ +uint32_t emmc_partition_select(uint32_t partition) +{ + int rc; + struct sd_handle *sd_handle = sdio_gethandle(); + + if (sd_handle->device == 0) { + EMMC_TRACE("eMMC init is not done"); + return 0; + } + + switch (partition) { + case EMMC_BOOT_PARTITION1: + rc = set_boot_config(sd_handle, + SDIO_HW_EMMC_EXT_CSD_BOOT_ACC_BOOT1); + EMMC_TRACE( + "Change to Boot Partition 1 result:%d (0 means SD_OK)\n", + rc); + break; + + case EMMC_BOOT_PARTITION2: + rc = set_boot_config(sd_handle, + SDIO_HW_EMMC_EXT_CSD_BOOT_ACC_BOOT2); + EMMC_TRACE( + "Change to Boot Partition 2 result:%d (0 means SD_OK)\n", + rc); + break; + + case EMMC_USE_CURRENT_PARTITION: + rc = SD_OK; + EMMC_TRACE("Stay on current partition"); + break; + + case EMMC_USER_AREA: + default: + rc = set_boot_config(sd_handle, + SDIO_HW_EMMC_EXT_CSD_BOOT_ACC_USER); + EMMC_TRACE("Change to User area result:%d (0 means SD_OK)\n", + rc); + break; + + } + return (rc == SD_OK); +} + +/* + * Initialize emmc controller for eMMC + * Returns 0 on fail condition + */ +uint32_t bcm_emmc_init(bool card_rdy_only) +{ + struct sd_handle *p_sdhandle; + uint32_t result = 0; + + EMMC_TRACE("Enter emmc_controller_init()\n"); + + /* If eMMC is already initialized, skip init */ + if (emmc_global_vars_ptr->init_done) + return 1; + + init_globals(); + + p_sdhandle = sdio_init(); + + if (p_sdhandle == NULL) { + ERROR("eMMC init failed"); + return result; + } + + if (card_rdy_only) { + /* Put the card in Ready state, Not complete init */ + result = bcm_emmc_card_ready_state(p_sdhandle); + return !result; + } + + if (sdio_idle(p_sdhandle) == EMMC_BOOT_OK) { + set_config(p_sdhandle, SD_NORMAL_SPEED, MAX_CMD_RETRY, USE_DMA, + SD_DMA_BOUNDARY_256K, EMMC_BLOCK_SIZE, + EMMC_WFE_RETRY); + + if (!select_blk_sz(p_sdhandle, + p_sdhandle->device->cfg.blockSize)) { + emmc_global_vars_ptr->init_done = 1; + result = 1; + } else { + ERROR("Select Block Size failed\n"); + } + } else { + ERROR("eMMC init failed"); + } + + /* Initialization is failed, so deinit HW setting */ + if (result == 0) + emmc_deinit(); + + return result; +} + +/* + * Function to de-init SDIO controller for eMMC + */ +void emmc_deinit(void) +{ + emmc_global_vars_ptr->init_done = 0; + emmc_global_vars_ptr->sdHandle.card = 0; + emmc_global_vars_ptr->sdHandle.device = 0; +} + +/* + * Read eMMC memory + * Returns read_size + */ +uint32_t emmc_read(uintptr_t mem_addr, uintptr_t storage_addr, + size_t storage_size, size_t bytes_to_read) +{ + struct sd_handle *sd_handle = sdio_gethandle(); + + if (sd_handle->device == 0) { + EMMC_TRACE("eMMC init is not done"); + return 0; + } + + return sdio_read(sdio_gethandle(), mem_addr, storage_addr, + storage_size, bytes_to_read); +} + +#ifdef INCLUDE_EMMC_DRIVER_ERASE_CODE +#define EXT_CSD_ERASE_GRP_SIZE 224 + +static int emmc_block_erase(uintptr_t mem_addr, size_t blocks) +{ + struct sd_handle *sd_handle = sdio_gethandle(); + + if (sd_handle->device == 0) { + ERROR("eMMC init is not done"); + return -1; + } + + return erase_card(sdio_gethandle(), mem_addr, blocks); +} + +int emmc_erase(uintptr_t mem_addr, size_t num_of_blocks, uint32_t partition) +{ + int err = 0; + size_t block_count = 0, blocks = 0; + size_t erase_group = 0; + + erase_group = + emmc_global_buf_ptr->u.Ext_CSD_storage[EXT_CSD_ERASE_GRP_SIZE]*1024; + + INFO("eMMC Erase Group Size=0x%lx\n", erase_group); + + emmc_partition_select(partition); + + while (block_count < num_of_blocks) { + blocks = ((num_of_blocks - block_count) > erase_group) ? + erase_group : (num_of_blocks - block_count); + err = emmc_block_erase(mem_addr + block_count, blocks); + if (err) + break; + + block_count += blocks; + } + + if (err == 0) + INFO("eMMC Erase of partition %d successful\n", partition); + else + ERROR("eMMC Erase of partition %d Failed(%i)\n", partition, err); + + return err; +} +#endif + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE +/* + * Write to eMMC memory + * Returns written_size + */ +uint32_t emmc_write(uintptr_t mem_addr, uintptr_t data_addr, + size_t bytes_to_write) +{ + struct sd_handle *sd_handle = sdio_gethandle(); + + if (sd_handle->device == 0) { + EMMC_TRACE("eMMC init is not done"); + return 0; + } + + return sdio_write(sd_handle, mem_addr, data_addr, bytes_to_write); +} +#endif + +/* + * Send SDIO Cmd + * Return 0 for pass condition + */ +uint32_t send_sdio_cmd(uint32_t cmdIndex, uint32_t argument, + uint32_t options, struct sd_resp *resp) +{ + struct sd_handle *sd_handle = sdio_gethandle(); + + if (sd_handle->device == 0) { + EMMC_TRACE("eMMC init is not done"); + return 1; + } + + return send_cmd(sd_handle, cmdIndex, argument, options, resp); +} + + +/* + * This function return SDIO handle + */ +struct sd_handle *sdio_gethandle(void) +{ + return &emmc_global_vars_ptr->sdHandle; +} + +/* + * Initialize SDIO controller + */ +struct sd_handle *sdio_init(void) +{ + uint32_t SDIO_base; + struct sd_handle *p_sdhandle = &emmc_global_vars_ptr->sdHandle; + + SDIO_base = EMMC_CTRL_REGS_BASE_ADDR; + + if (SDIO_base == SDIO0_EMMCSDXC_SYSADDR) + EMMC_TRACE(" ---> for SDIO 0 Controller\n\n"); + + memset(p_sdhandle, 0, sizeof(struct sd_handle)); + + p_sdhandle->device = &emmc_global_vars_ptr->sdDevice; + p_sdhandle->card = &emmc_global_vars_ptr->sdCard; + + memset(p_sdhandle->device, 0, sizeof(struct sd_dev)); + memset(p_sdhandle->card, 0, sizeof(struct sd_card_info)); + + if (chal_sd_start((CHAL_HANDLE *) p_sdhandle->device, + SD_PIO_MODE, SDIO_base, SDIO_base) != SD_OK) + return NULL; + + set_config(p_sdhandle, SD_NORMAL_SPEED, MAX_CMD_RETRY, SD_DMA_OFF, + SD_DMA_BOUNDARY_4K, EMMC_BLOCK_SIZE, EMMC_WFE_RETRY); + + return &emmc_global_vars_ptr->sdHandle; +} + +uint32_t sdio_idle(struct sd_handle *p_sdhandle) +{ + reset_card(p_sdhandle); + + SD_US_DELAY(1000); + + if (init_card(p_sdhandle, SD_CARD_DETECT_MMC) != SD_OK) { + reset_card(p_sdhandle); + reset_host_ctrl(p_sdhandle); + return EMMC_BOOT_NO_CARD; + } + + return EMMC_BOOT_OK; +} + +/* + * This function read eMMC + */ +uint32_t sdio_read(struct sd_handle *p_sdhandle, + uintptr_t mem_addr, + uintptr_t storage_addr, + size_t storage_size, size_t bytes_to_read) +{ + uint32_t offset = 0, blockAddr, readLen = 0, rdCount; + uint32_t remSize, manual_copy_size; + uint8_t *outputBuf = (uint8_t *) storage_addr; + const size_t blockSize = p_sdhandle->device->cfg.blockSize; + + VERBOSE("EMMC READ: dst=0x%lx, src=0x%lx, size=0x%lx\n", + storage_addr, mem_addr, bytes_to_read); + + if (storage_size < bytes_to_read) + /* Don't have sufficient storage to complete the operation */ + return 0; + + /* Range check non high capacity memory */ + if ((p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) == 0) { + if (mem_addr > 0x80000000) + return 0; + } + + /* High capacity card use block address mode */ + if (p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) { + blockAddr = (uint32_t) (mem_addr / blockSize); + offset = (uint32_t) (mem_addr - (blockAddr * blockSize)); + } else { + blockAddr = (uint32_t) (mem_addr / blockSize) * blockSize; + offset = (uint32_t) (mem_addr - blockAddr); + } + + remSize = bytes_to_read; + + rdCount = 0; + + /* Process first unaligned block of MAX_READ_LENGTH */ + if (offset > 0) { + if (!read_block(p_sdhandle, emmc_global_buf_ptr->u.tempbuf, + blockAddr, SD_MAX_READ_LENGTH)) { + + if (remSize < (blockSize - offset)) { + rdCount += remSize; + manual_copy_size = remSize; + remSize = 0; /* read is done */ + } else { + remSize -= (blockSize - offset); + rdCount += (blockSize - offset); + manual_copy_size = blockSize - offset; + } + + /* Check for overflow */ + if (manual_copy_size > storage_size || + (((uintptr_t)outputBuf + manual_copy_size) > + (storage_addr + storage_size))) { + ERROR("EMMC READ: Overflow 1\n"); + return 0; + } + + memcpy(outputBuf, + (void *)((uintptr_t) + (emmc_global_buf_ptr->u.tempbuf + offset)), + manual_copy_size); + + /* Update Physical address */ + outputBuf += manual_copy_size; + + if (p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) + blockAddr++; + else + blockAddr += blockSize; + } else { + return 0; + } + } + + while (remSize >= blockSize) { + + if (remSize >= SD_MAX_BLK_TRANSFER_LENGTH) + readLen = SD_MAX_BLK_TRANSFER_LENGTH; + else + readLen = (remSize / blockSize) * blockSize; + + /* Check for overflow */ + if ((rdCount + readLen) > storage_size || + (((uintptr_t) outputBuf + readLen) > + (storage_addr + storage_size))) { + ERROR("EMMC READ: Overflow\n"); + return 0; + } + + if (!read_block(p_sdhandle, outputBuf, blockAddr, readLen)) { + if (p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) + blockAddr += (readLen / blockSize); + else + blockAddr += readLen; + + remSize -= readLen; + rdCount += readLen; + + /* Update Physical address */ + outputBuf += readLen; + } else { + return 0; + } + } + + /* process the last unaligned block reading */ + if (remSize > 0) { + if (!read_block(p_sdhandle, emmc_global_buf_ptr->u.tempbuf, + blockAddr, SD_MAX_READ_LENGTH)) { + + rdCount += remSize; + /* Check for overflow */ + if (rdCount > storage_size || + (((uintptr_t) outputBuf + remSize) > + (storage_addr + storage_size))) { + ERROR("EMMC READ: Overflow\n"); + return 0; + } + + memcpy(outputBuf, + emmc_global_buf_ptr->u.tempbuf, remSize); + + /* Update Physical address */ + outputBuf += remSize; + } else { + rdCount = 0; + } + } + + return rdCount; +} + +#ifdef INCLUDE_EMMC_DRIVER_WRITE_CODE +static uint32_t sdio_write(struct sd_handle *p_sdhandle, uintptr_t mem_addr, + uintptr_t data_addr, size_t bytes_to_write) +{ + + uint32_t offset, blockAddr, writeLen, wtCount = 0; + uint32_t remSize, manual_copy_size = 0; + + uint8_t *inputBuf = (uint8_t *)data_addr; + + /* range check non high capacity memory */ + if ((p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) == 0) { + if (mem_addr > 0x80000000) + return 0; + } + + /* the high capacity card use block address mode */ + if (p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) { + blockAddr = + (uint32_t)(mem_addr / p_sdhandle->device->cfg.blockSize); + offset = + (uint32_t)(mem_addr - + blockAddr * p_sdhandle->device->cfg.blockSize); + } else { + blockAddr = + ((uint32_t)mem_addr / p_sdhandle->device->cfg.blockSize) * + p_sdhandle->device->cfg.blockSize; + offset = (uint32_t) mem_addr - blockAddr; + } + + remSize = bytes_to_write; + + wtCount = 0; + + /* process first unaligned block */ + if (offset > 0) { + if (!read_block(p_sdhandle, emmc_global_buf_ptr->u.tempbuf, + blockAddr, p_sdhandle->device->cfg.blockSize)) { + + if (remSize < + (p_sdhandle->device->cfg.blockSize - offset)) + manual_copy_size = remSize; + else + manual_copy_size = + p_sdhandle->device->cfg.blockSize - offset; + + memcpy((void *)((uintptr_t) + (emmc_global_buf_ptr->u.tempbuf + offset)), + inputBuf, + manual_copy_size); + + /* Update Physical address */ + + if (!write_block(p_sdhandle, + emmc_global_buf_ptr->u.tempbuf, + blockAddr, + p_sdhandle->device->cfg.blockSize)) { + + if (remSize < + (p_sdhandle->device->cfg.blockSize - + offset)) { + wtCount += remSize; + manual_copy_size = remSize; + remSize = 0; /* read is done */ + } else { + remSize -= + (p_sdhandle->device->cfg.blockSize - + offset); + wtCount += + (p_sdhandle->device->cfg.blockSize - + offset); + manual_copy_size = + p_sdhandle->device->cfg.blockSize - + offset; + } + + inputBuf += manual_copy_size; + + if (p_sdhandle->device->ctrl.ocr & + SD_CARD_HIGH_CAPACITY) + blockAddr++; + else + blockAddr += + p_sdhandle->device->cfg.blockSize; + } else + return 0; + } else { + return 0; + } + } + + /* process block writing */ + while (remSize >= p_sdhandle->device->cfg.blockSize) { + if (remSize >= SD_MAX_READ_LENGTH) { + writeLen = SD_MAX_READ_LENGTH; + } else { + writeLen = + (remSize / p_sdhandle->device->cfg.blockSize) * + p_sdhandle->device->cfg.blockSize; + } + + if (!write_block(p_sdhandle, inputBuf, blockAddr, writeLen)) { + if (p_sdhandle->device->ctrl.ocr & SD_CARD_HIGH_CAPACITY) + blockAddr += + (writeLen / + p_sdhandle->device->cfg.blockSize); + else + blockAddr += writeLen; + + remSize -= writeLen; + wtCount += writeLen; + inputBuf += writeLen; + } else { + return 0; + } + } + + /* process the last unaligned block reading */ + if (remSize > 0) { + if (!read_block(p_sdhandle, + emmc_global_buf_ptr->u.tempbuf, + blockAddr, p_sdhandle->device->cfg.blockSize)) { + + memcpy(emmc_global_buf_ptr->u.tempbuf, + inputBuf, remSize); + + /* Update Physical address */ + + if (!write_block(p_sdhandle, + emmc_global_buf_ptr->u.tempbuf, + blockAddr, + p_sdhandle->device->cfg.blockSize)) { + wtCount += remSize; + inputBuf += remSize; + } else { + return 0; + } + } else { + wtCount = 0; + } + } + + return wtCount; +} +#endif + +/* + * Function to put the card in Ready state by sending CMD0 and CMD1 + */ +static int32_t bcm_emmc_card_ready_state(struct sd_handle *p_sdhandle) +{ + int32_t result = 0; + uint32_t argument = MMC_CMD_IDLE_RESET_ARG; /* Exit from Boot mode */ + + if (p_sdhandle) { + send_sdio_cmd(SD_CMD_GO_IDLE_STATE, argument, 0, NULL); + + result = reset_card(p_sdhandle); + if (result != SD_OK) { + EMMC_TRACE("eMMC Reset error\n"); + return SD_RESET_ERROR; + } + SD_US_DELAY(2000); + result = mmc_cmd1(p_sdhandle); + } + + return result; +} |