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review.coreboot.org / coreboot / 0b0113f2436b448cd172d2ae9cfcc07628020173 / . / src / soc / cavium / cn81xx / spi.c
blob: a3ef56743d576a9ae52f97329188f0b608b18970 [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0-only */
/*
* Derived from Cavium's BSD-3 Clause OCTEONTX-SDK-6.2.0.
*/
#include <device/mmio.h>
#include <assert.h>
#include <console/console.h>
#include <endian.h>
#include <soc/addressmap.h>
#include <soc/spi.h>
#include <soc/clock.h>
#include <spi-generic.h>
#include <spi_flash.h>
#include <timer.h>
union cavium_spi_cfg {
u64 u;
struct {
u64 enable : 1;
u64 idlelow : 1;
u64 clk_cont : 1;
u64 wireor : 1;
u64 lsbfirst : 1;
u64 : 2;
u64 cshi : 1;
u64 idleclks : 2;
u64 tristate : 1;
u64 cslate : 1;
u64 csena : 4; /* Must be one */
u64 clkdiv : 13;
u64 : 35;
} s;
};
union cavium_spi_sts {
u64 u;
struct {
u64 busy : 1;
u64 mpi_intr : 1;
u64 : 6;
u64 rxnum : 5;
u64 : 51;
} s;
};
union cavium_spi_tx {
u64 u;
struct {
u64 totnum : 5;
u64 : 3;
u64 txnum : 5;
u64 : 3;
u64 leavecs : 1;
u64 : 3;
u64 csid : 2;
u64 : 42;
} s;
};
struct cavium_spi {
union cavium_spi_cfg cfg;
union cavium_spi_sts sts;
union cavium_spi_tx tx;
u64 rsvd1;
u64 sts_w1s;
u64 rsvd2;
u64 int_ena_w1c;
u64 int_ena_w1s;
u64 wide_dat;
u8 rsvd4[0x38];
u64 dat[8];
};
check_member(cavium_spi, cfg, 0);
check_member(cavium_spi, sts, 0x8);
check_member(cavium_spi, tx, 0x10);
check_member(cavium_spi, dat[7], 0xb8);
struct cavium_spi_slave {
struct cavium_spi *regs;
int cs;
};
#define SPI_TIMEOUT_US 5000
static struct cavium_spi_slave cavium_spi_slaves[] = {
{
.regs = (struct cavium_spi *)MPI_PF_BAR0,
.cs = 0,
},
};
static struct cavium_spi_slave *to_cavium_spi(const struct spi_slave *slave)
{
assert(slave->bus < ARRAY_SIZE(cavium_spi_slaves));
return &cavium_spi_slaves[slave->bus];
}
/**
* Enable the SPI controller. Pins are driven.
*
* @param bus The SPI bus to operate on
*/
void spi_enable(const size_t bus)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
cfg.u = read64(&regs->cfg);
cfg.s.csena = 0xf;
cfg.s.enable = 1;
write64(&regs->cfg, cfg.u);
}
/**
* Disable the SPI controller. Pins are tristated.
*
* @param bus The SPI bus to operate on
*/
void spi_disable(const size_t bus)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
cfg.u = read64(&regs->cfg);
cfg.s.csena = 0xf;
cfg.s.enable = 0;
write64(&regs->cfg, cfg.u);
}
/**
* Set SPI Chip select line and level if asserted.
*
* @param bus The SPI bus to operate on
* @param chip_select The chip select pin to use (0 - 3)
* @param assert_is_low CS pin state is low when asserted
*/
void spi_set_cs(const size_t bus,
const size_t chip_select,
const size_t assert_is_low)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return;
cavium_spi_slaves[bus].cs = chip_select & 0x3;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
cfg.u = read64(&regs->cfg);
cfg.s.csena = 0xf;
cfg.s.cshi = !assert_is_low;
write64(&regs->cfg, cfg.u);
//FIXME: CS2/3: Change pin mux here
}
/**
* Set SPI clock frequency.
*
* @param bus The SPI bus to operate on
* @param speed_hz The SPI frequency in Hz
* @param idle_low The SPI clock idles low
* @param idle_cycles Number of CLK cycles between two commands (0 - 3)
*/
void spi_set_clock(const size_t bus,
const size_t speed_hz,
const size_t idle_low,
const size_t idle_cycles)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
const uint64_t sclk = thunderx_get_io_clock();
cfg.u = read64(&regs->cfg);
cfg.s.csena = 0xf;
cfg.s.clk_cont = 0;
cfg.s.idlelow = !!idle_low;
cfg.s.idleclks = idle_cycles & 0x3;
cfg.s.clkdiv = MIN(sclk / (2ULL * speed_hz), 0x1fff);
write64(&regs->cfg, cfg.u);
printk(BIOS_DEBUG, "SPI: set clock to %lld kHz\n",
(sclk / (2ULL * cfg.s.clkdiv)) >> 10);
}
/**
* Get current SPI clock frequency in Hz.
*
* @param bus The SPI bus to operate on
*/
uint64_t spi_get_clock(const size_t bus)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return 0;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
const uint64_t sclk = thunderx_get_io_clock();
cfg.u = read64(&regs->cfg);
return (sclk / (2ULL * cfg.s.clkdiv));
}
/**
* Set SPI LSB/MSB first.
*
* @param bus The SPI bus to operate on
* @param lsb_first The SPI operates LSB first
*
*/
void spi_set_lsbmsb(const size_t bus, const size_t lsb_first)
{
union cavium_spi_cfg cfg;
assert(bus < ARRAY_SIZE(cavium_spi_slaves));
if (bus >= ARRAY_SIZE(cavium_spi_slaves))
return;
struct cavium_spi *regs = cavium_spi_slaves[bus].regs;
cfg.u = read64(&regs->cfg);
cfg.s.csena = 0xf;
cfg.s.lsbfirst = !!lsb_first;
write64(&regs->cfg, cfg.u);
}
/**
* Init SPI with custom parameters and enable SPI controller.
*
* @param bus The SPI bus to operate on
* @param speed_hz The SPI frequency in Hz
* @param idle_low The SPI clock idles low
* @param idle_cycles Number of CLK cycles between two commands (0 - 3)
* @param lsb_first The SPI operates LSB first
* @param chip_select The chip select pin to use (0 - 3)
* @param assert_is_low CS pin state is low when asserted
*/
void spi_init_custom(const size_t bus,
const size_t speed_hz,
const size_t idle_low,
const size_t idle_cycles,
const size_t lsb_first,
const size_t chip_select,
const size_t assert_is_low)
{
spi_disable(bus);
spi_set_clock(bus, speed_hz, idle_low, idle_cycles);
spi_set_lsbmsb(bus, lsb_first);
spi_set_cs(bus, chip_select, assert_is_low);
spi_enable(bus);
}
/**
* Init all SPI controllers with default values and enable all SPI controller.
*
*/
void spi_init(void)
{
for (size_t i = 0; i < ARRAY_SIZE(cavium_spi_slaves); i++) {
spi_disable(i);
spi_set_clock(i, 12500000, 0, 0);
spi_set_lsbmsb(i, 0);
spi_set_cs(i, 0, 1);
spi_enable(i);
}
}
static int cavium_spi_wait(struct cavium_spi *regs)
{
struct stopwatch sw;
union cavium_spi_sts sts;
stopwatch_init_usecs_expire(&sw, SPI_TIMEOUT_US);
do {
sts.u = read64(&regs->sts);
if (!sts.s.busy)
return 0;
} while (!stopwatch_expired(&sw));
printk(BIOS_DEBUG, "SPI: Timed out after %uus\n", SPI_TIMEOUT_US);
return -1;
}
static int do_xfer(const struct spi_slave *slave, struct spi_op *vector,
int leavecs)
{
struct cavium_spi *regs = to_cavium_spi(slave)->regs;
uint8_t *out_buf = (uint8_t *)vector->dout;
size_t bytesout = vector->bytesout;
uint8_t *in_buf = (uint8_t *)vector->din;
size_t bytesin = vector->bytesin;
union cavium_spi_sts sts;
union cavium_spi_tx tx;
/**
* The CN81xx SPI controller is half-duplex and has 8 data registers.
* If >8 bytes remain in the transfer then we must set LEAVECS = 1 so
* that the /CS remains asserted. Once <=8 bytes remain we must set
* LEAVECS = 0 so that /CS is de-asserted, thus completing the transfer.
*/
while (bytesout) {
size_t out_now = MIN(bytesout, 8);
unsigned int i;
for (i = 0; i < out_now; i++)
write64(&regs->dat[i], out_buf[i] & 0xff);
tx.u = 0;
tx.s.csid = to_cavium_spi(slave)->cs;
if (leavecs || ((bytesout > 8) || bytesin))
tx.s.leavecs = 1;
/* number of bytes to transmit goes in both TXNUM and TOTNUM */
tx.s.totnum = out_now;
tx.s.txnum = out_now;
write64(&regs->tx, tx.u);
/* check status */
if (cavium_spi_wait(regs) < 0)
return -1;
bytesout -= out_now;
out_buf += out_now;
}
while (bytesin) {
size_t in_now = MIN(bytesin, 8);
unsigned int i;
tx.u = 0;
tx.s.csid = to_cavium_spi(slave)->cs;
if (leavecs || (bytesin > 8))
tx.s.leavecs = 1;
tx.s.totnum = in_now;
write64(&regs->tx, tx.u);
/* check status */
if (cavium_spi_wait(regs) < 0)
return -1;
sts.u = read64(&regs->sts);
if (sts.s.rxnum != in_now) {
printk(BIOS_ERR,
"SPI: Incorrect number of bytes received: %u.\n",
sts.s.rxnum);
return -1;
}
for (i = 0; i < in_now; i++) {
*in_buf = (uint8_t)((read64(&regs->dat[i]) & 0xff));
in_buf++;
}
bytesin -= in_now;
}
return 0;
}
static int spi_ctrlr_xfer_vector(const struct spi_slave *slave,
struct spi_op vectors[], size_t count)
{
int i;
for (i = 0; i < count; i++) {
if (do_xfer(slave, &vectors[i], count - 1 == i ? 0 : 1)) {
printk(BIOS_ERR,
"SPI: Failed to transfer %zu vectors.\n", count);
return -1;
}
}
return 0;
}
static const struct spi_ctrlr spi_ctrlr = {
.xfer_vector = spi_ctrlr_xfer_vector,
.max_xfer_size = SPI_CTRLR_DEFAULT_MAX_XFER_SIZE,
};
const struct spi_ctrlr_buses spi_ctrlr_bus_map[] = {
{
.ctrlr = &spi_ctrlr,
.bus_start = 0,
.bus_end = ARRAY_SIZE(cavium_spi_slaves) - 1,
},
};
const size_t spi_ctrlr_bus_map_count = ARRAY_SIZE(spi_ctrlr_bus_map);