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/* SPDX-License-Identifier: GPL-2.0-only */
#include <device/mmio.h>
#include <soc/spi.h>
#include <soc/clock.h>
#include <soc/addressmap.h>
#include "spi_internal.h"
static struct spi_ctrl *spictrls[] = {
(struct spi_ctrl *)FU540_QSPI0,
(struct spi_ctrl *)FU540_QSPI1,
(struct spi_ctrl *)FU540_QSPI2
};
/**
* Wait until SPI is ready for transmission and transmit byte.
*/
static void spi_tx(volatile struct spi_ctrl *spictrl, uint8_t in)
{
#if __riscv_atomic
int32_t r;
do {
asm volatile (
"amoor.w %0, %2, %1\n"
: "=r" (r), "+A" (spictrl->txdata.raw_bits)
: "r" (in)
);
} while (r < 0);
#else
while ((int32_t) spictrl->txdata.raw_bits < 0)
;
spictrl->txdata.data = in;
#endif
}
/**
* Wait until SPI receive queue has data and read byte.
*/
static uint8_t spi_rx(volatile struct spi_ctrl *spictrl)
{
int32_t out;
while ((out = (int32_t) spictrl->rxdata.raw_bits) < 0)
;
return (uint8_t) out;
}
static int spi_claim_bus_(const struct spi_slave *slave)
{
struct spi_ctrl *spictrl = spictrls[slave->bus];
spi_reg_csmode csmode;
csmode.raw_bits = 0;
csmode.mode = FU540_SPI_CSMODE_HOLD;
write32(&spictrl->csmode.raw_bits, csmode.raw_bits);
return 0;
}
static void spi_release_bus_(const struct spi_slave *slave)
{
struct spi_ctrl *spictrl = spictrls[slave->bus];
spi_reg_csmode csmode;
csmode.raw_bits = 0;
csmode.mode = FU540_SPI_CSMODE_OFF;
write32(&spictrl->csmode.raw_bits, csmode.raw_bits);
}
static int spi_xfer_(const struct spi_slave *slave,
const void *dout, size_t bytesout,
void *din, size_t bytesin)
{
struct spi_ctrl *spictrl = spictrls[slave->bus];
spi_reg_fmt fmt;
fmt.raw_bits = read32(&spictrl->fmt.raw_bits);
if (fmt.proto == FU540_SPI_PROTO_S) {
/* working in full-duplex mode
* receiving data needs to be triggered by sending data */
while (bytesout || bytesin) {
uint8_t in, out = 0;
if (bytesout) {
out = *(uint8_t *)dout++;
bytesout--;
}
spi_tx(spictrl, out);
in = spi_rx(spictrl);
if (bytesin) {
*(uint8_t *)din++ = in;
bytesin--;
}
}
} else {
/* Working in half duplex
* send and receive can be done separately */
if (dout && din)
return -1;
if (dout) {
while (bytesout) {
spi_tx(spictrl, *(uint8_t *)dout++);
bytesout--;
}
}
if (din) {
while (bytesin) {
*(uint8_t *)din++ = spi_rx(spictrl);
bytesin--;
}
}
}
return 0;
}
static int spi_setup_(const struct spi_slave *slave)
{
spi_reg_sckmode sckmode;
spi_reg_csmode csmode;
spi_reg_fmt fmt;
if ((slave->bus > 2) || (slave->cs != 0))
return -1;
struct spi_ctrl *spictrl = spictrls[slave->bus];
write32(&spictrl->sckdiv, spi_min_clk_divisor(clock_get_tlclk_khz(),
10000));
sckmode.raw_bits = 0;
sckmode.pha = FU540_SPI_PHA_LOW;
sckmode.pol = FU540_SPI_POL_LEADING;
write32(&spictrl->sckmode.raw_bits, sckmode.raw_bits);
write32(&spictrl->csdef, 0xffffffff);
csmode.raw_bits = 0;
csmode.mode = FU540_SPI_CSMODE_AUTO;
write32(&spictrl->csmode.raw_bits, csmode.raw_bits);
fmt.raw_bits = 0;
fmt.proto = FU540_SPI_PROTO_S;
fmt.endian = FU540_SPI_ENDIAN_BIG;
fmt.dir = 0;
fmt.len = 8;
write32(&spictrl->fmt.raw_bits, fmt.raw_bits);
return 0;
}
struct spi_ctrlr fu540_spi_ctrlr = {
.xfer = spi_xfer_,
.setup = spi_setup_,
.claim_bus = spi_claim_bus_,
.release_bus = spi_release_bus_,
};
const struct spi_ctrlr_buses spi_ctrlr_bus_map[] = {
{
.bus_start = 0,
.bus_end = 2,
.ctrlr = &fu540_spi_ctrlr,
}
};
const size_t spi_ctrlr_bus_map_count = ARRAY_SIZE(spi_ctrlr_bus_map);
int fu540_spi_setup(unsigned int bus, unsigned int cs,
struct spi_slave *slave,
struct fu540_spi_config *config)
{
spi_reg_sckmode sckmode;
spi_reg_csmode csmode;
spi_reg_fmt fmt;
if ((bus > 2) || (cs != 0))
return -1;
if ((config->pha > 1)
|| (config->pol > 1)
|| (config->protocol > 2)
|| (config->endianness > 1)
|| (config->bits_per_frame > 8))
return -1;
slave->bus = bus;
slave->cs = cs;
slave->ctrlr = &fu540_spi_ctrlr;
struct spi_ctrl *spictrl = spictrls[slave->bus];
write32(&spictrl->sckdiv, spi_min_clk_divisor(clock_get_tlclk_khz(),
config->freq / 1000));
sckmode.raw_bits = 0;
sckmode.pha = config->pha;
sckmode.pol = config->pol;
write32(&spictrl->sckmode.raw_bits, sckmode.raw_bits);
write32(&spictrl->csdef, 0xffffffff);
csmode.raw_bits = 0;
csmode.mode = FU540_SPI_CSMODE_AUTO;
write32(&spictrl->csmode.raw_bits, csmode.raw_bits);
fmt.raw_bits = 0;
fmt.proto = config->protocol;
fmt.endian = config->endianness;
fmt.dir = 0;
fmt.len = config->bits_per_frame;
write32(&spictrl->fmt.raw_bits, fmt.raw_bits);
return 0;
}
int fu540_spi_mmap(
const struct spi_slave *slave,
const struct fu540_spi_mmap_config *config)
{
spi_reg_fctrl fctrl;
spi_reg_ffmt ffmt;
if (slave->bus > 2)
return -1;
if ((config->cmd_en > 1)
|| (config->addr_len > 4)
|| (config->pad_cnt > 15)
|| (config->cmd_proto > 2)
|| (config->addr_proto > 2)
|| (config->data_proto > 2)
|| (config->cmd_code > 255)
|| (config->pad_code > 255))
return -1;
struct spi_ctrl *spictrl = spictrls[slave->bus];
/* disable direct memory-mapped spi flash mode */
fctrl.raw_bits = 0;
fctrl.en = 0;
write32(&spictrl->fctrl.raw_bits, fctrl.raw_bits);
/* reset spi flash chip */
spi_tx(spictrl, 0x66);
spi_tx(spictrl, 0x99);
/* Pass the information of the flash read operation to the spi
* controller */
ffmt.raw_bits = 0;
ffmt.cmd_en = config->cmd_en;
ffmt.addr_len = config->addr_len;
ffmt.pad_cnt = config->pad_cnt;
ffmt.command_proto = config->cmd_proto;
ffmt.addr_proto = config->addr_proto;
ffmt.data_proto = config->data_proto;
ffmt.command_code = config->cmd_code;
ffmt.pad_code = config->pad_code;
write32(&spictrl->ffmt.raw_bits, ffmt.raw_bits);
/* enable direct memory-mapped spi flash mode */
fctrl.raw_bits = 0;
fctrl.en = 1;
write32(&spictrl->fctrl.raw_bits, fctrl.raw_bits);
return 0;
}
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