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linux-stable/drivers/mmc/host/cavium.c
Ulf Hansson 1be64c7963 mmc: host: Drop redundant MMC_CAP_ERASE 
The MMC_CAP_ERASE bit is no longer used by the mmc core as erase, discard
and trim operations are now always supported. Therefore, drop the bit and
move all mmc hosts away from using it.

Signed-off-by: Ulf Hansson <ulf.hansson@linaro.org>
Reviewed-by: Rui Miguel Silva <rmfrfs@gmail.com>
Link: https://lore.kernel.org/r/20200508112902.23575-1-ulf.hansson@linaro.org
Reviewed-by: Linus Walleij <linus.walleij@linaro.org>
2020-05-28 11:22:14 +02:00

1086 lines
28 KiB
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/*
* Shared part of driver for MMC/SDHC controller on Cavium OCTEON and
* ThunderX SOCs.
*
* This file is subject to the terms and conditions of the GNU General Public
* License. See the file "COPYING" in the main directory of this archive
* for more details.
*
* Copyright (C) 2012-2017 Cavium Inc.
* Authors:
* David Daney <david.daney@cavium.com>
* Peter Swain <pswain@cavium.com>
* Steven J. Hill <steven.hill@cavium.com>
* Jan Glauber <jglauber@cavium.com>
*/
#include <linux/bitfield.h>
#include <linux/delay.h>
#include <linux/dma-direction.h>
#include <linux/dma-mapping.h>
#include <linux/gpio/consumer.h>
#include <linux/interrupt.h>
#include <linux/mmc/mmc.h>
#include <linux/mmc/slot-gpio.h>
#include <linux/module.h>
#include <linux/regulator/consumer.h>
#include <linux/scatterlist.h>
#include <linux/time.h>
#include "cavium.h"
const char *cvm_mmc_irq_names[] = {
"MMC Buffer",
"MMC Command",
"MMC DMA",
"MMC Command Error",
"MMC DMA Error",
"MMC Switch",
"MMC Switch Error",
"MMC DMA int Fifo",
"MMC DMA int",
};
/*
* The Cavium MMC host hardware assumes that all commands have fixed
* command and response types. These are correct if MMC devices are
* being used. However, non-MMC devices like SD use command and
* response types that are unexpected by the host hardware.
*
* The command and response types can be overridden by supplying an
* XOR value that is applied to the type. We calculate the XOR value
* from the values in this table and the flags passed from the MMC
* core.
*/
static struct cvm_mmc_cr_type cvm_mmc_cr_types[] = {
{0, 0}, /* CMD0 */
{0, 3}, /* CMD1 */
{0, 2}, /* CMD2 */
{0, 1}, /* CMD3 */
{0, 0}, /* CMD4 */
{0, 1}, /* CMD5 */
{0, 1}, /* CMD6 */
{0, 1}, /* CMD7 */
{1, 1}, /* CMD8 */
{0, 2}, /* CMD9 */
{0, 2}, /* CMD10 */
{1, 1}, /* CMD11 */
{0, 1}, /* CMD12 */
{0, 1}, /* CMD13 */
{1, 1}, /* CMD14 */
{0, 0}, /* CMD15 */
{0, 1}, /* CMD16 */
{1, 1}, /* CMD17 */
{1, 1}, /* CMD18 */
{3, 1}, /* CMD19 */
{2, 1}, /* CMD20 */
{0, 0}, /* CMD21 */
{0, 0}, /* CMD22 */
{0, 1}, /* CMD23 */
{2, 1}, /* CMD24 */
{2, 1}, /* CMD25 */
{2, 1}, /* CMD26 */
{2, 1}, /* CMD27 */
{0, 1}, /* CMD28 */
{0, 1}, /* CMD29 */
{1, 1}, /* CMD30 */
{1, 1}, /* CMD31 */
{0, 0}, /* CMD32 */
{0, 0}, /* CMD33 */
{0, 0}, /* CMD34 */
{0, 1}, /* CMD35 */
{0, 1}, /* CMD36 */
{0, 0}, /* CMD37 */
{0, 1}, /* CMD38 */
{0, 4}, /* CMD39 */
{0, 5}, /* CMD40 */
{0, 0}, /* CMD41 */
{2, 1}, /* CMD42 */
{0, 0}, /* CMD43 */
{0, 0}, /* CMD44 */
{0, 0}, /* CMD45 */
{0, 0}, /* CMD46 */
{0, 0}, /* CMD47 */
{0, 0}, /* CMD48 */
{0, 0}, /* CMD49 */
{0, 0}, /* CMD50 */
{0, 0}, /* CMD51 */
{0, 0}, /* CMD52 */
{0, 0}, /* CMD53 */
{0, 0}, /* CMD54 */
{0, 1}, /* CMD55 */
{0xff, 0xff}, /* CMD56 */
{0, 0}, /* CMD57 */
{0, 0}, /* CMD58 */
{0, 0}, /* CMD59 */
{0, 0}, /* CMD60 */
{0, 0}, /* CMD61 */
{0, 0}, /* CMD62 */
{0, 0} /* CMD63 */
};
static struct cvm_mmc_cr_mods cvm_mmc_get_cr_mods(struct mmc_command *cmd)
{
struct cvm_mmc_cr_type *cr;
u8 hardware_ctype, hardware_rtype;
u8 desired_ctype = 0, desired_rtype = 0;
struct cvm_mmc_cr_mods r;
cr = cvm_mmc_cr_types + (cmd->opcode & 0x3f);
hardware_ctype = cr->ctype;
hardware_rtype = cr->rtype;
if (cmd->opcode == MMC_GEN_CMD)
hardware_ctype = (cmd->arg & 1) ? 1 : 2;
switch (mmc_cmd_type(cmd)) {
case MMC_CMD_ADTC:
desired_ctype = (cmd->data->flags & MMC_DATA_WRITE) ? 2 : 1;
break;
case MMC_CMD_AC:
case MMC_CMD_BC:
case MMC_CMD_BCR:
desired_ctype = 0;
break;
}
switch (mmc_resp_type(cmd)) {
case MMC_RSP_NONE:
desired_rtype = 0;
break;
case MMC_RSP_R1:/* MMC_RSP_R5, MMC_RSP_R6, MMC_RSP_R7 */
case MMC_RSP_R1B:
desired_rtype = 1;
break;
case MMC_RSP_R2:
desired_rtype = 2;
break;
case MMC_RSP_R3: /* MMC_RSP_R4 */
desired_rtype = 3;
break;
}
r.ctype_xor = desired_ctype ^ hardware_ctype;
r.rtype_xor = desired_rtype ^ hardware_rtype;
return r;
}
static void check_switch_errors(struct cvm_mmc_host *host)
{
u64 emm_switch;
emm_switch = readq(host->base + MIO_EMM_SWITCH(host));
if (emm_switch & MIO_EMM_SWITCH_ERR0)
dev_err(host->dev, "Switch power class error\n");
if (emm_switch & MIO_EMM_SWITCH_ERR1)
dev_err(host->dev, "Switch hs timing error\n");
if (emm_switch & MIO_EMM_SWITCH_ERR2)
dev_err(host->dev, "Switch bus width error\n");
}
static void clear_bus_id(u64 *reg)
{
u64 bus_id_mask = GENMASK_ULL(61, 60);
*reg &= ~bus_id_mask;
}
static void set_bus_id(u64 *reg, int bus_id)
{
clear_bus_id(reg);
*reg |= FIELD_PREP(GENMASK(61, 60), bus_id);
}
static int get_bus_id(u64 reg)
{
return FIELD_GET(GENMASK_ULL(61, 60), reg);
}
/*
* We never set the switch_exe bit since that would interfere
* with the commands send by the MMC core.
*/
static void do_switch(struct cvm_mmc_host *host, u64 emm_switch)
{
int retries = 100;
u64 rsp_sts;
int bus_id;
/*
* Modes setting only taken from slot 0. Work around that hardware
* issue by first switching to slot 0.
*/
bus_id = get_bus_id(emm_switch);
clear_bus_id(&emm_switch);
writeq(emm_switch, host->base + MIO_EMM_SWITCH(host));
set_bus_id(&emm_switch, bus_id);
writeq(emm_switch, host->base + MIO_EMM_SWITCH(host));
/* wait for the switch to finish */
do {
rsp_sts = readq(host->base + MIO_EMM_RSP_STS(host));
if (!(rsp_sts & MIO_EMM_RSP_STS_SWITCH_VAL))
break;
udelay(10);
} while (--retries);
check_switch_errors(host);
}
static bool switch_val_changed(struct cvm_mmc_slot *slot, u64 new_val)
{
/* Match BUS_ID, HS_TIMING, BUS_WIDTH, POWER_CLASS, CLK_HI, CLK_LO */
u64 match = 0x3001070fffffffffull;
return (slot->cached_switch & match) != (new_val & match);
}
static void set_wdog(struct cvm_mmc_slot *slot, unsigned int ns)
{
u64 timeout;
if (!slot->clock)
return;
if (ns)
timeout = (slot->clock * ns) / NSEC_PER_SEC;
else
timeout = (slot->clock * 850ull) / 1000ull;
writeq(timeout, slot->host->base + MIO_EMM_WDOG(slot->host));
}
static void cvm_mmc_reset_bus(struct cvm_mmc_slot *slot)
{
struct cvm_mmc_host *host = slot->host;
u64 emm_switch, wdog;
emm_switch = readq(slot->host->base + MIO_EMM_SWITCH(host));
emm_switch &= ~(MIO_EMM_SWITCH_EXE | MIO_EMM_SWITCH_ERR0 |
MIO_EMM_SWITCH_ERR1 | MIO_EMM_SWITCH_ERR2);
set_bus_id(&emm_switch, slot->bus_id);
wdog = readq(slot->host->base + MIO_EMM_WDOG(host));
do_switch(slot->host, emm_switch);
slot->cached_switch = emm_switch;
msleep(20);
writeq(wdog, slot->host->base + MIO_EMM_WDOG(host));
}
/* Switch to another slot if needed */
static void cvm_mmc_switch_to(struct cvm_mmc_slot *slot)
{
struct cvm_mmc_host *host = slot->host;
struct cvm_mmc_slot *old_slot;
u64 emm_sample, emm_switch;
if (slot->bus_id == host->last_slot)
return;
if (host->last_slot >= 0 && host->slot[host->last_slot]) {
old_slot = host->slot[host->last_slot];
old_slot->cached_switch = readq(host->base + MIO_EMM_SWITCH(host));
old_slot->cached_rca = readq(host->base + MIO_EMM_RCA(host));
}
writeq(slot->cached_rca, host->base + MIO_EMM_RCA(host));
emm_switch = slot->cached_switch;
set_bus_id(&emm_switch, slot->bus_id);
do_switch(host, emm_switch);
emm_sample = FIELD_PREP(MIO_EMM_SAMPLE_CMD_CNT, slot->cmd_cnt) |
FIELD_PREP(MIO_EMM_SAMPLE_DAT_CNT, slot->dat_cnt);
writeq(emm_sample, host->base + MIO_EMM_SAMPLE(host));
host->last_slot = slot->bus_id;
}
static void do_read(struct cvm_mmc_host *host, struct mmc_request *req,
u64 dbuf)
{
struct sg_mapping_iter *smi = &host->smi;
int data_len = req->data->blocks * req->data->blksz;
int bytes_xfered, shift = -1;
u64 dat = 0;
/* Auto inc from offset zero */
writeq((0x10000 | (dbuf << 6)), host->base + MIO_EMM_BUF_IDX(host));
for (bytes_xfered = 0; bytes_xfered < data_len;) {
if (smi->consumed >= smi->length) {
if (!sg_miter_next(smi))
break;
smi->consumed = 0;
}
if (shift < 0) {
dat = readq(host->base + MIO_EMM_BUF_DAT(host));
shift = 56;
}
while (smi->consumed < smi->length && shift >= 0) {
((u8 *)smi->addr)[smi->consumed] = (dat >> shift) & 0xff;
bytes_xfered++;
smi->consumed++;
shift -= 8;
}
}
sg_miter_stop(smi);
req->data->bytes_xfered = bytes_xfered;
req->data->error = 0;
}
static void do_write(struct mmc_request *req)
{
req->data->bytes_xfered = req->data->blocks * req->data->blksz;
req->data->error = 0;
}
static void set_cmd_response(struct cvm_mmc_host *host, struct mmc_request *req,
u64 rsp_sts)
{
u64 rsp_hi, rsp_lo;
if (!(rsp_sts & MIO_EMM_RSP_STS_RSP_VAL))
return;
rsp_lo = readq(host->base + MIO_EMM_RSP_LO(host));
switch (FIELD_GET(MIO_EMM_RSP_STS_RSP_TYPE, rsp_sts)) {
case 1:
case 3:
req->cmd->resp[0] = (rsp_lo >> 8) & 0xffffffff;
req->cmd->resp[1] = 0;
req->cmd->resp[2] = 0;
req->cmd->resp[3] = 0;
break;
case 2:
req->cmd->resp[3] = rsp_lo & 0xffffffff;
req->cmd->resp[2] = (rsp_lo >> 32) & 0xffffffff;
rsp_hi = readq(host->base + MIO_EMM_RSP_HI(host));
req->cmd->resp[1] = rsp_hi & 0xffffffff;
req->cmd->resp[0] = (rsp_hi >> 32) & 0xffffffff;
break;
}
}
static int get_dma_dir(struct mmc_data *data)
{
return (data->flags & MMC_DATA_WRITE) ? DMA_TO_DEVICE : DMA_FROM_DEVICE;
}
static int finish_dma_single(struct cvm_mmc_host *host, struct mmc_data *data)
{
data->bytes_xfered = data->blocks * data->blksz;
data->error = 0;
dma_unmap_sg(host->dev, data->sg, data->sg_len, get_dma_dir(data));
return 1;
}
static int finish_dma_sg(struct cvm_mmc_host *host, struct mmc_data *data)
{
u64 fifo_cfg;
int count;
/* Check if there are any pending requests left */
fifo_cfg = readq(host->dma_base + MIO_EMM_DMA_FIFO_CFG(host));
count = FIELD_GET(MIO_EMM_DMA_FIFO_CFG_COUNT, fifo_cfg);
if (count)
dev_err(host->dev, "%u requests still pending\n", count);
data->bytes_xfered = data->blocks * data->blksz;
data->error = 0;
/* Clear and disable FIFO */
writeq(BIT_ULL(16), host->dma_base + MIO_EMM_DMA_FIFO_CFG(host));
dma_unmap_sg(host->dev, data->sg, data->sg_len, get_dma_dir(data));
return 1;
}
static int finish_dma(struct cvm_mmc_host *host, struct mmc_data *data)
{
if (host->use_sg && data->sg_len > 1)
return finish_dma_sg(host, data);
else
return finish_dma_single(host, data);
}
static int check_status(u64 rsp_sts)
{
if (rsp_sts & MIO_EMM_RSP_STS_RSP_BAD_STS ||
rsp_sts & MIO_EMM_RSP_STS_RSP_CRC_ERR ||
rsp_sts & MIO_EMM_RSP_STS_BLK_CRC_ERR)
return -EILSEQ;
if (rsp_sts & MIO_EMM_RSP_STS_RSP_TIMEOUT ||
rsp_sts & MIO_EMM_RSP_STS_BLK_TIMEOUT)
return -ETIMEDOUT;
if (rsp_sts & MIO_EMM_RSP_STS_DBUF_ERR)
return -EIO;
return 0;
}
/* Try to clean up failed DMA. */
static void cleanup_dma(struct cvm_mmc_host *host, u64 rsp_sts)
{
u64 emm_dma;
emm_dma = readq(host->base + MIO_EMM_DMA(host));
emm_dma |= FIELD_PREP(MIO_EMM_DMA_VAL, 1) |
FIELD_PREP(MIO_EMM_DMA_DAT_NULL, 1);
set_bus_id(&emm_dma, get_bus_id(rsp_sts));
writeq(emm_dma, host->base + MIO_EMM_DMA(host));
}
irqreturn_t cvm_mmc_interrupt(int irq, void *dev_id)
{
struct cvm_mmc_host *host = dev_id;
struct mmc_request *req;
unsigned long flags = 0;
u64 emm_int, rsp_sts;
bool host_done;
if (host->need_irq_handler_lock)
spin_lock_irqsave(&host->irq_handler_lock, flags);
else
__acquire(&host->irq_handler_lock);
/* Clear interrupt bits (write 1 clears ). */
emm_int = readq(host->base + MIO_EMM_INT(host));
writeq(emm_int, host->base + MIO_EMM_INT(host));
if (emm_int & MIO_EMM_INT_SWITCH_ERR)
check_switch_errors(host);
req = host->current_req;
if (!req)
goto out;
rsp_sts = readq(host->base + MIO_EMM_RSP_STS(host));
/*
* dma_val set means DMA is still in progress. Don't touch
* the request and wait for the interrupt indicating that
* the DMA is finished.
*/
if ((rsp_sts & MIO_EMM_RSP_STS_DMA_VAL) && host->dma_active)
goto out;
if (!host->dma_active && req->data &&
(emm_int & MIO_EMM_INT_BUF_DONE)) {
unsigned int type = (rsp_sts >> 7) & 3;
if (type == 1)
do_read(host, req, rsp_sts & MIO_EMM_RSP_STS_DBUF);
else if (type == 2)
do_write(req);
}
host_done = emm_int & MIO_EMM_INT_CMD_DONE ||
emm_int & MIO_EMM_INT_DMA_DONE ||
emm_int & MIO_EMM_INT_CMD_ERR ||
emm_int & MIO_EMM_INT_DMA_ERR;
if (!(host_done && req->done))
goto no_req_done;
req->cmd->error = check_status(rsp_sts);
if (host->dma_active && req->data)
if (!finish_dma(host, req->data))
goto no_req_done;
set_cmd_response(host, req, rsp_sts);
if ((emm_int & MIO_EMM_INT_DMA_ERR) &&
(rsp_sts & MIO_EMM_RSP_STS_DMA_PEND))
cleanup_dma(host, rsp_sts);
host->current_req = NULL;
req->done(req);
no_req_done:
if (host->dmar_fixup_done)
host->dmar_fixup_done(host);
if (host_done)
host->release_bus(host);
out:
if (host->need_irq_handler_lock)
spin_unlock_irqrestore(&host->irq_handler_lock, flags);
else
__release(&host->irq_handler_lock);
return IRQ_RETVAL(emm_int != 0);
}
/*
* Program DMA_CFG and if needed DMA_ADR.
* Returns 0 on error, DMA address otherwise.
*/
static u64 prepare_dma_single(struct cvm_mmc_host *host, struct mmc_data *data)
{
u64 dma_cfg, addr;
int count, rw;
count = dma_map_sg(host->dev, data->sg, data->sg_len,
get_dma_dir(data));
if (!count)
return 0;
rw = (data->flags & MMC_DATA_WRITE) ? 1 : 0;
dma_cfg = FIELD_PREP(MIO_EMM_DMA_CFG_EN, 1) |
FIELD_PREP(MIO_EMM_DMA_CFG_RW, rw);
#ifdef __LITTLE_ENDIAN
dma_cfg |= FIELD_PREP(MIO_EMM_DMA_CFG_ENDIAN, 1);
#endif
dma_cfg |= FIELD_PREP(MIO_EMM_DMA_CFG_SIZE,
(sg_dma_len(&data->sg[0]) / 8) - 1);
addr = sg_dma_address(&data->sg[0]);
if (!host->big_dma_addr)
dma_cfg |= FIELD_PREP(MIO_EMM_DMA_CFG_ADR, addr);
writeq(dma_cfg, host->dma_base + MIO_EMM_DMA_CFG(host));
pr_debug("[%s] sg_dma_len: %u total sg_elem: %d\n",
(rw) ? "W" : "R", sg_dma_len(&data->sg[0]), count);
if (host->big_dma_addr)
writeq(addr, host->dma_base + MIO_EMM_DMA_ADR(host));
return addr;
}
/*
* Queue complete sg list into the FIFO.
* Returns 0 on error, 1 otherwise.
*/
static u64 prepare_dma_sg(struct cvm_mmc_host *host, struct mmc_data *data)
{
struct scatterlist *sg;
u64 fifo_cmd, addr;
int count, i, rw;
count = dma_map_sg(host->dev, data->sg, data->sg_len,
get_dma_dir(data));
if (!count)
return 0;
if (count > 16)
goto error;
/* Enable FIFO by removing CLR bit */
writeq(0, host->dma_base + MIO_EMM_DMA_FIFO_CFG(host));
for_each_sg(data->sg, sg, count, i) {
/* Program DMA address */
addr = sg_dma_address(sg);
if (addr & 7)
goto error;
writeq(addr, host->dma_base + MIO_EMM_DMA_FIFO_ADR(host));
/*
* If we have scatter-gather support we also have an extra
* register for the DMA addr, so no need to check
* host->big_dma_addr here.
*/
rw = (data->flags & MMC_DATA_WRITE) ? 1 : 0;
fifo_cmd = FIELD_PREP(MIO_EMM_DMA_FIFO_CMD_RW, rw);
/* enable interrupts on the last element */
fifo_cmd |= FIELD_PREP(MIO_EMM_DMA_FIFO_CMD_INTDIS,
(i + 1 == count) ? 0 : 1);
#ifdef __LITTLE_ENDIAN
fifo_cmd |= FIELD_PREP(MIO_EMM_DMA_FIFO_CMD_ENDIAN, 1);
#endif
fifo_cmd |= FIELD_PREP(MIO_EMM_DMA_FIFO_CMD_SIZE,
sg_dma_len(sg) / 8 - 1);
/*
* The write copies the address and the command to the FIFO
* and increments the FIFO's COUNT field.
*/
writeq(fifo_cmd, host->dma_base + MIO_EMM_DMA_FIFO_CMD(host));
pr_debug("[%s] sg_dma_len: %u sg_elem: %d/%d\n",
(rw) ? "W" : "R", sg_dma_len(sg), i, count);
}
/*
* In difference to prepare_dma_single we don't return the
* address here, as it would not make sense for scatter-gather.
* The dma fixup is only required on models that don't support
* scatter-gather, so that is not a problem.
*/
return 1;
error:
WARN_ON_ONCE(1);
dma_unmap_sg(host->dev, data->sg, data->sg_len, get_dma_dir(data));
/* Disable FIFO */
writeq(BIT_ULL(16), host->dma_base + MIO_EMM_DMA_FIFO_CFG(host));
return 0;
}
static u64 prepare_dma(struct cvm_mmc_host *host, struct mmc_data *data)
{
if (host->use_sg && data->sg_len > 1)
return prepare_dma_sg(host, data);
else
return prepare_dma_single(host, data);
}
static u64 prepare_ext_dma(struct mmc_host *mmc, struct mmc_request *mrq)
{
struct cvm_mmc_slot *slot = mmc_priv(mmc);
u64 emm_dma;
emm_dma = FIELD_PREP(MIO_EMM_DMA_VAL, 1) |
FIELD_PREP(MIO_EMM_DMA_SECTOR,
mmc_card_is_blockaddr(mmc->card) ? 1 : 0) |
FIELD_PREP(MIO_EMM_DMA_RW,
(mrq->data->flags & MMC_DATA_WRITE) ? 1 : 0) |
FIELD_PREP(MIO_EMM_DMA_BLOCK_CNT, mrq->data->blocks) |
FIELD_PREP(MIO_EMM_DMA_CARD_ADDR, mrq->cmd->arg);
set_bus_id(&emm_dma, slot->bus_id);
if (mmc_card_mmc(mmc->card) || (mmc_card_sd(mmc->card) &&
(mmc->card->scr.cmds & SD_SCR_CMD23_SUPPORT)))
emm_dma |= FIELD_PREP(MIO_EMM_DMA_MULTI, 1);
pr_debug("[%s] blocks: %u multi: %d\n",
(emm_dma & MIO_EMM_DMA_RW) ? "W" : "R",
mrq->data->blocks, (emm_dma & MIO_EMM_DMA_MULTI) ? 1 : 0);
return emm_dma;
}
static void cvm_mmc_dma_request(struct mmc_host *mmc,
struct mmc_request *mrq)
{
struct cvm_mmc_slot *slot = mmc_priv(mmc);
struct cvm_mmc_host *host = slot->host;
struct mmc_data *data;
u64 emm_dma, addr;
if (!mrq->data || !mrq->data->sg || !mrq->data->sg_len ||
!mrq->stop || mrq->stop->opcode != MMC_STOP_TRANSMISSION) {
dev_err(&mmc->card->dev,
"Error: cmv_mmc_dma_request no data\n");
goto error;
}
cvm_mmc_switch_to(slot);
data = mrq->data;
pr_debug("DMA request blocks: %d block_size: %d total_size: %d\n",
data->blocks, data->blksz, data->blocks * data->blksz);
if (data->timeout_ns)
set_wdog(slot, data->timeout_ns);
WARN_ON(host->current_req);
host->current_req = mrq;
emm_dma = prepare_ext_dma(mmc, mrq);
addr = prepare_dma(host, data);
if (!addr) {
dev_err(host->dev, "prepare_dma failed\n");
goto error;
}
host->dma_active = true;
host->int_enable(host, MIO_EMM_INT_CMD_ERR | MIO_EMM_INT_DMA_DONE |
MIO_EMM_INT_DMA_ERR);
if (host->dmar_fixup)
host->dmar_fixup(host, mrq->cmd, data, addr);
/*
* If we have a valid SD card in the slot, we set the response
* bit mask to check for CRC errors and timeouts only.
* Otherwise, use the default power reset value.
*/
if (mmc_card_sd(mmc->card))
writeq(0x00b00000ull, host->base + MIO_EMM_STS_MASK(host));
else
writeq(0xe4390080ull, host->base + MIO_EMM_STS_MASK(host));
writeq(emm_dma, host->base + MIO_EMM_DMA(host));
return;
error:
mrq->cmd->error = -EINVAL;
if (mrq->done)
mrq->done(mrq);
host->release_bus(host);
}
static void do_read_request(struct cvm_mmc_host *host, struct mmc_request *mrq)
{
sg_miter_start(&host->smi, mrq->data->sg, mrq->data->sg_len,
SG_MITER_ATOMIC | SG_MITER_TO_SG);
}
static void do_write_request(struct cvm_mmc_host *host, struct mmc_request *mrq)
{
unsigned int data_len = mrq->data->blocks * mrq->data->blksz;
struct sg_mapping_iter *smi = &host->smi;
unsigned int bytes_xfered;
int shift = 56;
u64 dat = 0;
/* Copy data to the xmit buffer before issuing the command. */
sg_miter_start(smi, mrq->data->sg, mrq->data->sg_len, SG_MITER_FROM_SG);
/* Auto inc from offset zero, dbuf zero */
writeq(0x10000ull, host->base + MIO_EMM_BUF_IDX(host));
for (bytes_xfered = 0; bytes_xfered < data_len;) {
if (smi->consumed >= smi->length) {
if (!sg_miter_next(smi))
break;
smi->consumed = 0;
}
while (smi->consumed < smi->length && shift >= 0) {
dat |= (u64)((u8 *)smi->addr)[smi->consumed] << shift;
bytes_xfered++;
smi->consumed++;
shift -= 8;
}
if (shift < 0) {
writeq(dat, host->base + MIO_EMM_BUF_DAT(host));
shift = 56;
dat = 0;
}
}
sg_miter_stop(smi);
}
static void cvm_mmc_request(struct mmc_host *mmc, struct mmc_request *mrq)
{
struct cvm_mmc_slot *slot = mmc_priv(mmc);
struct cvm_mmc_host *host = slot->host;
struct mmc_command *cmd = mrq->cmd;
struct cvm_mmc_cr_mods mods;
u64 emm_cmd, rsp_sts;
int retries = 100;
/*
* Note about locking:
* All MMC devices share the same bus and controller. Allow only a
* single user of the bootbus/MMC bus at a time. The lock is acquired
* on all entry points from the MMC layer.
*
* For requests the lock is only released after the completion
* interrupt!
*/
host->acquire_bus(host);
if (cmd->opcode == MMC_READ_MULTIPLE_BLOCK ||
cmd->opcode == MMC_WRITE_MULTIPLE_BLOCK)
return cvm_mmc_dma_request(mmc, mrq);
cvm_mmc_switch_to(slot);
mods = cvm_mmc_get_cr_mods(cmd);
WARN_ON(host->current_req);
host->current_req = mrq;
if (cmd->data) {
if (cmd->data->flags & MMC_DATA_READ)
do_read_request(host, mrq);
else
do_write_request(host, mrq);
if (cmd->data->timeout_ns)
set_wdog(slot, cmd->data->timeout_ns);
} else
set_wdog(slot, 0);
host->dma_active = false;
host->int_enable(host, MIO_EMM_INT_CMD_DONE | MIO_EMM_INT_CMD_ERR);
emm_cmd = FIELD_PREP(MIO_EMM_CMD_VAL, 1) |
FIELD_PREP(MIO_EMM_CMD_CTYPE_XOR, mods.ctype_xor) |
FIELD_PREP(MIO_EMM_CMD_RTYPE_XOR, mods.rtype_xor) |
FIELD_PREP(MIO_EMM_CMD_IDX, cmd->opcode) |
FIELD_PREP(MIO_EMM_CMD_ARG, cmd->arg);
set_bus_id(&emm_cmd, slot->bus_id);
if (cmd->data && mmc_cmd_type(cmd) == MMC_CMD_ADTC)
emm_cmd |= FIELD_PREP(MIO_EMM_CMD_OFFSET,
64 - ((cmd->data->blocks * cmd->data->blksz) / 8));
writeq(0, host->base + MIO_EMM_STS_MASK(host));
retry:
rsp_sts = readq(host->base + MIO_EMM_RSP_STS(host));
if (rsp_sts & MIO_EMM_RSP_STS_DMA_VAL ||
rsp_sts & MIO_EMM_RSP_STS_CMD_VAL ||
rsp_sts & MIO_EMM_RSP_STS_SWITCH_VAL ||
rsp_sts & MIO_EMM_RSP_STS_DMA_PEND) {
udelay(10);
if (--retries)
goto retry;
}
if (!retries)
dev_err(host->dev, "Bad status: %llx before command write\n", rsp_sts);
writeq(emm_cmd, host->base + MIO_EMM_CMD(host));
}
static void cvm_mmc_set_ios(struct mmc_host *mmc, struct mmc_ios *ios)
{
struct cvm_mmc_slot *slot = mmc_priv(mmc);
struct cvm_mmc_host *host = slot->host;
int clk_period = 0, power_class = 10, bus_width = 0;
u64 clock, emm_switch;
host->acquire_bus(host);
cvm_mmc_switch_to(slot);
/* Set the power state */
switch (ios->power_mode) {
case MMC_POWER_ON:
break;
case MMC_POWER_OFF:
cvm_mmc_reset_bus(slot);
if (host->global_pwr_gpiod)
host->set_shared_power(host, 0);
else if (!IS_ERR(mmc->supply.vmmc))
mmc_regulator_set_ocr(mmc, mmc->supply.vmmc, 0);
break;
case MMC_POWER_UP:
if (host->global_pwr_gpiod)
host->set_shared_power(host, 1);
else if (!IS_ERR(mmc->supply.vmmc))
mmc_regulator_set_ocr(mmc, mmc->supply.vmmc, ios->vdd);
break;
}
/* Convert bus width to HW definition */
switch (ios->bus_width) {
case MMC_BUS_WIDTH_8:
bus_width = 2;
break;
case MMC_BUS_WIDTH_4:
bus_width = 1;
break;
case MMC_BUS_WIDTH_1:
bus_width = 0;
break;
}
/* DDR is available for 4/8 bit bus width */
if (ios->bus_width && ios->timing == MMC_TIMING_MMC_DDR52)
bus_width |= 4;
/* Change the clock frequency. */
clock = ios->clock;
if (clock > 52000000)
clock = 52000000;
slot->clock = clock;
if (clock)
clk_period = (host->sys_freq + clock - 1) / (2 * clock);
emm_switch = FIELD_PREP(MIO_EMM_SWITCH_HS_TIMING,
(ios->timing == MMC_TIMING_MMC_HS)) |
FIELD_PREP(MIO_EMM_SWITCH_BUS_WIDTH, bus_width) |
FIELD_PREP(MIO_EMM_SWITCH_POWER_CLASS, power_class) |
FIELD_PREP(MIO_EMM_SWITCH_CLK_HI, clk_period) |
FIELD_PREP(MIO_EMM_SWITCH_CLK_LO, clk_period);
set_bus_id(&emm_switch, slot->bus_id);
if (!switch_val_changed(slot, emm_switch))
goto out;
set_wdog(slot, 0);
do_switch(host, emm_switch);
slot->cached_switch = emm_switch;
out:
host->release_bus(host);
}
static const struct mmc_host_ops cvm_mmc_ops = {
.request = cvm_mmc_request,
.set_ios = cvm_mmc_set_ios,
.get_ro = mmc_gpio_get_ro,
.get_cd = mmc_gpio_get_cd,
};
static void cvm_mmc_set_clock(struct cvm_mmc_slot *slot, unsigned int clock)
{
struct mmc_host *mmc = slot->mmc;
clock = min(clock, mmc->f_max);
clock = max(clock, mmc->f_min);
slot->clock = clock;
}
static int cvm_mmc_init_lowlevel(struct cvm_mmc_slot *slot)
{
struct cvm_mmc_host *host = slot->host;
u64 emm_switch;
/* Enable this bus slot. */
host->emm_cfg |= (1ull << slot->bus_id);
writeq(host->emm_cfg, slot->host->base + MIO_EMM_CFG(host));
udelay(10);
/* Program initial clock speed and power. */
cvm_mmc_set_clock(slot, slot->mmc->f_min);
emm_switch = FIELD_PREP(MIO_EMM_SWITCH_POWER_CLASS, 10);
emm_switch |= FIELD_PREP(MIO_EMM_SWITCH_CLK_HI,
(host->sys_freq / slot->clock) / 2);
emm_switch |= FIELD_PREP(MIO_EMM_SWITCH_CLK_LO,
(host->sys_freq / slot->clock) / 2);
/* Make the changes take effect on this bus slot. */
set_bus_id(&emm_switch, slot->bus_id);
do_switch(host, emm_switch);
slot->cached_switch = emm_switch;
/*
* Set watchdog timeout value and default reset value
* for the mask register. Finally, set the CARD_RCA
* bit so that we can get the card address relative
* to the CMD register for CMD7 transactions.
*/
set_wdog(slot, 0);
writeq(0xe4390080ull, host->base + MIO_EMM_STS_MASK(host));
writeq(1, host->base + MIO_EMM_RCA(host));
return 0;
}
static int cvm_mmc_of_parse(struct device *dev, struct cvm_mmc_slot *slot)
{
u32 id, cmd_skew = 0, dat_skew = 0, bus_width = 0;
struct device_node *node = dev->of_node;
struct mmc_host *mmc = slot->mmc;
u64 clock_period;
int ret;
ret = of_property_read_u32(node, "reg", &id);
if (ret) {
dev_err(dev, "Missing or invalid reg property on %pOF\n", node);
return ret;
}
if (id >= CAVIUM_MAX_MMC || slot->host->slot[id]) {
dev_err(dev, "Invalid reg property on %pOF\n", node);
return -EINVAL;
}
ret = mmc_regulator_get_supply(mmc);
if (ret)
return ret;
/*
* Legacy Octeon firmware has no regulator entry, fall-back to
* a hard-coded voltage to get a sane OCR.
*/
if (IS_ERR(mmc->supply.vmmc))
mmc->ocr_avail = MMC_VDD_32_33 | MMC_VDD_33_34;
/* Common MMC bindings */
ret = mmc_of_parse(mmc);
if (ret)
return ret;
/* Set bus width */
if (!(mmc->caps & (MMC_CAP_8_BIT_DATA | MMC_CAP_4_BIT_DATA))) {
of_property_read_u32(node, "cavium,bus-max-width", &bus_width);
if (bus_width == 8)
mmc->caps |= MMC_CAP_8_BIT_DATA | MMC_CAP_4_BIT_DATA;
else if (bus_width == 4)
mmc->caps |= MMC_CAP_4_BIT_DATA;
}
/* Set maximum and minimum frequency */
if (!mmc->f_max)
of_property_read_u32(node, "spi-max-frequency", &mmc->f_max);
if (!mmc->f_max || mmc->f_max > 52000000)
mmc->f_max = 52000000;
mmc->f_min = 400000;
/* Sampling register settings, period in picoseconds */
clock_period = 1000000000000ull / slot->host->sys_freq;
of_property_read_u32(node, "cavium,cmd-clk-skew", &cmd_skew);
of_property_read_u32(node, "cavium,dat-clk-skew", &dat_skew);
slot->cmd_cnt = (cmd_skew + clock_period / 2) / clock_period;
slot->dat_cnt = (dat_skew + clock_period / 2) / clock_period;
return id;
}
int cvm_mmc_of_slot_probe(struct device *dev, struct cvm_mmc_host *host)
{
struct cvm_mmc_slot *slot;
struct mmc_host *mmc;
int ret, id;
mmc = mmc_alloc_host(sizeof(struct cvm_mmc_slot), dev);
if (!mmc)
return -ENOMEM;
slot = mmc_priv(mmc);
slot->mmc = mmc;
slot->host = host;
ret = cvm_mmc_of_parse(dev, slot);
if (ret < 0)
goto error;
id = ret;
/* Set up host parameters */
mmc->ops = &cvm_mmc_ops;
/*
* We only have a 3.3v supply, we cannot support any
* of the UHS modes. We do support the high speed DDR
* modes up to 52MHz.
*
* Disable bounce buffers for max_segs = 1
*/
mmc->caps |= MMC_CAP_MMC_HIGHSPEED | MMC_CAP_SD_HIGHSPEED |
MMC_CAP_CMD23 | MMC_CAP_POWER_OFF_CARD | MMC_CAP_3_3V_DDR;
if (host->use_sg)
mmc->max_segs = 16;
else
mmc->max_segs = 1;
/* DMA size field can address up to 8 MB */
mmc->max_seg_size = min_t(unsigned int, 8 * 1024 * 1024,
dma_get_max_seg_size(host->dev));
mmc->max_req_size = mmc->max_seg_size;
/* External DMA is in 512 byte blocks */
mmc->max_blk_size = 512;
/* DMA block count field is 15 bits */
mmc->max_blk_count = 32767;
slot->clock = mmc->f_min;
slot->bus_id = id;
slot->cached_rca = 1;
host->acquire_bus(host);
host->slot[id] = slot;
cvm_mmc_switch_to(slot);
cvm_mmc_init_lowlevel(slot);
host->release_bus(host);
ret = mmc_add_host(mmc);
if (ret) {
dev_err(dev, "mmc_add_host() returned %d\n", ret);
slot->host->slot[id] = NULL;
goto error;
}
return 0;
error:
mmc_free_host(slot->mmc);
return ret;
}
int cvm_mmc_of_slot_remove(struct cvm_mmc_slot *slot)
{
mmc_remove_host(slot->mmc);
slot->host->slot[slot->bus_id] = NULL;
mmc_free_host(slot->mmc);
return 0;
}
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