fusee: handle SDMMC speeds sanely

2024-11-06 04:01:44 +00:00 · 2018-05-18 13:17:04 -06:00 · 2018-05-18 13:17:04 -06:00 · 817c42efc2
commit 817c42efc2
parent ec7e0d923d
3 changed files with 208 additions and 64 deletions
--- a/fusee/fusee-primary/src/car.h
+++ b/fusee/fusee-primary/src/car.h
@ -51,8 +51,6 @@ enum {
    CLK_SOURCE_MASK        = (0b111 << 29),
    CLK_SOURCE_FIRST       = 0,
    CLK_DIVIDER_UNITY      = 0,
    CLK_DIVIDER_32         = 32,
 };
--- a/fusee/fusee-primary/src/sdmmc.c
+++ b/fusee/fusee-primary/src/sdmmc.c
@ -126,11 +126,21 @@ enum sdmmc_response_type {
 /**
 * Lengths of SD command responses
 */
-enum sdmmc_response_sizes {
+enum sdmmc_constants {
    /* Bytes in a LEN136 response */
    MMC_RESPONSE_SIZE_LEN136    = 15,
 };
 /**
 * SDMMC clock divider constants
 */
 enum sdmmc_clock_dividers {
    MMC_CLOCK_DIVIDER_SDR12  = 32, // 16.5, from the TRM table
    MMC_CLOCK_DIVIDER_SDR25  = 16, // 8.5, from the table
    MMC_CLOCK_DIVIDER_SDR50  = 8,  // 4.5, from the table
    MMC_CLOCK_DIVIDER_SDR104 = 3,  // 2, from the datasheet
 };
 /**
 * SDMMC response sanity checks
 * see the standard for when these should be used
@ -153,6 +163,8 @@ enum sdmmc_register_bits {
    MMC_BUFFER_WRITE_ENABLE  = (1 << 10),
    MMC_BUFFER_READ_ENABLE   = (1 << 11),
    MMC_DAT0_LINE_STATE      = (1 << 20),
    MMC_READ_ACTIVE          = (1 << 9),
    MMC_WRITE_ACTIVE         = (1 << 8),
    /* Block size register */
    MMC_DMA_BOUNDARY_MAXIMUM = (0x7 << 12),
@ -193,6 +205,8 @@ enum sdmmc_register_bits {
    /* Clock control */
    MMC_CLOCK_CONTROL_CARD_CLOCK_ENABLE = (1 << 2),
    MMC_CLOCK_CONTROL_FREQUENCY_MASK = (0x3FF << 6),
    MMC_CLOCK_CONTROL_FREQUENCY_INIT = (0x18 << 8),
    /* Host control */
    MMC_DMA_SELECT_MASK = (0x3 << 3),
@ -200,6 +214,15 @@ enum sdmmc_register_bits {
    MMC_HOST_BUS_WIDTH_MASK = (1 << 1) | (1 << 5),
    MMC_HOST_BUS_WIDTH_4BIT = (1 << 1),
    MMC_HOST_BUS_WIDTH_8BIT = (1 << 5),
    MMC_HOST_ENABLE_HIGH_SPEED = (1 << 2),
    /* Host control 2 */
    MMC_HOST2_DRIVE_STRENGTH_MASK = (0x3 << 4),
    MMC_HOST2_DRIVE_STRENGTH_B = (0x0 << 4),
    MMC_HOST2_DRIVE_STRENGTH_A = (0x1 << 4),
    MMC_HOST2_DRIVE_STRENGTH_C = (0x2 << 4),
    MMC_HOST2_DRIVE_STRENGTH_D = (0x3 << 4),
    MMC_HOST2_USE_1V8_SIGNALING = (1 << 3),
    /* Software reset */
    MMC_SOFT_RESET_FULL = (1 << 0),
@ -327,6 +350,12 @@ enum sdmmc_command_magic {
    MMC_DEFAULT_BLOCK_ORDER = 9,
    MMC_VOLTAGE_SWITCH_TIME = 5000, // 5mS
    MMC_POST_CLOCK_DELAY = 1000, // 1mS
    /* Switch mode constants */
    SDMMC_SWITCH_MODE_MODE_SHIFT = 31,
    SDMMC_SWITCH_MODE_ALL_FUNCTIONS_UNUSED = 0xFFFFFF,
    SDMMC_SWITCH_MODE_FUNCTION_MASK = 0xF,
    SDMMC_SWITCH_MODE_GROUP_SIZE_BITS = 4,
 };
@ -384,6 +413,20 @@ enum sdmmc_ext_csd_extents {
 };
 /**
 * Bus speeds possible for an SDMMC controller.
 */
 enum sdmmc_bus_speed {
    SDMMC_SPEED_SDR12  = 0,
    SDMMC_SPEED_SDR25  = 1,
    SDMMC_SPEED_SDR50  = 2,
    SDMMC_SPEED_SDR104 = 3,
    SDMMC_SPEED_DDR50  = 4,
    SDMMC_SPEED_INIT = -1,
 };
 /**
 * Bitfield struct representing an SD SCR.
 */
@ -569,12 +612,13 @@ static int sdmmc4_set_up_clock_and_io(struct mmc *mmc)
    // Put SDMMC4 in reset
    car->rst_dev_l_set |= 0x8000;
-    // Set SDMMC4 clock source (PLLP_OUT0) and divisor (32).
+    // Set SDMMC4 clock source (PLLP_OUT0) and divisor (17).
-    // We use 32 beacuse Nintendo does, and they probably know what they're doing?
+    // Divider value is the suggested base from the dataseet.
-    car->clk_src[CLK_SOURCE_SDMMC4] = CLK_SOURCE_FIRST | CLK_DIVIDER_32;
+    // TODO: abstract me!
    car->clk_src[CLK_SOURCE_SDMMC4] = CLK_SOURCE_FIRST | MMC_CLOCK_DIVIDER_SDR12;
    // Set the legacy divier used for detecting timeouts.
-    car->clk_src_y[CLK_SOURCE_SDMMC_LEGACY] = CLK_SOURCE_FIRST | CLK_DIVIDER_32;
+    car->clk_src_y[CLK_SOURCE_SDMMC_LEGACY] = CLK_SOURCE_FIRST | MMC_CLOCK_DIVIDER_SDR12;
    // Set SDMMC4 clock enable
    car->clk_enb_l_set |= 0x8000;
@ -608,6 +652,9 @@ static void sdmmc_set_working_voltage(struct mmc *mmc, enum sdmmc_bus_voltage vo
    mmc->regs->power_control &= ~MMC_POWER_CONTROL_VOLTAGE_MASK;
    mmc->regs->power_control |= voltage << MMC_POWER_CONTROL_VOLTAGE_SHIFT;
    // Switch to 1V8 signaling.
    mmc->regs->host_control2 |= MMC_HOST2_USE_1V8_SIGNALING;
    // Mark the power as on.
    mmc->regs->power_control |= MMC_POWER_CONTROL_POWER_ENABLE;
 }
@ -860,12 +907,13 @@ static int sdmmc1_set_up_clock_and_io(struct mmc *mmc)
    // Put SDMMC1 in reset
    car->rst_dev_l_set |= CAR_CONTROL_SDMMC1;
-    // Set SDMMC1 clock source (PLLP_OUT0) and divisor (32).
+    // Set SDMMC1 clock source (PLLP_OUT0) and divisor (div by 17).
-    // We use 32 beacuse Nintendo does, and they probably know what they're doing?
+    // This is the datasheet recommended value for SDR12.
-    car->clk_src[CLK_SOURCE_SDMMC1] = CLK_SOURCE_FIRST | CLK_DIVIDER_32;
+    // TODO: abstract this into a clock source specification function!
    car->clk_src[CLK_SOURCE_SDMMC1] = CLK_SOURCE_FIRST | MMC_CLOCK_DIVIDER_SDR12;
    // Set the legacy divier used for detecting timeouts.
-    car->clk_src_y[CLK_SOURCE_SDMMC_LEGACY] = CLK_SOURCE_FIRST | CLK_DIVIDER_32;
+    car->clk_src_y[CLK_SOURCE_SDMMC_LEGACY] = CLK_SOURCE_FIRST | MMC_CLOCK_DIVIDER_SDR12;
    // Set SDMMC1 clock enable
    car->clk_enb_l_set |= CAR_CONTROL_SDMMC1;
@ -884,6 +932,53 @@ static int sdmmc1_set_up_clock_and_io(struct mmc *mmc)
 }
 /**
 * Applies the appropriate clock dividers to the CAR and SD controller to enable use of the
 * provided speed. Does not handle any requisite communications with the card.
 *
 * @param mmc The controller to affect.
 * @param speed The speed to apply.
 * @param enable_after If set, the SDMMC clock will be enabled after the change. If not, it will be left disabled.
 */
 static int sdmmc_apply_clock_speed(struct mmc *mmc, enum sdmmc_bus_speed speed, bool enable_after)
 {
    // TODO: also set the clock for the main divider
    // Ensure the clocks are not currently running to avoid glitches.
    sdmmc_clock_enable(mmc, false);
    // Clear the registers of any existing values, so we can apply new ones.
    mmc->regs->clock_control &= ~MMC_CLOCK_CONTROL_FREQUENCY_MASK;
    mmc->regs->host_control &= ~MMC_HOST_ENABLE_HIGH_SPEED;
    mmc->regs->host_control2 &= ~MMC_HOST2_DRIVE_STRENGTH_MASK;
    // Apply the dividers according to the speed provided.
    switch (speed) {
        // 400kHz initialization mode.
        case SDMMC_SPEED_INIT:
            mmc->regs->clock_control |= MMC_CLOCK_CONTROL_FREQUENCY_INIT;
            break;
        // 25MHz default speed
        case SDMMC_SPEED_SDR12:
            break;
        default:
            mmc_print(mmc, "ERROR: switching to unsupported speed!\n");
            return ENOSYS;
    }
    // Re-enable the clock, if necessary.
    if (enable_after) {
        sdmmc_clock_enable(mmc, true);
        udelay(MMC_POST_CLOCK_DELAY);
    }
    return 0;
 }
 /**
 * Initialize the low-level SDMMC hardware.
 * Thanks to hexkyz for this init code.
@ -978,38 +1073,30 @@ static int sdmmc_hardware_init(struct mmc *mmc)
    // Clear SDHCI_PROG_CLOCK_MODE
    regs->clock_control &= ~(0x20);
-    // Clear SDHCI_CTRL_SDMA and SDHCI_CTRL_ADMA2
+    // Ensure we're using Single-operation DMA (SDMA) mode for DMA.
-    regs->host_control &= 0xE7;
+    regs->host_control &= ~MMC_DMA_SELECT_MASK;
    // Set the timeout to be the maximum value
    regs->timeout_control &= ~(0x0F);
    regs->timeout_control |= 0x0E;
-    // Clear SDHCI_CTRL_4BITBUS and SDHCI_CTRL_8BITBUS
+    // Ensure we start off using a single-bit bus.
-    regs->host_control &= 0xFD;
+    mmc->regs->host_control &= ~MMC_HOST_BUS_WIDTH_MASK;
    regs->host_control &= 0xDF;
    // TODO: move me into enable voltages, if applicable?
    // Clear TAP_VAL_UPDATED_BY_HW
    regs->vendor_tuning_cntrl0 &= ~(0x20000);
-    // Clear SDHCI_CTRL_HISPD
+    // Start off in non-high-speed mode.
-    regs->host_control &= 0xFB;
+    regs->host_control &= ~MMC_HOST_ENABLE_HIGH_SPEED;
    // Clear SDHCI_CTRL_VDD_180
    regs->host_control2 &= ~(0x08);
-    // Set SDHCI_DIVIDER and SDHCI_DIVIDER_HI
+    // Set up the card's initialization.
-    // FIXME: divider SD if necessary
+    sdmmc_apply_clock_speed(mmc, SDMMC_SPEED_INIT, true);
    regs->clock_control &= ~(0xFFC0);
    regs->clock_control |= (0x18 << 8);  // 200kHz, initially
    // Start delivering the clock to the card.
    sdmmc_clock_enable(mmc, true);
    // Ensure we're using Single-operation DMA (SDMA) mode for DMA.
    regs->host_control &= ~MMC_DMA_SELECT_MASK;
    return 0;
 }
@ -1115,11 +1202,14 @@ static int sdmmc_flush_bounce_buffer(struct mmc *mmc)
 }
 /**
- * Blocks until the SD driver has completed issuing a command.
+ * Generic SDMMC waiting function.
 *
 * @param mmc The MMC controller on which to wait.
- * @param target_irq A bitmask that specifies the bits that
+ * @param target_irq A bitmask that specifies the interrupt bits that
- *      will make this function return success
+ *      will make this function return success.
 * @param state_condition A bitmask that specifies a collection of bits
 *      that indicate business in present_state. If zero, all of the relevant
 *      conditions becoming false will cause a sucessful return.
 * @param fault_conditions A bitmask that specifies the bits that
 *      will make this function trigger its fault handler.
 *  @param fault_handler A function that's called to handle DMA faults.
@ -1129,8 +1219,9 @@ static int sdmmc_flush_bounce_buffer(struct mmc *mmc)
 * @return 0 on sucess, EFAULT if a fault condition occurs,
 *      or an error code if a transfer failure occurs
 */
-static int sdmmc_wait_for_interrupt(struct mmc *mmc,
+static int sdmmc_wait_for_event(struct mmc *mmc,
-        uint32_t target_irq, uint32_t fault_conditions, fault_handler_t fault_handler)
+        uint32_t target_irq, uint32_t state_conditions,
        uint32_t fault_conditions, fault_handler_t fault_handler)
 {
    uint32_t timebase = get_time();
    int rc;
@ -1144,14 +1235,14 @@ static int sdmmc_wait_for_interrupt(struct mmc *mmc,
            // If we don't have a handler, fault.
            if (!fault_handler) {
-                mmc_print(mmc, "ERROR: unhandled DMA fault!\n");
+                mmc_print(mmc, "ERROR: unhandled DMA fault!");
                return EFAULT;
            }
            // Call the DMA fault handler.
            rc = fault_handler(mmc);
            if (rc) {
-                mmc_print(mmc, "ERROR: unhandled DMA fault!\n (%d)", rc);
+                mmc_print(mmc, "ERROR: unhandled DMA fault! (%d)", rc);
                return rc;
            }
@ -1166,6 +1257,9 @@ static int sdmmc_wait_for_interrupt(struct mmc *mmc,
        if (mmc->regs->int_status & target_irq)
            return 0;
        if (state_conditions && !(mmc->regs->present_state & state_conditions))
            return 0;
        // If an error occurs, return it.
        if (mmc->regs->int_status & MMC_STATUS_ERROR_MASK)
            return (mmc->regs->int_status & MMC_STATUS_ERROR_MASK);
@ -1179,7 +1273,7 @@ static int sdmmc_wait_for_interrupt(struct mmc *mmc,
 */
 static int sdmmc_wait_for_command_completion(struct mmc *mmc)
 {
-    return sdmmc_wait_for_interrupt(mmc, MMC_STATUS_COMMAND_COMPLETE, 0, NULL);
+    return sdmmc_wait_for_event(mmc, MMC_STATUS_COMMAND_COMPLETE, 0, 0, NULL);
 }
@ -1191,8 +1285,11 @@ static int sdmmc_wait_for_command_completion(struct mmc *mmc)
 */
 static int sdmmc_wait_for_transfer_completion(struct mmc *mmc)
 {
-    return sdmmc_wait_for_interrupt(mmc, MMC_STATUS_TRANSFER_COMPLETE,
+    int rc = sdmmc_wait_for_event(mmc, MMC_STATUS_TRANSFER_COMPLETE,
-            MMC_STATUS_DMA_INTERRUPT, sdmmc_flush_bounce_buffer);
+            MMC_WRITE_ACTIVE | MMC_READ_ACTIVE, MMC_STATUS_DMA_INTERRUPT, sdmmc_flush_bounce_buffer);
    return rc;
 }
@ -1894,7 +1991,7 @@ static int sdmmc_mmc_switch_bus_width(struct mmc *mmc, enum sdmmc_bus_width widt
 {
    // Ask the card to adjust to the wider bus width.
    int rc = mmc->switch_mode(mmc, MMC_SWITCH_EXTCSD_NORMAL,
-            MMC_BUS_WIDTH, width, mmc->timeout);
+            MMC_BUS_WIDTH, width, mmc->timeout, NULL);
    if (rc) {
        mmc_print(mmc, "could not switch mode on the card side!");
        return rc;
@ -1965,6 +2062,12 @@ static int sdmmc_optimize_transfer_mode(struct mmc *mmc)
        return rc;
    }
    // We started off with the controller opearting with a divided clock,
    // which is meant to keep us within the pre-init operating frequency of 400kHz.
    // We're now set up, so we can drop the divider. From this point forward, the
    // clock is now driven by the CAR frequency.
    sdmmc_apply_clock_speed(mmc, SDMMC_SPEED_SDR12, true);
    // TODO: step up into high speed modes
    return 0;
@ -2338,7 +2441,7 @@ static int sdmmc_wait_for_card_ready(struct mmc *mmc, uint32_t timeout)
 *
 * @return 0 on success, or an error code on failure
 */
-static int sdmmc_mmc_switch_mode(struct mmc *mmc, enum sdmmc_switch_access_mode mode, enum sdmmc_switch_field field, uint16_t value, uint32_t timeout)
+static int sdmmc_mmc_switch_mode(struct mmc *mmc, int mode, int field, int value, uint32_t timeout, void *unused)
 {
    // Collapse our various parameters into a single argument.
    uint32_t argument =
@ -2366,25 +2469,6 @@ static int sdmmc_mmc_switch_mode(struct mmc *mmc, enum sdmmc_switch_access_mode
 }
 /**
 * Issues a SWITCH_MODE command, which can be used to write registers on the SD card's controller,
 * and thus to e.g. switch partitions.
 *
 * @param mmc The MMC device to use for comms.
 * @param mode The access mode with which to access the controller.
 * @param field The field to access.
 * @param value The argument to the access mode.
 * @param timeout The timeout, which is often longer than the normal MMC timeout.
 *
 * @return 0 on success, or an error code on failure
 */
 static int sdmmc_sd_switch_mode(struct mmc *mmc, enum sdmmc_switch_access_mode mode, enum sdmmc_switch_field field, uint16_t value, uint32_t timeout)
 {
    mmc_print(mmc, "ERROR: SD card mode switching not yet implemented");
    return ENOSYS;
 }
 /**
 * @return True iff the given MMC card supports hardare partitions.
 */
@ -2410,6 +2494,69 @@ bool sdmmc_external_card_present(struct mmc *mmc)
    return !gpio_read(mmc->card_detect_gpio);
 }
 /**
 * Issues an SD card mode-switch command.
 *
 * @param mmc The controller to use.
 * @param mode The mode flag -- one to set function data, zero to query.
 * @param group The SD card function group-- see the SD card Physical Layer spec.
 */
 static int sdmmc_sd_switch_mode(struct mmc *mmc, int mode, int group, int value, uint32_t timeout, void *response)
 {
    int rc;
    // Read the current block order, so we can restore it.
    int original_block_order = sdmmc_get_block_order(mmc, false);
    // Always request a single 64-byte block.
    const int block_order = 6;
    const int num_blocks = 1;
    // Build the argument we're going to issue.
    const int group_shift = group * SDMMC_SWITCH_MODE_GROUP_SIZE_BITS;
    uint32_t argument = (mode << SDMMC_SWITCH_MODE_MODE_SHIFT) | SDMMC_SWITCH_MODE_ALL_FUNCTIONS_UNUSED;
    argument         &= ~(SDMMC_SWITCH_MODE_FUNCTION_MASK << group_shift);
    argument         |= value << group_shift;
    // Momentarily step down to a smaller block size, so we don't
    // have to allocate a huge buffer for this command.
    rc = sdmmc_use_block_size(mmc, block_order);
    if (rc) {
        mmc_print(mmc, "could not step down to a smaller block size! (%d)", rc);
        return rc;
    }
    // Issue the command itself.
    rc = sdmmc_send_command(mmc, CMD_SWITCH_MODE, MMC_RESPONSE_LEN48, MMC_CHECKS_ALL, argument, NULL, num_blocks, false, false, response);
    if (rc) {
        mmc_print(mmc, "could not issue switch command!");
        sdmmc_use_block_size(mmc, original_block_order);
        return rc;
    }
    // Restore the original block order.
    rc = sdmmc_use_block_size(mmc, original_block_order);
    if (rc) {
        mmc_print(mmc, "could not restore the original block size! (%d)", rc);
        return rc;
    }
    return 0;
 }
 /**
 * Switches the host controller and SD card to high speed mode.
 */
 /*
 static int sdmmc_sd_switch_to_high_speed(struct mmc *mmc)
 {
    return ENOSYS;
 }
 */
 /**
 * Switches a given SDMMC Controller where
 */
@ -2507,7 +2654,7 @@ static int sdmmc_initialize_defaults(struct mmc *mmc)
 *
 * @param mmc The SDMMC structure to be initiailized with the device state.
 * @param controler The controller description to be used; usually SWITCH_EMMC
- *      or SWTICH_MICROSD.
+ *      or SWITCH_MICROSD.
 */
 int sdmmc_init(struct mmc *mmc, enum sdmmc_controller controller)
 {
@ -2589,7 +2736,7 @@ int sdmmc_select_partition(struct mmc *mmc, enum sdmmc_partition partition)
    // Set the PARTITION_CONFIG register to select the active partition.
    mmc_print(mmc, "switching to partition %d", partition);
-    rc = mmc->switch_mode(mmc, MMC_SWITCH_MODE_WRITE_BYTE, MMC_PARTITION_CONFIG, argument, 0);
+    rc = mmc->switch_mode(mmc, MMC_SWITCH_MODE_WRITE_BYTE, MMC_PARTITION_CONFIG, argument, 0, NULL);
    if (rc) {
        mmc_print(mmc, "failed to select partition %d (%02x, rc=%d)", partition, argument, rc);
    }
--- a/fusee/fusee-primary/src/sdmmc.h
+++ b/fusee/fusee-primary/src/sdmmc.h
@ -126,7 +126,6 @@ enum sdmmc_switch_field {
 };
 /**
 * Primary data structure describing a Fusée MMC driver.
 */
@ -150,9 +149,9 @@ struct mmc {
    /* Per-card-type operations */
    int (*card_init)(struct mmc *mmc);
    int (*establish_relative_address)(struct mmc *mmc);
-    int (*switch_mode)(struct mmc *mmc, enum sdmmc_switch_access_mode mode,
+    int (*switch_mode)(struct mmc *mmc, int a, int b, int c, uint32_t timeout, void *response);
            enum sdmmc_switch_field field, uint16_t value, uint32_t timeout);
    int (*switch_bus_width)(struct mmc *mmc, enum sdmmc_bus_width width);
    int (*switch_to_high_speed)(struct mmc *mmc);
    /* Card properties */
    uint8_t cid[15];