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|
/* $OpenBSD: octmmc.c,v 1.8 2017/09/23 04:56:42 visa Exp $ */
/*
* Copyright (c) 2016, 2017 Visa Hankala
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
/* Driver for OCTEON MMC host controller. */
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/device.h>
#include <sys/endian.h>
#include <sys/malloc.h>
#include <sys/rwlock.h>
#include <sys/kernel.h>
#include <dev/ofw/fdt.h>
#include <dev/ofw/openfirm.h>
#include <dev/sdmmc/sdmmcchip.h>
#include <dev/sdmmc/sdmmcvar.h>
#include <dev/sdmmc/sdmmc_ioreg.h>
#include <mips64/cache.h>
#include <machine/bus.h>
#include <machine/fdt.h>
#include <machine/octeonreg.h>
#include <machine/octeonvar.h>
#include <machine/octeon_model.h>
#include <octeon/dev/octmmcreg.h>
#define OCTMMC_BLOCK_SIZE 512
#define OCTMMC_CMD_TIMEOUT 5 /* in seconds */
#define OCTMMC_MAX_DMASEG MIN(MAXPHYS, (1u << 18))
#define OCTMMC_MAX_FREQ 52000 /* in kHz */
#define OCTMMC_MAX_BUSES 4
#define OCTMMC_MAX_INTRS 4
#define DEF_STS_MASK 0xe4390080ul
#define PIO_STS_MASK 0x00b00000ul
#define MMC_RD_8(sc, reg) \
bus_space_read_8((sc)->sc_iot, (sc)->sc_mmc_ioh, (reg))
#define MMC_WR_8(sc, reg, val) \
bus_space_write_8((sc)->sc_iot, (sc)->sc_mmc_ioh, (reg), (val))
#define DMA_WR_8(sc, reg, val) \
bus_space_write_8((sc)->sc_iot, (sc)->sc_dma_ioh, (reg), (val))
#define divround(n, d) (((n) + (d) / 2) / (d))
struct octmmc_softc;
struct octmmc_bus {
struct octmmc_softc *bus_hc;
struct device *bus_sdmmc;
uint32_t bus_id;
uint32_t bus_cmd_skew;
uint32_t bus_dat_skew;
uint32_t bus_max_freq; /* in kHz */
uint64_t bus_switch;
uint64_t bus_rca;
uint64_t bus_wdog;
};
struct octmmc_softc {
struct device sc_dev;
bus_space_tag_t sc_iot;
bus_space_handle_t sc_mmc_ioh;
bus_space_handle_t sc_dma_ioh;
bus_dma_tag_t sc_dmat;
bus_dmamap_t sc_dma_data;
caddr_t sc_bounce_buf;
bus_dma_segment_t sc_bounce_seg;
void *sc_ihs[OCTMMC_MAX_INTRS];
int sc_nihs;
struct octmmc_bus sc_buses[OCTMMC_MAX_BUSES];
struct octmmc_bus *sc_current_bus;
uint64_t sc_current_switch;
uint64_t sc_intr_status;
int sc_hwrev;
#define OCTMMC_HWREV_6130 0
#define OCTMMC_HWREV_7890 1
};
int octmmc_match(struct device *, void *, void *);
void octmmc_attach(struct device *, struct device *, void *);
int octmmc_host_reset(sdmmc_chipset_handle_t);
uint32_t octmmc_host_ocr(sdmmc_chipset_handle_t);
int octmmc_host_maxblklen(sdmmc_chipset_handle_t);
int octmmc_card_detect(sdmmc_chipset_handle_t);
int octmmc_bus_width(sdmmc_chipset_handle_t, int);
int octmmc_bus_power(sdmmc_chipset_handle_t, uint32_t);
int octmmc_bus_clock(sdmmc_chipset_handle_t, int, int);
void octmmc_exec_command(sdmmc_chipset_handle_t, struct sdmmc_command *);
void octmmc_exec_dma(struct octmmc_bus *, struct sdmmc_command *);
void octmmc_exec_pio(struct octmmc_bus *, struct sdmmc_command *);
void octmmc_acquire(struct octmmc_bus *);
void octmmc_release(struct octmmc_bus *);
uint64_t octmmc_crtype_fixup(struct sdmmc_command *);
void octmmc_get_response(struct octmmc_softc *, struct sdmmc_command *);
int octmmc_init_bus(struct octmmc_bus *);
int octmmc_intr(void *);
int octmmc_wait_intr(struct octmmc_softc *, uint64_t, int);
const struct cfattach octmmc_ca = {
sizeof(struct octmmc_softc), octmmc_match, octmmc_attach
};
struct cfdriver octmmc_cd = {
NULL, "octmmc", DV_DULL
};
struct sdmmc_chip_functions octmmc_funcs = {
.host_reset = octmmc_host_reset,
.host_ocr = octmmc_host_ocr,
.host_maxblklen = octmmc_host_maxblklen,
.card_detect = octmmc_card_detect,
.bus_power = octmmc_bus_power,
.bus_clock = octmmc_bus_clock,
.bus_width = octmmc_bus_width,
.exec_command = octmmc_exec_command,
};
static const int octmmc_6130_interrupts[] = { 0, 1, -1 };
static const int octmmc_7890_interrupts[] = { 1, 2, 3, 4, -1 };
struct rwlock octmmc_lock = RWLOCK_INITIALIZER("octmmclk");
int
octmmc_match(struct device *parent, void *match, void *aux)
{
struct fdt_attach_args *fa = aux;
return OF_is_compatible(fa->fa_node, "cavium,octeon-6130-mmc") ||
OF_is_compatible(fa->fa_node, "cavium,octeon-7890-mmc");
}
void
octmmc_attach(struct device *parent, struct device *self, void *aux)
{
struct sdmmcbus_attach_args saa;
struct fdt_attach_args *fa = aux;
struct octmmc_softc *sc = (struct octmmc_softc *)self;
struct octmmc_bus *bus;
void *ih;
const int *interrupts;
uint64_t reg;
uint32_t bus_id, bus_width;
int i, node, rsegs;
if (OF_is_compatible(fa->fa_node, "cavium,octeon-7890-mmc")) {
sc->sc_hwrev = OCTMMC_HWREV_7890;
interrupts = octmmc_7890_interrupts;
} else {
sc->sc_hwrev = OCTMMC_HWREV_6130;
interrupts = octmmc_6130_interrupts;
}
if (fa->fa_nreg < 2) {
printf(": expected 2 IO spaces, got %d\n", fa->fa_nreg);
return;
}
sc->sc_iot = fa->fa_iot;
sc->sc_dmat = fa->fa_dmat;
if (bus_space_map(sc->sc_iot, fa->fa_reg[0].addr, fa->fa_reg[0].size, 0,
&sc->sc_mmc_ioh)) {
printf(": could not map MMC registers\n");
goto error;
}
if (bus_space_map(sc->sc_iot, fa->fa_reg[1].addr, fa->fa_reg[1].size, 0,
&sc->sc_dma_ioh)) {
printf(": could not map DMA registers\n");
goto error;
}
if (bus_dmamem_alloc(sc->sc_dmat, OCTMMC_MAX_DMASEG, 0, 0,
&sc->sc_bounce_seg, 1, &rsegs, BUS_DMA_NOWAIT)) {
printf(": could not allocate bounce buffer\n");
goto error;
}
if (bus_dmamem_map(sc->sc_dmat, &sc->sc_bounce_seg, rsegs,
OCTMMC_MAX_DMASEG, &sc->sc_bounce_buf,
BUS_DMA_NOWAIT | BUS_DMA_COHERENT)) {
printf(": could not map bounce buffer\n");
goto error_free;
}
if (bus_dmamap_create(sc->sc_dmat, OCTMMC_MAX_DMASEG, 1,
OCTMMC_MAX_DMASEG, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW,
&sc->sc_dma_data)) {
printf(": could not create data dmamap\n");
goto error_unmap;
}
/* Disable all buses. */
reg = MMC_RD_8(sc, MIO_EMM_CFG);
reg &= ~((1u << OCTMMC_MAX_BUSES) - 1);
MMC_WR_8(sc, MIO_EMM_CFG, reg);
/* Clear any pending interrupts. */
reg = MMC_RD_8(sc, MIO_EMM_INT);
MMC_WR_8(sc, MIO_EMM_INT, reg);
for (i = 0; interrupts[i] != -1; i++) {
KASSERT(i < OCTMMC_MAX_INTRS);
ih = octeon_intr_establish_fdt_idx(fa->fa_node, interrupts[i],
IPL_SDMMC, octmmc_intr, sc, DEVNAME(sc));
if (ih == NULL) {
printf(": could not establish interrupt %d\n", i);
goto error_intr;
}
sc->sc_ihs[i] = ih;
sc->sc_nihs++;
}
printf("\n");
sc->sc_current_bus = NULL;
sc->sc_current_switch = ~0ull;
for (node = OF_child(fa->fa_node); node != 0; node = OF_peer(node)) {
if (!OF_is_compatible(node, "cavium,octeon-6130-mmc-slot"))
continue;
bus_id = OF_getpropint(node, "reg", (uint32_t)-1);
if (bus_id >= OCTMMC_MAX_BUSES)
continue;
bus = &sc->sc_buses[bus_id];
bus->bus_hc = sc;
bus->bus_id = bus_id;
bus->bus_cmd_skew = OF_getpropint(node,
"cavium,cmd-clk-skew", 0);
bus->bus_dat_skew = OF_getpropint(node,
"cavium,dat-clk-skew", 0);
bus->bus_max_freq = OF_getpropint(node,
"spi-max-frequency", 0) / 1000;
if (bus->bus_max_freq == 0 ||
bus->bus_max_freq > OCTMMC_MAX_FREQ)
bus->bus_max_freq = OCTMMC_MAX_FREQ;
bus_width = OF_getpropint(node, "bus-width", 0);
if (bus_width == 0)
bus_width = OF_getpropint(node,
"cavium,bus-max-width", 8);
if (octmmc_init_bus(bus)) {
printf("%s: could not init bus %d\n", DEVNAME(sc),
bus_id);
continue;
}
memset(&saa, 0, sizeof(saa));
saa.saa_busname = "sdmmc";
saa.sct = &octmmc_funcs;
saa.sch = bus;
saa.caps = SMC_CAPS_MMC_HIGHSPEED;
if (bus_width >= 8)
saa.caps |= SMC_CAPS_8BIT_MODE;
if (bus_width >= 4)
saa.caps |= SMC_CAPS_4BIT_MODE;
bus->bus_sdmmc = config_found(&sc->sc_dev, &saa, NULL);
if (bus->bus_sdmmc == NULL)
printf("%s: bus %d: could not attach sdmmc\n",
DEVNAME(sc), bus_id);
}
return;
error_intr:
for (i = 0; i < sc->sc_nihs; i++)
octeon_intr_disestablish_fdt(sc->sc_ihs[i]);
error_unmap:
bus_dmamem_unmap(sc->sc_dmat, sc->sc_bounce_buf, OCTMMC_MAX_DMASEG);
error_free:
bus_dmamem_free(sc->sc_dmat, &sc->sc_bounce_seg, rsegs);
error:
if (sc->sc_dma_data != NULL)
bus_dmamap_destroy(sc->sc_dmat, sc->sc_dma_data);
if (sc->sc_dma_ioh != 0)
bus_space_unmap(sc->sc_iot, sc->sc_dma_ioh, fa->fa_reg[1].size);
if (sc->sc_mmc_ioh != 0)
bus_space_unmap(sc->sc_iot, sc->sc_mmc_ioh, fa->fa_reg[0].size);
}
void
octmmc_acquire(struct octmmc_bus *bus)
{
struct octmmc_softc *sc = bus->bus_hc;
uint64_t period, sample;
splassert(IPL_SDMMC);
rw_enter_write(&octmmc_lock);
/* Acquire the bootbus. */
octeon_xkphys_write_8(MIO_BOOT_CFG, 0);
if (sc->sc_current_bus == bus &&
sc->sc_current_switch == bus->bus_switch)
return;
/* Save relative card address. */
if (sc->sc_current_bus != NULL)
sc->sc_current_bus->bus_rca = MMC_RD_8(sc, MIO_EMM_RCA);
sc->sc_current_bus = NULL;
sc->sc_current_switch = ~0ull;
/* Set bus parameters. */
MMC_WR_8(sc, MIO_EMM_SWITCH, bus->bus_switch &
~MIO_EMM_SWITCH_BUS_ID);
MMC_WR_8(sc, MIO_EMM_SWITCH, bus->bus_switch);
/* Set relative card address. */
MMC_WR_8(sc, MIO_EMM_RCA, bus->bus_rca);
/* Set command timeout. */
MMC_WR_8(sc, MIO_EMM_WDOG, bus->bus_wdog);
/* Set sampling skew parameters. */
period = 1000000000000ull / octeon_ioclock_speed();
sample = (divround(bus->bus_cmd_skew, period) <<
MIO_EMM_SAMPLE_CMD_CNT_SHIFT) &
MIO_EMM_SAMPLE_CMD_CNT;
sample |= (divround(bus->bus_dat_skew, period) <<
MIO_EMM_SAMPLE_DAT_CNT_SHIFT) &
MIO_EMM_SAMPLE_DAT_CNT;
MMC_WR_8(bus->bus_hc, MIO_EMM_SAMPLE, sample);
sc->sc_current_bus = bus;
sc->sc_current_switch = bus->bus_switch;
return;
}
void
octmmc_release(struct octmmc_bus *bus)
{
rw_exit_write(&octmmc_lock);
}
int
octmmc_init_bus(struct octmmc_bus *bus)
{
struct octmmc_softc *sc = bus->bus_hc;
uint64_t init_freq = SDMMC_SDCLK_400KHZ;
uint64_t period;
uint64_t reg;
int s;
period = divround(octeon_ioclock_speed(), init_freq * 1000 * 2);
if (period > MIO_EMM_SWITCH_CLK_MAX)
period = MIO_EMM_SWITCH_CLK_MAX;
/* Set initial parameters. */
bus->bus_switch = (uint64_t)bus->bus_id << MIO_EMM_SWITCH_BUS_ID_SHIFT;
bus->bus_switch |= 10ull << MIO_EMM_SWITCH_POWER_CLASS_SHIFT;
bus->bus_switch |= period << MIO_EMM_SWITCH_CLK_HI_SHIFT;
bus->bus_switch |= period << MIO_EMM_SWITCH_CLK_LO_SHIFT;
bus->bus_rca = 1;
/* Make hardware timeout happen before timeout in software. */
bus->bus_wdog = init_freq * 900 * OCTMMC_CMD_TIMEOUT;
if (bus->bus_wdog > MIO_EMM_WDOG_CLK_CNT)
bus->bus_wdog = MIO_EMM_WDOG_CLK_CNT;
s = splsdmmc();
/* Enable the bus. */
reg = MMC_RD_8(sc, MIO_EMM_CFG);
reg |= 1u << bus->bus_id;
MMC_WR_8(sc, MIO_EMM_CFG, reg);
octmmc_acquire(bus);
/*
* Enable interrupts.
*
* The mask register is present only on the revision 6130 controller
* where interrupt causes share an interrupt vector.
* The 7890 controller has a separate vector for each interrupt cause.
*/
if (sc->sc_hwrev == OCTMMC_HWREV_6130) {
MMC_WR_8(sc, MIO_EMM_INT_EN,
MIO_EMM_INT_CMD_ERR | MIO_EMM_INT_CMD_DONE |
MIO_EMM_INT_DMA_ERR | MIO_EMM_INT_DMA_DONE);
}
MMC_WR_8(sc, MIO_EMM_STS_MASK, DEF_STS_MASK);
octmmc_release(bus);
splx(s);
return 0;
}
int
octmmc_intr(void *arg)
{
struct octmmc_softc *sc = arg;
uint64_t isr;
/* Get and acknowledge pending interrupts. */
isr = MMC_RD_8(sc, MIO_EMM_INT);
if (isr == 0)
return 0;
MMC_WR_8(sc, MIO_EMM_INT, isr);
if (ISSET(isr, MIO_EMM_INT_CMD_DONE) ||
ISSET(isr, MIO_EMM_INT_CMD_ERR) ||
ISSET(isr, MIO_EMM_INT_DMA_DONE) ||
ISSET(isr, MIO_EMM_INT_DMA_ERR)) {
sc->sc_intr_status |= isr;
wakeup(&sc->sc_intr_status);
}
return 1;
}
int
octmmc_host_reset(sdmmc_chipset_handle_t sch)
{
struct octmmc_bus *bus = sch;
int s;
/* Force reswitch. */
bus->bus_hc->sc_current_switch = ~0ull;
s = splsdmmc();
octmmc_acquire(bus);
octmmc_release(bus);
splx(s);
return 0;
}
uint32_t
octmmc_host_ocr(sdmmc_chipset_handle_t sch)
{
/* The hardware does only 3.3V. */
return MMC_OCR_3_2V_3_3V | MMC_OCR_3_3V_3_4V;
}
int
octmmc_host_maxblklen(sdmmc_chipset_handle_t sch)
{
return OCTMMC_BLOCK_SIZE;
}
int
octmmc_card_detect(sdmmc_chipset_handle_t sch)
{
return 1;
}
int
octmmc_bus_power(sdmmc_chipset_handle_t sch, uint32_t ocr)
{
if (ocr == 0)
octmmc_host_reset(sch);
return 0;
}
int
octmmc_bus_clock(sdmmc_chipset_handle_t sch, int freq, int timing)
{
struct octmmc_bus *bus = sch;
uint64_t ioclock = octeon_ioclock_speed();
uint64_t period;
if (freq == 0)
return 0;
if (freq > bus->bus_max_freq)
freq = bus->bus_max_freq;
period = divround(ioclock, freq * 1000 * 2);
if (period > MIO_EMM_SWITCH_CLK_MAX)
period = MIO_EMM_SWITCH_CLK_MAX;
bus->bus_switch &= ~MIO_EMM_SWITCH_CLK_HI;
bus->bus_switch &= ~MIO_EMM_SWITCH_CLK_LO;
bus->bus_switch |= period << MIO_EMM_SWITCH_CLK_HI_SHIFT;
bus->bus_switch |= period << MIO_EMM_SWITCH_CLK_LO_SHIFT;
/* Make hardware timeout happen before timeout in software. */
bus->bus_wdog = freq * 900 * OCTMMC_CMD_TIMEOUT;
if (timing)
bus->bus_switch |= MIO_EMM_SWITCH_HS_TIMING;
else
bus->bus_switch &= ~MIO_EMM_SWITCH_HS_TIMING;
return 0;
}
int
octmmc_bus_width(sdmmc_chipset_handle_t sch, int width)
{
struct octmmc_bus *bus = sch;
uint64_t bus_width;
switch (width) {
case 1:
bus_width = 0;
break;
case 4:
bus_width = 1;
break;
case 8:
bus_width = 2;
break;
default:
return ENOTSUP;
}
bus->bus_switch &= ~MIO_EMM_SWITCH_BUS_WIDTH;
bus->bus_switch |= bus_width << MIO_EMM_SWITCH_BUS_WIDTH_SHIFT;
return 0;
}
void
octmmc_exec_command(sdmmc_chipset_handle_t sch, struct sdmmc_command *cmd)
{
struct octmmc_bus *bus = sch;
/*
* Refuse SDIO probe. Proper SDIO operation is not possible
* because of a lack of card interrupt handling.
*/
if (cmd->c_opcode == SD_IO_SEND_OP_COND) {
cmd->c_error = ENOTSUP;
return;
}
/*
* The DMA mode can only do data block transfers. Other commands have
* to use the PIO mode. Single-block transfers can use PIO because
* it has low setup overhead.
*/
if (cmd->c_opcode == MMC_READ_BLOCK_MULTIPLE ||
cmd->c_opcode == MMC_WRITE_BLOCK_MULTIPLE)
octmmc_exec_dma(bus, cmd);
else
octmmc_exec_pio(bus, cmd);
}
void
octmmc_exec_dma(struct octmmc_bus *bus, struct sdmmc_command *cmd)
{
struct octmmc_softc *sc = bus->bus_hc;
uint64_t dmacfg, dmacmd, status;
paddr_t locked_block = 0;
int bounce = 0;
int s;
if (cmd->c_datalen > OCTMMC_MAX_DMASEG) {
cmd->c_error = ENOMEM;
return;
}
s = splsdmmc();
octmmc_acquire(bus);
/*
* Attempt to use the buffer directly for DMA. In case the region
* is not physically contiguous, bounce the data.
*/
if (bus_dmamap_load(sc->sc_dmat, sc->sc_dma_data, cmd->c_data,
cmd->c_datalen, NULL, BUS_DMA_WAITOK)) {
cmd->c_error = bus_dmamap_load(sc->sc_dmat, sc->sc_dma_data,
sc->sc_bounce_buf, cmd->c_datalen, NULL, BUS_DMA_WAITOK);
if (cmd->c_error != 0)
goto dma_out;
bounce = 1;
if (!ISSET(cmd->c_flags, SCF_CMD_READ))
memcpy(sc->sc_bounce_buf, cmd->c_data, cmd->c_datalen);
}
bus_dmamap_sync(sc->sc_dmat, sc->sc_dma_data, 0, cmd->c_datalen,
ISSET(cmd->c_flags, SCF_CMD_READ) ? BUS_DMASYNC_PREREAD :
BUS_DMASYNC_PREWRITE);
/*
* According to Linux, the DMA hardware has a silicon bug that can
* corrupt data. As a workaround, Linux locks the second last block
* of a transfer into the L2 cache if the opcode is multi-block write
* and there are more than two data blocks to write. In Linux, it is
* not described under what circumstances the corruption can happen.
* Lacking better information, use the same workaround here.
*/
if (cmd->c_opcode == MMC_WRITE_BLOCK_MULTIPLE &&
cmd->c_datalen > OCTMMC_BLOCK_SIZE * 2) {
locked_block = sc->sc_dma_data->dm_segs[0].ds_addr +
sc->sc_dma_data->dm_segs[0].ds_len - OCTMMC_BLOCK_SIZE * 2;
Octeon_lock_secondary_cache(curcpu(), locked_block,
OCTMMC_BLOCK_SIZE);
}
/* Set status mask. */
MMC_WR_8(sc, MIO_EMM_STS_MASK, DEF_STS_MASK);
/* Set up the DMA engine. */
dmacfg = MIO_NDF_DMA_CFG_EN;
if (!ISSET(cmd->c_flags, SCF_CMD_READ))
dmacfg |= MIO_NDF_DMA_CFG_RW;
dmacfg |= (sc->sc_dma_data->dm_segs[0].ds_len / sizeof(uint64_t) - 1)
<< MIO_NDF_DMA_CFG_SIZE_SHIFT;
if (sc->sc_hwrev == OCTMMC_HWREV_6130)
dmacfg |= sc->sc_dma_data->dm_segs[0].ds_addr;
DMA_WR_8(sc, MIO_NDF_DMA_CFG, dmacfg);
if (sc->sc_hwrev == OCTMMC_HWREV_7890)
DMA_WR_8(sc, MIO_NDF_DMA_ADR,
sc->sc_dma_data->dm_segs[0].ds_addr);
/* Prepare and issue the command. */
dmacmd = MIO_EMM_DMA_DMA_VAL | MIO_EMM_DMA_MULTI | MIO_EMM_DMA_SECTOR;
dmacmd |= (uint64_t)bus->bus_id << MIO_EMM_DMA_BUS_ID_SHIFT;
dmacmd |= (uint64_t)(cmd->c_datalen / cmd->c_blklen) <<
MIO_EMM_DMA_BLOCK_CNT_SHIFT;
dmacmd |= cmd->c_arg;
if (!ISSET(cmd->c_flags, SCF_CMD_READ))
dmacmd |= MIO_EMM_DMA_RW;
MMC_WR_8(sc, MIO_EMM_DMA, dmacmd);
wait_intr:
cmd->c_error = octmmc_wait_intr(sc, MIO_EMM_INT_CMD_ERR |
MIO_EMM_INT_DMA_DONE | MIO_EMM_INT_DMA_ERR,
OCTMMC_CMD_TIMEOUT * hz);
status = MMC_RD_8(sc, MIO_EMM_RSP_STS);
/* Check DMA engine error. */
if (ISSET(sc->sc_intr_status, MIO_EMM_INT_DMA_ERR)) {
printf("%s: dma error\n", bus->bus_sdmmc->dv_xname);
if (ISSET(status, MIO_EMM_RSP_STS_DMA_PEND)) {
/* Try to stop the DMA engine. */
dmacmd = MMC_RD_8(sc, MIO_EMM_DMA);
dmacmd |= MIO_EMM_DMA_DMA_VAL | MIO_EMM_DMA_DAT_NULL;
dmacmd &= ~MIO_EMM_DMA_BUS_ID;
dmacmd |= (uint64_t)bus->bus_id <<
MIO_EMM_DMA_BUS_ID_SHIFT;
MMC_WR_8(sc, MIO_EMM_DMA, dmacmd);
goto wait_intr;
}
cmd->c_error = EIO;
}
if (cmd->c_error != 0)
goto unload_dma;
/* Check command status. */
if (((status & MIO_EMM_RSP_STS_CMD_IDX) >>
MIO_EMM_RSP_STS_CMD_IDX_SHIFT) != cmd->c_opcode ||
ISSET(status, MIO_EMM_RSP_STS_BLK_CRC_ERR) ||
ISSET(status, MIO_EMM_RSP_STS_DBUF_ERR) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_BAD_STS) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_CRC_ERR)) {
cmd->c_error = EIO;
goto unload_dma;
}
if (ISSET(status, MIO_EMM_RSP_STS_BLK_TIMEOUT) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_TIMEOUT)) {
cmd->c_error = ETIMEDOUT;
goto unload_dma;
}
if (ISSET(cmd->c_flags, SCF_RSP_PRESENT))
octmmc_get_response(sc, cmd);
bus_dmamap_sync(sc->sc_dmat, sc->sc_dma_data, 0, cmd->c_datalen,
ISSET(cmd->c_flags, SCF_CMD_READ) ? BUS_DMASYNC_POSTREAD :
BUS_DMASYNC_POSTWRITE);
if (bounce && ISSET(cmd->c_flags, SCF_CMD_READ))
memcpy(cmd->c_data, sc->sc_bounce_buf, cmd->c_datalen);
unload_dma:
if (locked_block != 0)
Octeon_unlock_secondary_cache(curcpu(), locked_block,
OCTMMC_BLOCK_SIZE);
bus_dmamap_unload(sc->sc_dmat, sc->sc_dma_data);
dma_out:
octmmc_release(bus);
splx(s);
}
void
octmmc_exec_pio(struct octmmc_bus *bus, struct sdmmc_command *cmd)
{
struct octmmc_softc *sc = bus->bus_hc;
unsigned char *ptr;
uint64_t index, piocmd, status, value;
unsigned int i;
int s;
if (cmd->c_datalen > OCTMMC_BLOCK_SIZE ||
cmd->c_datalen % sizeof(uint64_t) != 0) {
cmd->c_error = EINVAL;
return;
}
s = splsdmmc();
octmmc_acquire(bus);
/* If this is a write, copy data to the controller's buffer. */
if (cmd->c_data != NULL && !ISSET(cmd->c_flags, SCF_CMD_READ)) {
/* Reset index and set autoincrement. */
MMC_WR_8(sc, MIO_EMM_BUF_IDX, MIO_EMM_BUF_IDX_INC);
ptr = cmd->c_data;
for (i = 0; i < cmd->c_datalen / sizeof(value); i++) {
memcpy(&value, ptr, sizeof(value));
MMC_WR_8(sc, MIO_EMM_BUF_DAT, value);
ptr += sizeof(value);
}
}
/* Set status mask. */
MMC_WR_8(sc, MIO_EMM_STS_MASK, PIO_STS_MASK);
/* Issue the command. */
piocmd = MIO_EMM_CMD_CMD_VAL;
piocmd |= (uint64_t)bus->bus_id << MIO_EMM_CMD_BUS_ID_SHIFT;
piocmd |= (uint64_t)cmd->c_opcode << MIO_EMM_CMD_CMD_IDX_SHIFT;
piocmd |= cmd->c_arg;
piocmd |= octmmc_crtype_fixup(cmd);
MMC_WR_8(sc, MIO_EMM_CMD, piocmd);
cmd->c_error = octmmc_wait_intr(sc, MIO_EMM_INT_CMD_DONE,
OCTMMC_CMD_TIMEOUT * hz);
if (cmd->c_error != 0)
goto pio_out;
if (ISSET(sc->sc_intr_status, MIO_EMM_INT_CMD_ERR)) {
cmd->c_error = EIO;
goto pio_out;
}
/* Check command status. */
status = MMC_RD_8(sc, MIO_EMM_RSP_STS);
if (((status & MIO_EMM_RSP_STS_CMD_IDX) >>
MIO_EMM_RSP_STS_CMD_IDX_SHIFT) != cmd->c_opcode ||
ISSET(status, MIO_EMM_RSP_STS_BLK_CRC_ERR) ||
ISSET(status, MIO_EMM_RSP_STS_DBUF_ERR) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_BAD_STS) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_CRC_ERR)) {
cmd->c_error = EIO;
goto pio_out;
}
if (ISSET(status, MIO_EMM_RSP_STS_BLK_TIMEOUT) ||
ISSET(status, MIO_EMM_RSP_STS_RSP_TIMEOUT)) {
cmd->c_error = ETIMEDOUT;
goto pio_out;
}
if (ISSET(cmd->c_flags, SCF_RSP_PRESENT))
octmmc_get_response(sc, cmd);
/* If this is a read, copy data from the controller's buffer. */
if (cmd->c_data != NULL && ISSET(cmd->c_flags, SCF_CMD_READ)) {
/* Reset index, set autoincrement and select the buffer. */
index = MIO_EMM_BUF_IDX_INC;
index |= (status >> MIO_EMM_RSP_STS_DBUF_SHIFT) <<
MIO_EMM_BUF_IDX_BUF_NUM_SHIFT;
MMC_WR_8(sc, MIO_EMM_BUF_IDX, MIO_EMM_BUF_IDX_INC);
ptr = cmd->c_data;
for (i = 0; i < cmd->c_datalen / sizeof(value); i++) {
value = MMC_RD_8(sc, MIO_EMM_BUF_DAT);
memcpy(ptr, &value, sizeof(value));
ptr += sizeof(value);
}
}
pio_out:
octmmc_release(bus);
splx(s);
}
/*
* The controller uses MMC command and response types by default.
* When the command and response types of an SD opcode differ from those
* of an overlapping MMC opcode, it is necessary to fix the types.
* Fixing is also needed with a non-overlapping SD opcode when the command
* is a data transfer (adtc) or if a response is expected.
*/
uint64_t
octmmc_crtype_fixup(struct sdmmc_command *cmd)
{
uint64_t cxor = 0;
uint64_t rxor = 0;
switch (cmd->c_opcode) {
case SD_IO_SEND_OP_COND:
cxor = 0x00;
rxor = 0x02;
break;
case SD_SEND_IF_COND:
/* The opcode overlaps with MMC_SEND_EXT_CSD. */
if (SCF_CMD(cmd->c_flags) == SCF_CMD_BCR) {
cxor = 0x01;
rxor = 0x00;
}
break;
case SD_APP_OP_COND:
cxor = 0x00;
rxor = 0x03;
break;
case SD_IO_RW_DIRECT:
case SD_IO_RW_EXTENDED:
cxor = 0x00;
rxor = 0x01;
break;
}
return (cxor << MIO_EMM_CMD_CTYPE_XOR_SHIFT) |
(rxor << MIO_EMM_CMD_RTYPE_XOR_SHIFT);
}
void
octmmc_get_response(struct octmmc_softc *sc, struct sdmmc_command *cmd)
{
uint64_t hi, lo;
if (ISSET(cmd->c_flags, SCF_RSP_136)) {
hi = MMC_RD_8(sc, MIO_EMM_RSP_HI);
lo = MMC_RD_8(sc, MIO_EMM_RSP_LO);
/* Discard the checksum. */
lo = (lo >> 8) | (hi << 56);
hi >>= 8;
/* The stack expects long response in little endian order. */
cmd->c_resp[0] = htole32(lo & 0xffffffffu);
cmd->c_resp[1] = htole32(lo >> 32);
cmd->c_resp[2] = htole32(hi & 0xffffffffu);
cmd->c_resp[3] = htole32(hi >> 32);
} else {
cmd->c_resp[0] = MMC_RD_8(sc, MIO_EMM_RSP_LO) >> 8;
}
}
int
octmmc_wait_intr(struct octmmc_softc *sc, uint64_t mask, int timeout)
{
splassert(IPL_SDMMC);
mask |= MIO_EMM_INT_CMD_ERR | MIO_EMM_INT_DMA_ERR;
sc->sc_intr_status = 0;
while ((sc->sc_intr_status & mask) == 0) {
if (tsleep(&sc->sc_intr_status, PWAIT, "hcintr", timeout)
== EWOULDBLOCK)
return ETIMEDOUT;
}
return 0;
}
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