linux/drivers/mmc/host/mmc_spi.c

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/*
* mmc_spi.c - Access SD/MMC cards through SPI master controllers
*
* (C) Copyright 2005, Intec Automation,
* Mike Lavender (mike@steroidmicros)
* (C) Copyright 2006-2007, David Brownell
* (C) Copyright 2007, Axis Communications,
* Hans-Peter Nilsson (hp@axis.com)
* (C) Copyright 2007, ATRON electronic GmbH,
* Jan Nikitenko <jan.nikitenko@gmail.com>
*
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <linux/sched.h>
#include <linux/delay.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 16:04:11 +08:00
#include <linux/slab.h>
#include <linux/module.h>
#include <linux/bio.h>
#include <linux/dma-mapping.h>
#include <linux/crc7.h>
#include <linux/crc-itu-t.h>
#include <linux/scatterlist.h>
#include <linux/mmc/host.h>
#include <linux/mmc/mmc.h> /* for R1_SPI_* bit values */
#include <linux/mmc/slot-gpio.h>
#include <linux/spi/spi.h>
#include <linux/spi/mmc_spi.h>
#include <asm/unaligned.h>
/* NOTES:
*
* - For now, we won't try to interoperate with a real mmc/sd/sdio
* controller, although some of them do have hardware support for
* SPI protocol. The main reason for such configs would be mmc-ish
* cards like DataFlash, which don't support that "native" protocol.
*
* We don't have a "DataFlash/MMC/SD/SDIO card slot" abstraction to
* switch between driver stacks, and in any case if "native" mode
* is available, it will be faster and hence preferable.
*
* - MMC depends on a different chipselect management policy than the
* SPI interface currently supports for shared bus segments: it needs
* to issue multiple spi_message requests with the chipselect active,
* using the results of one message to decide the next one to issue.
*
* Pending updates to the programming interface, this driver expects
* that it not share the bus with other drivers (precluding conflicts).
*
* - We tell the controller to keep the chipselect active from the
* beginning of an mmc_host_ops.request until the end. So beware
* of SPI controller drivers that mis-handle the cs_change flag!
*
* However, many cards seem OK with chipselect flapping up/down
* during that time ... at least on unshared bus segments.
*/
/*
* Local protocol constants, internal to data block protocols.
*/
/* Response tokens used to ack each block written: */
#define SPI_MMC_RESPONSE_CODE(x) ((x) & 0x1f)
#define SPI_RESPONSE_ACCEPTED ((2 << 1)|1)
#define SPI_RESPONSE_CRC_ERR ((5 << 1)|1)
#define SPI_RESPONSE_WRITE_ERR ((6 << 1)|1)
/* Read and write blocks start with these tokens and end with crc;
* on error, read tokens act like a subset of R2_SPI_* values.
*/
#define SPI_TOKEN_SINGLE 0xfe /* single block r/w, multiblock read */
#define SPI_TOKEN_MULTI_WRITE 0xfc /* multiblock write */
#define SPI_TOKEN_STOP_TRAN 0xfd /* terminate multiblock write */
#define MMC_SPI_BLOCKSIZE 512
/* These fixed timeouts come from the latest SD specs, which say to ignore
* the CSD values. The R1B value is for card erase (e.g. the "I forgot the
* card's password" scenario); it's mostly applied to STOP_TRANSMISSION after
* reads which takes nowhere near that long. Older cards may be able to use
* shorter timeouts ... but why bother?
*/
#define r1b_timeout (HZ * 3)
/* One of the critical speed parameters is the amount of data which may
* be transferred in one command. If this value is too low, the SD card
* controller has to do multiple partial block writes (argggh!). With
* today (2008) SD cards there is little speed gain if we transfer more
* than 64 KBytes at a time. So use this value until there is any indication
* that we should do more here.
*/
#define MMC_SPI_BLOCKSATONCE 128
/****************************************************************************/
/*
* Local Data Structures
*/
/* "scratch" is per-{command,block} data exchanged with the card */
struct scratch {
u8 status[29];
u8 data_token;
__be16 crc_val;
};
struct mmc_spi_host {
struct mmc_host *mmc;
struct spi_device *spi;
unsigned char power_mode;
u16 powerup_msecs;
struct mmc_spi_platform_data *pdata;
/* for bulk data transfers */
struct spi_transfer token, t, crc, early_status;
struct spi_message m;
/* for status readback */
struct spi_transfer status;
struct spi_message readback;
/* underlying DMA-aware controller, or null */
struct device *dma_dev;
/* buffer used for commands and for message "overhead" */
struct scratch *data;
dma_addr_t data_dma;
/* Specs say to write ones most of the time, even when the card
* has no need to read its input data; and many cards won't care.
* This is our source of those ones.
*/
void *ones;
dma_addr_t ones_dma;
};
/****************************************************************************/
/*
* MMC-over-SPI protocol glue, used by the MMC stack interface
*/
static inline int mmc_cs_off(struct mmc_spi_host *host)
{
/* chipselect will always be inactive after setup() */
return spi_setup(host->spi);
}
static int
mmc_spi_readbytes(struct mmc_spi_host *host, unsigned len)
{
int status;
if (len > sizeof(*host->data)) {
WARN_ON(1);
return -EIO;
}
host->status.len = len;
if (host->dma_dev)
dma_sync_single_for_device(host->dma_dev,
host->data_dma, sizeof(*host->data),
DMA_FROM_DEVICE);
status = spi_sync_locked(host->spi, &host->readback);
if (host->dma_dev)
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*host->data),
DMA_FROM_DEVICE);
return status;
}
static int mmc_spi_skip(struct mmc_spi_host *host, unsigned long timeout,
unsigned n, u8 byte)
{
u8 *cp = host->data->status;
unsigned long start = jiffies;
while (1) {
int status;
unsigned i;
status = mmc_spi_readbytes(host, n);
if (status < 0)
return status;
for (i = 0; i < n; i++) {
if (cp[i] != byte)
return cp[i];
}
if (time_is_before_jiffies(start + timeout))
break;
/* If we need long timeouts, we may release the CPU.
* We use jiffies here because we want to have a relation
* between elapsed time and the blocking of the scheduler.
*/
if (time_is_before_jiffies(start+1))
schedule();
}
return -ETIMEDOUT;
}
static inline int
mmc_spi_wait_unbusy(struct mmc_spi_host *host, unsigned long timeout)
{
return mmc_spi_skip(host, timeout, sizeof(host->data->status), 0);
}
static int mmc_spi_readtoken(struct mmc_spi_host *host, unsigned long timeout)
{
return mmc_spi_skip(host, timeout, 1, 0xff);
}
/*
* Note that for SPI, cmd->resp[0] is not the same data as "native" protocol
* hosts return! The low byte holds R1_SPI bits. The next byte may hold
* R2_SPI bits ... for SEND_STATUS, or after data read errors.
*
* cmd->resp[1] holds any four-byte response, for R3 (READ_OCR) and on
* newer cards R7 (IF_COND).
*/
static char *maptype(struct mmc_command *cmd)
{
switch (mmc_spi_resp_type(cmd)) {
case MMC_RSP_SPI_R1: return "R1";
case MMC_RSP_SPI_R1B: return "R1B";
case MMC_RSP_SPI_R2: return "R2/R5";
case MMC_RSP_SPI_R3: return "R3/R4/R7";
default: return "?";
}
}
/* return zero, else negative errno after setting cmd->error */
static int mmc_spi_response_get(struct mmc_spi_host *host,
struct mmc_command *cmd, int cs_on)
{
u8 *cp = host->data->status;
u8 *end = cp + host->t.len;
int value = 0;
int bitshift;
u8 leftover = 0;
unsigned short rotator;
int i;
char tag[32];
snprintf(tag, sizeof(tag), " ... CMD%d response SPI_%s",
cmd->opcode, maptype(cmd));
/* Except for data block reads, the whole response will already
* be stored in the scratch buffer. It's somewhere after the
* command and the first byte we read after it. We ignore that
* first byte. After STOP_TRANSMISSION command it may include
* two data bits, but otherwise it's all ones.
*/
cp += 8;
while (cp < end && *cp == 0xff)
cp++;
/* Data block reads (R1 response types) may need more data... */
if (cp == end) {
cp = host->data->status;
end = cp+1;
/* Card sends N(CR) (== 1..8) bytes of all-ones then one
* status byte ... and we already scanned 2 bytes.
*
* REVISIT block read paths use nasty byte-at-a-time I/O
* so it can always DMA directly into the target buffer.
* It'd probably be better to memcpy() the first chunk and
* avoid extra i/o calls...
*
* Note we check for more than 8 bytes, because in practice,
* some SD cards are slow...
*/
for (i = 2; i < 16; i++) {
value = mmc_spi_readbytes(host, 1);
if (value < 0)
goto done;
if (*cp != 0xff)
goto checkstatus;
}
value = -ETIMEDOUT;
goto done;
}
checkstatus:
bitshift = 0;
if (*cp & 0x80) {
/* Houston, we have an ugly card with a bit-shifted response */
rotator = *cp++ << 8;
/* read the next byte */
if (cp == end) {
value = mmc_spi_readbytes(host, 1);
if (value < 0)
goto done;
cp = host->data->status;
end = cp+1;
}
rotator |= *cp++;
while (rotator & 0x8000) {
bitshift++;
rotator <<= 1;
}
cmd->resp[0] = rotator >> 8;
leftover = rotator;
} else {
cmd->resp[0] = *cp++;
}
cmd->error = 0;
/* Status byte: the entire seven-bit R1 response. */
if (cmd->resp[0] != 0) {
if ((R1_SPI_PARAMETER | R1_SPI_ADDRESS)
& cmd->resp[0])
value = -EFAULT; /* Bad address */
else if (R1_SPI_ILLEGAL_COMMAND & cmd->resp[0])
value = -ENOSYS; /* Function not implemented */
else if (R1_SPI_COM_CRC & cmd->resp[0])
value = -EILSEQ; /* Illegal byte sequence */
else if ((R1_SPI_ERASE_SEQ | R1_SPI_ERASE_RESET)
& cmd->resp[0])
value = -EIO; /* I/O error */
/* else R1_SPI_IDLE, "it's resetting" */
}
switch (mmc_spi_resp_type(cmd)) {
/* SPI R1B == R1 + busy; STOP_TRANSMISSION (for multiblock reads)
* and less-common stuff like various erase operations.
*/
case MMC_RSP_SPI_R1B:
/* maybe we read all the busy tokens already */
while (cp < end && *cp == 0)
cp++;
if (cp == end)
mmc_spi_wait_unbusy(host, r1b_timeout);
break;
/* SPI R2 == R1 + second status byte; SEND_STATUS
* SPI R5 == R1 + data byte; IO_RW_DIRECT
*/
case MMC_RSP_SPI_R2:
/* read the next byte */
if (cp == end) {
value = mmc_spi_readbytes(host, 1);
if (value < 0)
goto done;
cp = host->data->status;
end = cp+1;
}
if (bitshift) {
rotator = leftover << 8;
rotator |= *cp << bitshift;
cmd->resp[0] |= (rotator & 0xFF00);
} else {
cmd->resp[0] |= *cp << 8;
}
break;
/* SPI R3, R4, or R7 == R1 + 4 bytes */
case MMC_RSP_SPI_R3:
rotator = leftover << 8;
cmd->resp[1] = 0;
for (i = 0; i < 4; i++) {
cmd->resp[1] <<= 8;
/* read the next byte */
if (cp == end) {
value = mmc_spi_readbytes(host, 1);
if (value < 0)
goto done;
cp = host->data->status;
end = cp+1;
}
if (bitshift) {
rotator |= *cp++ << bitshift;
cmd->resp[1] |= (rotator >> 8);
rotator <<= 8;
} else {
cmd->resp[1] |= *cp++;
}
}
break;
/* SPI R1 == just one status byte */
case MMC_RSP_SPI_R1:
break;
default:
dev_dbg(&host->spi->dev, "bad response type %04x\n",
mmc_spi_resp_type(cmd));
if (value >= 0)
value = -EINVAL;
goto done;
}
if (value < 0)
dev_dbg(&host->spi->dev, "%s: resp %04x %08x\n",
tag, cmd->resp[0], cmd->resp[1]);
/* disable chipselect on errors and some success cases */
if (value >= 0 && cs_on)
return value;
done:
if (value < 0)
cmd->error = value;
mmc_cs_off(host);
return value;
}
/* Issue command and read its response.
* Returns zero on success, negative for error.
*
* On error, caller must cope with mmc core retry mechanism. That
* means immediate low-level resubmit, which affects the bus lock...
*/
static int
mmc_spi_command_send(struct mmc_spi_host *host,
struct mmc_request *mrq,
struct mmc_command *cmd, int cs_on)
{
struct scratch *data = host->data;
u8 *cp = data->status;
int status;
struct spi_transfer *t;
/* We can handle most commands (except block reads) in one full
* duplex I/O operation before either starting the next transfer
* (data block or command) or else deselecting the card.
*
* First, write 7 bytes:
* - an all-ones byte to ensure the card is ready
* - opcode byte (plus start and transmission bits)
* - four bytes of big-endian argument
* - crc7 (plus end bit) ... always computed, it's cheap
*
* We init the whole buffer to all-ones, which is what we need
* to write while we're reading (later) response data.
*/
memset(cp, 0xff, sizeof(data->status));
cp[1] = 0x40 | cmd->opcode;
put_unaligned_be32(cmd->arg, cp+2);
cp[6] = crc7_be(0, cp+1, 5) | 0x01;
cp += 7;
/* Then, read up to 13 bytes (while writing all-ones):
* - N(CR) (== 1..8) bytes of all-ones
* - status byte (for all response types)
* - the rest of the response, either:
* + nothing, for R1 or R1B responses
* + second status byte, for R2 responses
* + four data bytes, for R3 and R7 responses
*
* Finally, read some more bytes ... in the nice cases we know in
* advance how many, and reading 1 more is always OK:
* - N(EC) (== 0..N) bytes of all-ones, before deselect/finish
* - N(RC) (== 1..N) bytes of all-ones, before next command
* - N(WR) (== 1..N) bytes of all-ones, before data write
*
* So in those cases one full duplex I/O of at most 21 bytes will
* handle the whole command, leaving the card ready to receive a
* data block or new command. We do that whenever we can, shaving
* CPU and IRQ costs (especially when using DMA or FIFOs).
*
* There are two other cases, where it's not generally practical
* to rely on a single I/O:
*
* - R1B responses need at least N(EC) bytes of all-zeroes.
*
* In this case we can *try* to fit it into one I/O, then
* maybe read more data later.
*
* - Data block reads are more troublesome, since a variable
* number of padding bytes precede the token and data.
* + N(CX) (== 0..8) bytes of all-ones, before CSD or CID
* + N(AC) (== 1..many) bytes of all-ones
*
* In this case we currently only have minimal speedups here:
* when N(CR) == 1 we can avoid I/O in response_get().
*/
if (cs_on && (mrq->data->flags & MMC_DATA_READ)) {
cp += 2; /* min(N(CR)) + status */
/* R1 */
} else {
cp += 10; /* max(N(CR)) + status + min(N(RC),N(WR)) */
if (cmd->flags & MMC_RSP_SPI_S2) /* R2/R5 */
cp++;
else if (cmd->flags & MMC_RSP_SPI_B4) /* R3/R4/R7 */
cp += 4;
else if (cmd->flags & MMC_RSP_BUSY) /* R1B */
cp = data->status + sizeof(data->status);
/* else: R1 (most commands) */
}
dev_dbg(&host->spi->dev, " mmc_spi: CMD%d, resp %s\n",
cmd->opcode, maptype(cmd));
/* send command, leaving chipselect active */
spi_message_init(&host->m);
t = &host->t;
memset(t, 0, sizeof(*t));
t->tx_buf = t->rx_buf = data->status;
t->tx_dma = t->rx_dma = host->data_dma;
t->len = cp - data->status;
t->cs_change = 1;
spi_message_add_tail(t, &host->m);
if (host->dma_dev) {
host->m.is_dma_mapped = 1;
dma_sync_single_for_device(host->dma_dev,
host->data_dma, sizeof(*host->data),
DMA_BIDIRECTIONAL);
}
status = spi_sync_locked(host->spi, &host->m);
if (host->dma_dev)
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*host->data),
DMA_BIDIRECTIONAL);
if (status < 0) {
dev_dbg(&host->spi->dev, " ... write returned %d\n", status);
cmd->error = status;
return status;
}
/* after no-data commands and STOP_TRANSMISSION, chipselect off */
return mmc_spi_response_get(host, cmd, cs_on);
}
/* Build data message with up to four separate transfers. For TX, we
* start by writing the data token. And in most cases, we finish with
* a status transfer.
*
* We always provide TX data for data and CRC. The MMC/SD protocol
* requires us to write ones; but Linux defaults to writing zeroes;
* so we explicitly initialize it to all ones on RX paths.
*
* We also handle DMA mapping, so the underlying SPI controller does
* not need to (re)do it for each message.
*/
static void
mmc_spi_setup_data_message(
struct mmc_spi_host *host,
int multiple,
enum dma_data_direction direction)
{
struct spi_transfer *t;
struct scratch *scratch = host->data;
dma_addr_t dma = host->data_dma;
spi_message_init(&host->m);
if (dma)
host->m.is_dma_mapped = 1;
/* for reads, readblock() skips 0xff bytes before finding
* the token; for writes, this transfer issues that token.
*/
if (direction == DMA_TO_DEVICE) {
t = &host->token;
memset(t, 0, sizeof(*t));
t->len = 1;
if (multiple)
scratch->data_token = SPI_TOKEN_MULTI_WRITE;
else
scratch->data_token = SPI_TOKEN_SINGLE;
t->tx_buf = &scratch->data_token;
if (dma)
t->tx_dma = dma + offsetof(struct scratch, data_token);
spi_message_add_tail(t, &host->m);
}
/* Body of transfer is buffer, then CRC ...
* either TX-only, or RX with TX-ones.
*/
t = &host->t;
memset(t, 0, sizeof(*t));
t->tx_buf = host->ones;
t->tx_dma = host->ones_dma;
/* length and actual buffer info are written later */
spi_message_add_tail(t, &host->m);
t = &host->crc;
memset(t, 0, sizeof(*t));
t->len = 2;
if (direction == DMA_TO_DEVICE) {
/* the actual CRC may get written later */
t->tx_buf = &scratch->crc_val;
if (dma)
t->tx_dma = dma + offsetof(struct scratch, crc_val);
} else {
t->tx_buf = host->ones;
t->tx_dma = host->ones_dma;
t->rx_buf = &scratch->crc_val;
if (dma)
t->rx_dma = dma + offsetof(struct scratch, crc_val);
}
spi_message_add_tail(t, &host->m);
/*
* A single block read is followed by N(EC) [0+] all-ones bytes
* before deselect ... don't bother.
*
* Multiblock reads are followed by N(AC) [1+] all-ones bytes before
* the next block is read, or a STOP_TRANSMISSION is issued. We'll
* collect that single byte, so readblock() doesn't need to.
*
* For a write, the one-byte data response follows immediately, then
* come zero or more busy bytes, then N(WR) [1+] all-ones bytes.
* Then single block reads may deselect, and multiblock ones issue
* the next token (next data block, or STOP_TRAN). We can try to
* minimize I/O ops by using a single read to collect end-of-busy.
*/
if (multiple || direction == DMA_TO_DEVICE) {
t = &host->early_status;
memset(t, 0, sizeof(*t));
t->len = (direction == DMA_TO_DEVICE)
? sizeof(scratch->status)
: 1;
t->tx_buf = host->ones;
t->tx_dma = host->ones_dma;
t->rx_buf = scratch->status;
if (dma)
t->rx_dma = dma + offsetof(struct scratch, status);
t->cs_change = 1;
spi_message_add_tail(t, &host->m);
}
}
/*
* Write one block:
* - caller handled preceding N(WR) [1+] all-ones bytes
* - data block
* + token
* + data bytes
* + crc16
* - an all-ones byte ... card writes a data-response byte
* - followed by N(EC) [0+] all-ones bytes, card writes zero/'busy'
*
* Return negative errno, else success.
*/
static int
mmc_spi_writeblock(struct mmc_spi_host *host, struct spi_transfer *t,
unsigned long timeout)
{
struct spi_device *spi = host->spi;
int status, i;
struct scratch *scratch = host->data;
u32 pattern;
if (host->mmc->use_spi_crc)
scratch->crc_val = cpu_to_be16(
crc_itu_t(0, t->tx_buf, t->len));
if (host->dma_dev)
dma_sync_single_for_device(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
status = spi_sync_locked(spi, &host->m);
if (status != 0) {
dev_dbg(&spi->dev, "write error (%d)\n", status);
return status;
}
if (host->dma_dev)
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
/*
* Get the transmission data-response reply. It must follow
* immediately after the data block we transferred. This reply
* doesn't necessarily tell whether the write operation succeeded;
* it just says if the transmission was ok and whether *earlier*
* writes succeeded; see the standard.
*
* In practice, there are (even modern SDHC-)cards which are late
* in sending the response, and miss the time frame by a few bits,
* so we have to cope with this situation and check the response
* bit-by-bit. Arggh!!!
*/
pattern = get_unaligned_be32(scratch->status);
/* First 3 bit of pattern are undefined */
pattern |= 0xE0000000;
/* left-adjust to leading 0 bit */
while (pattern & 0x80000000)
pattern <<= 1;
/* right-adjust for pattern matching. Code is in bit 4..0 now. */
pattern >>= 27;
switch (pattern) {
case SPI_RESPONSE_ACCEPTED:
status = 0;
break;
case SPI_RESPONSE_CRC_ERR:
/* host shall then issue MMC_STOP_TRANSMISSION */
status = -EILSEQ;
break;
case SPI_RESPONSE_WRITE_ERR:
/* host shall then issue MMC_STOP_TRANSMISSION,
* and should MMC_SEND_STATUS to sort it out
*/
status = -EIO;
break;
default:
status = -EPROTO;
break;
}
if (status != 0) {
dev_dbg(&spi->dev, "write error %02x (%d)\n",
scratch->status[0], status);
return status;
}
t->tx_buf += t->len;
if (host->dma_dev)
t->tx_dma += t->len;
/* Return when not busy. If we didn't collect that status yet,
* we'll need some more I/O.
*/
for (i = 4; i < sizeof(scratch->status); i++) {
/* card is non-busy if the most recent bit is 1 */
if (scratch->status[i] & 0x01)
return 0;
}
return mmc_spi_wait_unbusy(host, timeout);
}
/*
* Read one block:
* - skip leading all-ones bytes ... either
* + N(AC) [1..f(clock,CSD)] usually, else
* + N(CX) [0..8] when reading CSD or CID
* - data block
* + token ... if error token, no data or crc
* + data bytes
* + crc16
*
* After single block reads, we're done; N(EC) [0+] all-ones bytes follow
* before dropping chipselect.
*
* For multiblock reads, caller either reads the next block or issues a
* STOP_TRANSMISSION command.
*/
static int
mmc_spi_readblock(struct mmc_spi_host *host, struct spi_transfer *t,
unsigned long timeout)
{
struct spi_device *spi = host->spi;
int status;
struct scratch *scratch = host->data;
unsigned int bitshift;
u8 leftover;
/* At least one SD card sends an all-zeroes byte when N(CX)
* applies, before the all-ones bytes ... just cope with that.
*/
status = mmc_spi_readbytes(host, 1);
if (status < 0)
return status;
status = scratch->status[0];
if (status == 0xff || status == 0)
status = mmc_spi_readtoken(host, timeout);
if (status < 0) {
dev_dbg(&spi->dev, "read error %02x (%d)\n", status, status);
return status;
}
/* The token may be bit-shifted...
* the first 0-bit precedes the data stream.
*/
bitshift = 7;
while (status & 0x80) {
status <<= 1;
bitshift--;
}
leftover = status << 1;
if (host->dma_dev) {
dma_sync_single_for_device(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
dma_sync_single_for_device(host->dma_dev,
t->rx_dma, t->len,
DMA_FROM_DEVICE);
}
status = spi_sync_locked(spi, &host->m);
if (host->dma_dev) {
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
dma_sync_single_for_cpu(host->dma_dev,
t->rx_dma, t->len,
DMA_FROM_DEVICE);
}
if (bitshift) {
/* Walk through the data and the crc and do
* all the magic to get byte-aligned data.
*/
u8 *cp = t->rx_buf;
unsigned int len;
unsigned int bitright = 8 - bitshift;
u8 temp;
for (len = t->len; len; len--) {
temp = *cp;
*cp++ = leftover | (temp >> bitshift);
leftover = temp << bitright;
}
cp = (u8 *) &scratch->crc_val;
temp = *cp;
*cp++ = leftover | (temp >> bitshift);
leftover = temp << bitright;
temp = *cp;
*cp = leftover | (temp >> bitshift);
}
if (host->mmc->use_spi_crc) {
u16 crc = crc_itu_t(0, t->rx_buf, t->len);
be16_to_cpus(&scratch->crc_val);
if (scratch->crc_val != crc) {
dev_dbg(&spi->dev, "read - crc error: crc_val=0x%04x, "
"computed=0x%04x len=%d\n",
scratch->crc_val, crc, t->len);
return -EILSEQ;
}
}
t->rx_buf += t->len;
if (host->dma_dev)
t->rx_dma += t->len;
return 0;
}
/*
* An MMC/SD data stage includes one or more blocks, optional CRCs,
* and inline handshaking. That handhaking makes it unlike most
* other SPI protocol stacks.
*/
static void
mmc_spi_data_do(struct mmc_spi_host *host, struct mmc_command *cmd,
struct mmc_data *data, u32 blk_size)
{
struct spi_device *spi = host->spi;
struct device *dma_dev = host->dma_dev;
struct spi_transfer *t;
enum dma_data_direction direction;
struct scatterlist *sg;
unsigned n_sg;
int multiple = (data->blocks > 1);
u32 clock_rate;
unsigned long timeout;
if (data->flags & MMC_DATA_READ)
direction = DMA_FROM_DEVICE;
else
direction = DMA_TO_DEVICE;
mmc_spi_setup_data_message(host, multiple, direction);
t = &host->t;
if (t->speed_hz)
clock_rate = t->speed_hz;
else
clock_rate = spi->max_speed_hz;
timeout = data->timeout_ns +
data->timeout_clks * 1000000 / clock_rate;
timeout = usecs_to_jiffies((unsigned int)(timeout / 1000)) + 1;
/* Handle scatterlist segments one at a time, with synch for
* each 512-byte block
*/
for (sg = data->sg, n_sg = data->sg_len; n_sg; n_sg--, sg++) {
int status = 0;
dma_addr_t dma_addr = 0;
void *kmap_addr;
unsigned length = sg->length;
enum dma_data_direction dir = direction;
/* set up dma mapping for controller drivers that might
* use DMA ... though they may fall back to PIO
*/
if (dma_dev) {
/* never invalidate whole *shared* pages ... */
if ((sg->offset != 0 || length != PAGE_SIZE)
&& dir == DMA_FROM_DEVICE)
dir = DMA_BIDIRECTIONAL;
dma_addr = dma_map_page(dma_dev, sg_page(sg), 0,
PAGE_SIZE, dir);
if (direction == DMA_TO_DEVICE)
t->tx_dma = dma_addr + sg->offset;
else
t->rx_dma = dma_addr + sg->offset;
}
/* allow pio too; we don't allow highmem */
kmap_addr = kmap(sg_page(sg));
if (direction == DMA_TO_DEVICE)
t->tx_buf = kmap_addr + sg->offset;
else
t->rx_buf = kmap_addr + sg->offset;
/* transfer each block, and update request status */
while (length) {
t->len = min(length, blk_size);
dev_dbg(&host->spi->dev,
" mmc_spi: %s block, %d bytes\n",
(direction == DMA_TO_DEVICE)
? "write"
: "read",
t->len);
if (direction == DMA_TO_DEVICE)
status = mmc_spi_writeblock(host, t, timeout);
else
status = mmc_spi_readblock(host, t, timeout);
if (status < 0)
break;
data->bytes_xfered += t->len;
length -= t->len;
if (!multiple)
break;
}
/* discard mappings */
if (direction == DMA_FROM_DEVICE)
flush_kernel_dcache_page(sg_page(sg));
kunmap(sg_page(sg));
if (dma_dev)
dma_unmap_page(dma_dev, dma_addr, PAGE_SIZE, dir);
if (status < 0) {
data->error = status;
dev_dbg(&spi->dev, "%s status %d\n",
(direction == DMA_TO_DEVICE)
? "write" : "read",
status);
break;
}
}
/* NOTE some docs describe an MMC-only SET_BLOCK_COUNT (CMD23) that
* can be issued before multiblock writes. Unlike its more widely
* documented analogue for SD cards (SET_WR_BLK_ERASE_COUNT, ACMD23),
* that can affect the STOP_TRAN logic. Complete (and current)
* MMC specs should sort that out before Linux starts using CMD23.
*/
if (direction == DMA_TO_DEVICE && multiple) {
struct scratch *scratch = host->data;
int tmp;
const unsigned statlen = sizeof(scratch->status);
dev_dbg(&spi->dev, " mmc_spi: STOP_TRAN\n");
/* Tweak the per-block message we set up earlier by morphing
* it to hold single buffer with the token followed by some
* all-ones bytes ... skip N(BR) (0..1), scan the rest for
* "not busy any longer" status, and leave chip selected.
*/
INIT_LIST_HEAD(&host->m.transfers);
list_add(&host->early_status.transfer_list,
&host->m.transfers);
memset(scratch->status, 0xff, statlen);
scratch->status[0] = SPI_TOKEN_STOP_TRAN;
host->early_status.tx_buf = host->early_status.rx_buf;
host->early_status.tx_dma = host->early_status.rx_dma;
host->early_status.len = statlen;
if (host->dma_dev)
dma_sync_single_for_device(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
tmp = spi_sync_locked(spi, &host->m);
if (host->dma_dev)
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*scratch),
DMA_BIDIRECTIONAL);
if (tmp < 0) {
if (!data->error)
data->error = tmp;
return;
}
/* Ideally we collected "not busy" status with one I/O,
* avoiding wasteful byte-at-a-time scanning... but more
* I/O is often needed.
*/
for (tmp = 2; tmp < statlen; tmp++) {
if (scratch->status[tmp] != 0)
return;
}
tmp = mmc_spi_wait_unbusy(host, timeout);
if (tmp < 0 && !data->error)
data->error = tmp;
}
}
/****************************************************************************/
/*
* MMC driver implementation -- the interface to the MMC stack
*/
static void mmc_spi_request(struct mmc_host *mmc, struct mmc_request *mrq)
{
struct mmc_spi_host *host = mmc_priv(mmc);
int status = -EINVAL;
int crc_retry = 5;
struct mmc_command stop;
#ifdef DEBUG
/* MMC core and layered drivers *MUST* issue SPI-aware commands */
{
struct mmc_command *cmd;
int invalid = 0;
cmd = mrq->cmd;
if (!mmc_spi_resp_type(cmd)) {
dev_dbg(&host->spi->dev, "bogus command\n");
cmd->error = -EINVAL;
invalid = 1;
}
cmd = mrq->stop;
if (cmd && !mmc_spi_resp_type(cmd)) {
dev_dbg(&host->spi->dev, "bogus STOP command\n");
cmd->error = -EINVAL;
invalid = 1;
}
if (invalid) {
dump_stack();
mmc_request_done(host->mmc, mrq);
return;
}
}
#endif
/* request exclusive bus access */
spi_bus_lock(host->spi->master);
crc_recover:
/* issue command; then optionally data and stop */
status = mmc_spi_command_send(host, mrq, mrq->cmd, mrq->data != NULL);
if (status == 0 && mrq->data) {
mmc_spi_data_do(host, mrq->cmd, mrq->data, mrq->data->blksz);
/*
* The SPI bus is not always reliable for large data transfers.
* If an occasional crc error is reported by the SD device with
* data read/write over SPI, it may be recovered by repeating
* the last SD command again. The retry count is set to 5 to
* ensure the driver passes stress tests.
*/
if (mrq->data->error == -EILSEQ && crc_retry) {
stop.opcode = MMC_STOP_TRANSMISSION;
stop.arg = 0;
stop.flags = MMC_RSP_SPI_R1B | MMC_RSP_R1B | MMC_CMD_AC;
status = mmc_spi_command_send(host, mrq, &stop, 0);
crc_retry--;
mrq->data->error = 0;
goto crc_recover;
}
if (mrq->stop)
status = mmc_spi_command_send(host, mrq, mrq->stop, 0);
else
mmc_cs_off(host);
}
/* release the bus */
spi_bus_unlock(host->spi->master);
mmc_request_done(host->mmc, mrq);
}
/* See Section 6.4.1, in SD "Simplified Physical Layer Specification 2.0"
*
* NOTE that here we can't know that the card has just been powered up;
* not all MMC/SD sockets support power switching.
*
* FIXME when the card is still in SPI mode, e.g. from a previous kernel,
* this doesn't seem to do the right thing at all...
*/
static void mmc_spi_initsequence(struct mmc_spi_host *host)
{
/* Try to be very sure any previous command has completed;
* wait till not-busy, skip debris from any old commands.
*/
mmc_spi_wait_unbusy(host, r1b_timeout);
mmc_spi_readbytes(host, 10);
/*
* Do a burst with chipselect active-high. We need to do this to
* meet the requirement of 74 clock cycles with both chipselect
* and CMD (MOSI) high before CMD0 ... after the card has been
* powered up to Vdd(min), and so is ready to take commands.
*
* Some cards are particularly needy of this (e.g. Viking "SD256")
* while most others don't seem to care.
*
* Note that this is one of the places MMC/SD plays games with the
* SPI protocol. Another is that when chipselect is released while
* the card returns BUSY status, the clock must issue several cycles
* with chipselect high before the card will stop driving its output.
*/
host->spi->mode |= SPI_CS_HIGH;
if (spi_setup(host->spi) != 0) {
/* Just warn; most cards work without it. */
dev_warn(&host->spi->dev,
"can't change chip-select polarity\n");
host->spi->mode &= ~SPI_CS_HIGH;
} else {
mmc_spi_readbytes(host, 18);
host->spi->mode &= ~SPI_CS_HIGH;
if (spi_setup(host->spi) != 0) {
/* Wot, we can't get the same setup we had before? */
dev_err(&host->spi->dev,
"can't restore chip-select polarity\n");
}
}
}
static char *mmc_powerstring(u8 power_mode)
{
switch (power_mode) {
case MMC_POWER_OFF: return "off";
case MMC_POWER_UP: return "up";
case MMC_POWER_ON: return "on";
}
return "?";
}
static void mmc_spi_set_ios(struct mmc_host *mmc, struct mmc_ios *ios)
{
struct mmc_spi_host *host = mmc_priv(mmc);
if (host->power_mode != ios->power_mode) {
int canpower;
canpower = host->pdata && host->pdata->setpower;
dev_dbg(&host->spi->dev, "mmc_spi: power %s (%d)%s\n",
mmc_powerstring(ios->power_mode),
ios->vdd,
canpower ? ", can switch" : "");
/* switch power on/off if possible, accounting for
* max 250msec powerup time if needed.
*/
if (canpower) {
switch (ios->power_mode) {
case MMC_POWER_OFF:
case MMC_POWER_UP:
host->pdata->setpower(&host->spi->dev,
ios->vdd);
if (ios->power_mode == MMC_POWER_UP)
msleep(host->powerup_msecs);
}
}
/* See 6.4.1 in the simplified SD card physical spec 2.0 */
if (ios->power_mode == MMC_POWER_ON)
mmc_spi_initsequence(host);
/* If powering down, ground all card inputs to avoid power
* delivery from data lines! On a shared SPI bus, this
* will probably be temporary; 6.4.2 of the simplified SD
* spec says this must last at least 1msec.
*
* - Clock low means CPOL 0, e.g. mode 0
* - MOSI low comes from writing zero
* - Chipselect is usually active low...
*/
if (canpower && ios->power_mode == MMC_POWER_OFF) {
int mres;
u8 nullbyte = 0;
host->spi->mode &= ~(SPI_CPOL|SPI_CPHA);
mres = spi_setup(host->spi);
if (mres < 0)
dev_dbg(&host->spi->dev,
"switch to SPI mode 0 failed\n");
if (spi_write(host->spi, &nullbyte, 1) < 0)
dev_dbg(&host->spi->dev,
"put spi signals to low failed\n");
/*
* Now clock should be low due to spi mode 0;
* MOSI should be low because of written 0x00;
* chipselect should be low (it is active low)
* power supply is off, so now MMC is off too!
*
* FIXME no, chipselect can be high since the
* device is inactive and SPI_CS_HIGH is clear...
*/
msleep(10);
if (mres == 0) {
host->spi->mode |= (SPI_CPOL|SPI_CPHA);
mres = spi_setup(host->spi);
if (mres < 0)
dev_dbg(&host->spi->dev,
"switch back to SPI mode 3"
" failed\n");
}
}
host->power_mode = ios->power_mode;
}
if (host->spi->max_speed_hz != ios->clock && ios->clock != 0) {
int status;
host->spi->max_speed_hz = ios->clock;
status = spi_setup(host->spi);
dev_dbg(&host->spi->dev,
"mmc_spi: clock to %d Hz, %d\n",
host->spi->max_speed_hz, status);
}
}
static const struct mmc_host_ops mmc_spi_ops = {
.request = mmc_spi_request,
.set_ios = mmc_spi_set_ios,
.get_ro = mmc_gpio_get_ro,
.get_cd = mmc_gpio_get_cd,
};
/****************************************************************************/
/*
* SPI driver implementation
*/
static irqreturn_t
mmc_spi_detect_irq(int irq, void *mmc)
{
struct mmc_spi_host *host = mmc_priv(mmc);
u16 delay_msec = max(host->pdata->detect_delay, (u16)100);
mmc_detect_change(mmc, msecs_to_jiffies(delay_msec));
return IRQ_HANDLED;
}
static int mmc_spi_probe(struct spi_device *spi)
{
void *ones;
struct mmc_host *mmc;
struct mmc_spi_host *host;
int status;
bool has_ro = false;
/* We rely on full duplex transfers, mostly to reduce
* per-transfer overheads (by making fewer transfers).
*/
if (spi->master->flags & SPI_MASTER_HALF_DUPLEX)
return -EINVAL;
/* MMC and SD specs only seem to care that sampling is on the
* rising edge ... meaning SPI modes 0 or 3. So either SPI mode
* should be legit. We'll use mode 0 since the steady state is 0,
* which is appropriate for hotplugging, unless the platform data
* specify mode 3 (if hardware is not compatible to mode 0).
*/
if (spi->mode != SPI_MODE_3)
spi->mode = SPI_MODE_0;
spi->bits_per_word = 8;
status = spi_setup(spi);
if (status < 0) {
dev_dbg(&spi->dev, "needs SPI mode %02x, %d KHz; %d\n",
spi->mode, spi->max_speed_hz / 1000,
status);
return status;
}
/* We need a supply of ones to transmit. This is the only time
* the CPU touches these, so cache coherency isn't a concern.
*
* NOTE if many systems use more than one MMC-over-SPI connector
* it'd save some memory to share this. That's evidently rare.
*/
status = -ENOMEM;
ones = kmalloc(MMC_SPI_BLOCKSIZE, GFP_KERNEL);
if (!ones)
goto nomem;
memset(ones, 0xff, MMC_SPI_BLOCKSIZE);
mmc = mmc_alloc_host(sizeof(*host), &spi->dev);
if (!mmc)
goto nomem;
mmc->ops = &mmc_spi_ops;
mmc->max_blk_size = MMC_SPI_BLOCKSIZE;
mmc->max_segs = MMC_SPI_BLOCKSATONCE;
mmc->max_req_size = MMC_SPI_BLOCKSATONCE * MMC_SPI_BLOCKSIZE;
mmc->max_blk_count = MMC_SPI_BLOCKSATONCE;
mmc->caps = MMC_CAP_SPI;
/* SPI doesn't need the lowspeed device identification thing for
* MMC or SD cards, since it never comes up in open drain mode.
* That's good; some SPI masters can't handle very low speeds!
*
* However, low speed SDIO cards need not handle over 400 KHz;
* that's the only reason not to use a few MHz for f_min (until
* the upper layer reads the target frequency from the CSD).
*/
mmc->f_min = 400000;
mmc->f_max = spi->max_speed_hz;
host = mmc_priv(mmc);
host->mmc = mmc;
host->spi = spi;
host->ones = ones;
/* Platform data is used to hook up things like card sensing
* and power switching gpios.
*/
host->pdata = mmc_spi_get_pdata(spi);
if (host->pdata)
mmc->ocr_avail = host->pdata->ocr_mask;
if (!mmc->ocr_avail) {
dev_warn(&spi->dev, "ASSUMING 3.2-3.4 V slot power\n");
mmc->ocr_avail = MMC_VDD_32_33|MMC_VDD_33_34;
}
if (host->pdata && host->pdata->setpower) {
host->powerup_msecs = host->pdata->powerup_msecs;
if (!host->powerup_msecs || host->powerup_msecs > 250)
host->powerup_msecs = 250;
}
dev_set_drvdata(&spi->dev, mmc);
/* preallocate dma buffers */
host->data = kmalloc(sizeof(*host->data), GFP_KERNEL);
if (!host->data)
goto fail_nobuf1;
if (spi->master->dev.parent->dma_mask) {
struct device *dev = spi->master->dev.parent;
host->dma_dev = dev;
host->ones_dma = dma_map_single(dev, ones,
MMC_SPI_BLOCKSIZE, DMA_TO_DEVICE);
host->data_dma = dma_map_single(dev, host->data,
sizeof(*host->data), DMA_BIDIRECTIONAL);
/* REVISIT in theory those map operations can fail... */
dma_sync_single_for_cpu(host->dma_dev,
host->data_dma, sizeof(*host->data),
DMA_BIDIRECTIONAL);
}
/* setup message for status/busy readback */
spi_message_init(&host->readback);
host->readback.is_dma_mapped = (host->dma_dev != NULL);
spi_message_add_tail(&host->status, &host->readback);
host->status.tx_buf = host->ones;
host->status.tx_dma = host->ones_dma;
host->status.rx_buf = &host->data->status;
host->status.rx_dma = host->data_dma + offsetof(struct scratch, status);
host->status.cs_change = 1;
/* register card detect irq */
if (host->pdata && host->pdata->init) {
status = host->pdata->init(&spi->dev, mmc_spi_detect_irq, mmc);
if (status != 0)
goto fail_glue_init;
}
/* pass platform capabilities, if any */
if (host->pdata) {
mmc->caps |= host->pdata->caps;
mmc->caps2 |= host->pdata->caps2;
}
status = mmc_add_host(mmc);
if (status != 0)
goto fail_add_host;
if (host->pdata && host->pdata->flags & MMC_SPI_USE_CD_GPIO) {
status = mmc_gpio_request_cd(mmc, host->pdata->cd_gpio,
host->pdata->cd_debounce);
if (status != 0)
goto fail_add_host;
}
if (host->pdata && host->pdata->flags & MMC_SPI_USE_RO_GPIO) {
has_ro = true;
status = mmc_gpio_request_ro(mmc, host->pdata->ro_gpio);
if (status != 0)
goto fail_add_host;
}
dev_info(&spi->dev, "SD/MMC host %s%s%s%s%s\n",
dev_name(&mmc->class_dev),
host->dma_dev ? "" : ", no DMA",
has_ro ? "" : ", no WP",
(host->pdata && host->pdata->setpower)
? "" : ", no poweroff",
(mmc->caps & MMC_CAP_NEEDS_POLL)
? ", cd polling" : "");
return 0;
fail_add_host:
mmc_remove_host (mmc);
fail_glue_init:
if (host->dma_dev)
dma_unmap_single(host->dma_dev, host->data_dma,
sizeof(*host->data), DMA_BIDIRECTIONAL);
kfree(host->data);
fail_nobuf1:
mmc_free_host(mmc);
mmc_spi_put_pdata(spi);
dev_set_drvdata(&spi->dev, NULL);
nomem:
kfree(ones);
return status;
}
static int mmc_spi_remove(struct spi_device *spi)
{
struct mmc_host *mmc = dev_get_drvdata(&spi->dev);
struct mmc_spi_host *host;
if (mmc) {
host = mmc_priv(mmc);
/* prevent new mmc_detect_change() calls */
if (host->pdata && host->pdata->exit)
host->pdata->exit(&spi->dev, mmc);
mmc_remove_host(mmc);
if (host->dma_dev) {
dma_unmap_single(host->dma_dev, host->ones_dma,
MMC_SPI_BLOCKSIZE, DMA_TO_DEVICE);
dma_unmap_single(host->dma_dev, host->data_dma,
sizeof(*host->data), DMA_BIDIRECTIONAL);
}
kfree(host->data);
kfree(host->ones);
spi->max_speed_hz = mmc->f_max;
mmc_free_host(mmc);
mmc_spi_put_pdata(spi);
dev_set_drvdata(&spi->dev, NULL);
}
return 0;
}
static struct of_device_id mmc_spi_of_match_table[] = {
{ .compatible = "mmc-spi-slot", },
{},
};
static struct spi_driver mmc_spi_driver = {
.driver = {
.name = "mmc_spi",
.owner = THIS_MODULE,
.of_match_table = mmc_spi_of_match_table,
},
.probe = mmc_spi_probe,
.remove = mmc_spi_remove,
};
module_spi_driver(mmc_spi_driver);
MODULE_AUTHOR("Mike Lavender, David Brownell, "
"Hans-Peter Nilsson, Jan Nikitenko");
MODULE_DESCRIPTION("SPI SD/MMC host driver");
MODULE_LICENSE("GPL");
MODULE_ALIAS("spi:mmc_spi");