tf-a/tf-a-stm32mp-2.2.r1/plat/intel/soc/common/drivers/qspi/cadence_qspi.c

829 lines
20 KiB
C

/*
* Copyright (c) 2019, ARM Limited and Contributors. All rights reserved.
* Copyright (c) 2019, Intel Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <common/debug.h>
#include <lib/mmio.h>
#include <string.h>
#include <drivers/delay_timer.h>
#include <drivers/console.h>
#include "cadence_qspi.h"
#include <platform_def.h>
#define LESS(a, b) (((a) < (b)) ? (a) : (b))
#define MORE(a, b) (((a) > (b)) ? (a) : (b))
uint32_t qspi_device_size;
int cad_qspi_cs;
int cad_qspi_idle(void)
{
return (mmio_read_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG)
& CAD_QSPI_CFG_IDLE) >> 31;
}
int cad_qspi_set_baudrate_div(uint32_t div)
{
if (div > 0xf)
return CAD_INVALID;
mmio_clrsetbits_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG,
~CAD_QSPI_CFG_BAUDDIV_MSK,
CAD_QSPI_CFG_BAUDDIV(div));
return 0;
}
int cad_qspi_configure_dev_size(uint32_t addr_bytes,
uint32_t bytes_per_dev, uint32_t bytes_per_block)
{
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_DEVSZ,
CAD_QSPI_DEVSZ_ADDR_BYTES(addr_bytes) |
CAD_QSPI_DEVSZ_BYTES_PER_PAGE(bytes_per_dev) |
CAD_QSPI_DEVSZ_BYTES_PER_BLOCK(bytes_per_block));
return 0;
}
int cad_qspi_set_read_config(uint32_t opcode, uint32_t instr_type,
uint32_t addr_type, uint32_t data_type,
uint32_t mode_bit, uint32_t dummy_clk_cycle)
{
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_DEVRD,
CAD_QSPI_DEV_OPCODE(opcode) |
CAD_QSPI_DEV_INST_TYPE(instr_type) |
CAD_QSPI_DEV_ADDR_TYPE(addr_type) |
CAD_QSPI_DEV_DATA_TYPE(data_type) |
CAD_QSPI_DEV_MODE_BIT(mode_bit) |
CAD_QSPI_DEV_DUMMY_CLK_CYCLE(dummy_clk_cycle));
return 0;
}
int cad_qspi_set_write_config(uint32_t opcode, uint32_t addr_type,
uint32_t data_type, uint32_t dummy_clk_cycle)
{
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_DEVWR,
CAD_QSPI_DEV_OPCODE(opcode) |
CAD_QSPI_DEV_ADDR_TYPE(addr_type) |
CAD_QSPI_DEV_DATA_TYPE(data_type) |
CAD_QSPI_DEV_DUMMY_CLK_CYCLE(dummy_clk_cycle));
return 0;
}
int cad_qspi_timing_config(uint32_t clkphase, uint32_t clkpol, uint32_t csda,
uint32_t csdads, uint32_t cseot, uint32_t cssot,
uint32_t rddatacap)
{
uint32_t cfg = mmio_read_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG);
cfg &= CAD_QSPI_CFG_SELCLKPHASE_CLR_MSK &
CAD_QSPI_CFG_SELCLKPOL_CLR_MSK;
cfg |= CAD_QSPI_SELCLKPHASE(clkphase) | CAD_QSPI_SELCLKPOL(clkpol);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG, cfg);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_DELAY,
CAD_QSPI_DELAY_CSSOT(cssot) | CAD_QSPI_DELAY_CSEOT(cseot) |
CAD_QSPI_DELAY_CSDADS(csdads) | CAD_QSPI_DELAY_CSDA(csda));
return 0;
}
int cad_qspi_stig_cmd_helper(int cs, uint32_t cmd)
{
uint32_t count = 0;
/* chip select */
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG,
(mmio_read_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG)
& CAD_QSPI_CFG_CS_MSK) | CAD_QSPI_CFG_CS(cs));
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD, cmd);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD,
cmd | CAD_QSPI_FLASHCMD_EXECUTE);
do {
uint32_t reg = mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_FLASHCMD);
if (!(reg & CAD_QSPI_FLASHCMD_EXECUTE_STAT))
break;
count++;
} while (count < CAD_QSPI_COMMAND_TIMEOUT);
if (count >= CAD_QSPI_COMMAND_TIMEOUT) {
ERROR("Error sending QSPI command %x, timed out\n",
cmd);
return CAD_QSPI_ERROR;
}
return 0;
}
int cad_qspi_stig_cmd(uint32_t opcode, uint32_t dummy)
{
if (dummy > ((1 << CAD_QSPI_FLASHCMD_NUM_DUMMYBYTES_MAX) - 1)) {
ERROR("Faulty dummy bytes\n");
return -1;
}
return cad_qspi_stig_cmd_helper(cad_qspi_cs,
CAD_QSPI_FLASHCMD_OPCODE(opcode) |
CAD_QSPI_FLASHCMD_NUM_DUMMYBYTES(dummy));
}
int cad_qspi_stig_read_cmd(uint32_t opcode, uint32_t dummy, uint32_t num_bytes,
uint32_t *output)
{
if (dummy > ((1 << CAD_QSPI_FLASHCMD_NUM_DUMMYBYTES_MAX) - 1)) {
ERROR("Faulty dummy byes\n");
return -1;
}
if ((num_bytes > 8) || (num_bytes == 0))
return -1;
uint32_t cmd =
CAD_QSPI_FLASHCMD_OPCODE(opcode) |
CAD_QSPI_FLASHCMD_ENRDDATA(1) |
CAD_QSPI_FLASHCMD_NUMRDDATABYTES(num_bytes - 1) |
CAD_QSPI_FLASHCMD_ENCMDADDR(0) |
CAD_QSPI_FLASHCMD_ENMODEBIT(0) |
CAD_QSPI_FLASHCMD_NUMADDRBYTES(0) |
CAD_QSPI_FLASHCMD_ENWRDATA(0) |
CAD_QSPI_FLASHCMD_NUMWRDATABYTES(0) |
CAD_QSPI_FLASHCMD_NUMDUMMYBYTES(dummy);
if (cad_qspi_stig_cmd_helper(cad_qspi_cs, cmd)) {
ERROR("failed to send stig cmd\n");
return -1;
}
output[0] = mmio_read_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD_RDDATA0);
if (num_bytes > 4) {
output[1] = mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_FLASHCMD_RDDATA1);
}
return 0;
}
int cad_qspi_stig_wr_cmd(uint32_t opcode, uint32_t dummy, uint32_t num_bytes,
uint32_t *input)
{
if (dummy > ((1 << CAD_QSPI_FLASHCMD_NUM_DUMMYBYTES_MAX) - 1)) {
ERROR("Faulty dummy byes\n");
return -1;
}
if ((num_bytes > 8) || (num_bytes == 0))
return -1;
uint32_t cmd = CAD_QSPI_FLASHCMD_OPCODE(opcode) |
CAD_QSPI_FLASHCMD_ENRDDATA(0) |
CAD_QSPI_FLASHCMD_NUMRDDATABYTES(0) |
CAD_QSPI_FLASHCMD_ENCMDADDR(0) |
CAD_QSPI_FLASHCMD_ENMODEBIT(0) |
CAD_QSPI_FLASHCMD_NUMADDRBYTES(0) |
CAD_QSPI_FLASHCMD_ENWRDATA(1) |
CAD_QSPI_FLASHCMD_NUMWRDATABYTES(num_bytes - 1) |
CAD_QSPI_FLASHCMD_NUMDUMMYBYTES(dummy);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD_WRDATA0, input[0]);
if (num_bytes > 4)
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD_WRDATA1,
input[1]);
return cad_qspi_stig_cmd_helper(cad_qspi_cs, cmd);
}
int cad_qspi_stig_addr_cmd(uint32_t opcode, uint32_t dummy, uint32_t addr)
{
uint32_t cmd;
if (dummy > ((1 << CAD_QSPI_FLASHCMD_NUM_DUMMYBYTES_MAX) - 1))
return -1;
cmd = CAD_QSPI_FLASHCMD_OPCODE(opcode) |
CAD_QSPI_FLASHCMD_NUMDUMMYBYTES(dummy) |
CAD_QSPI_FLASHCMD_ENCMDADDR(1) |
CAD_QSPI_FLASHCMD_NUMADDRBYTES(2);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_FLASHCMD_ADDR, addr);
return cad_qspi_stig_cmd_helper(cad_qspi_cs, cmd);
}
int cad_qspi_device_bank_select(uint32_t bank)
{
int status = 0;
status = cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_WREN, 0);
if (status != 0)
return status;
status = cad_qspi_stig_wr_cmd(CAD_QSPI_STIG_OPCODE_WREN_EXT_REG,
0, 1, &bank);
if (status != 0)
return status;
return cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_WRDIS, 0);
}
int cad_qspi_device_status(uint32_t *status)
{
return cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDSR, 0, 1, status);
}
#if CAD_QSPI_MICRON_N25Q_SUPPORT
int cad_qspi_n25q_enable(void)
{
cad_qspi_set_read_config(QSPI_FAST_READ, CAD_QSPI_INST_SINGLE,
CAD_QSPI_ADDR_FASTREAD, CAT_QSPI_ADDR_SINGLE_IO, 1,
0);
cad_qspi_set_write_config(QSPI_WRITE, 0, 0, 0);
return 0;
}
int cad_qspi_n25q_wait_for_program_and_erase(int program_only)
{
uint32_t status, flag_sr;
int count = 0;
while (count < CAD_QSPI_COMMAND_TIMEOUT) {
status = cad_qspi_device_status(&status);
if (status != 0) {
ERROR("Error getting device status\n");
return -1;
}
if (!CAD_QSPI_STIG_SR_BUSY(status))
break;
count++;
}
if (count >= CAD_QSPI_COMMAND_TIMEOUT) {
ERROR("Timed out waiting for idle\n");
return -1;
}
count = 0;
while (count < CAD_QSPI_COMMAND_TIMEOUT) {
status = cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDFLGSR,
0, 1, &flag_sr);
if (status != 0) {
ERROR("Error waiting program and erase.\n");
return status;
}
if ((program_only &&
CAD_QSPI_STIG_FLAGSR_PROGRAMREADY(flag_sr)) ||
(!program_only &&
CAD_QSPI_STIG_FLAGSR_ERASEREADY(flag_sr)))
break;
}
if (count >= CAD_QSPI_COMMAND_TIMEOUT)
ERROR("Timed out waiting for program and erase\n");
if ((program_only && CAD_QSPI_STIG_FLAGSR_PROGRAMERROR(flag_sr)) ||
(!program_only &&
CAD_QSPI_STIG_FLAGSR_ERASEERROR(flag_sr))) {
ERROR("Error programming/erasing flash\n");
cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_CLFSR, 0);
return -1;
}
return 0;
}
#endif
int cad_qspi_indirect_read_start_bank(uint32_t flash_addr, uint32_t num_bytes)
{
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDRDSTADDR, flash_addr);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDRDCNT, num_bytes);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDRD,
CAD_QSPI_INDRD_START |
CAD_QSPI_INDRD_IND_OPS_DONE);
return 0;
}
int cad_qspi_indirect_write_start_bank(uint32_t flash_addr,
uint32_t num_bytes)
{
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDWRSTADDR, flash_addr);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDWRCNT, num_bytes);
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_INDWR,
CAD_QSPI_INDWR_START |
CAD_QSPI_INDWR_INDDONE);
return 0;
}
int cad_qspi_indirect_write_finish(void)
{
#if CAD_QSPI_MICRON_N25Q_SUPPORT
return cad_qspi_n25q_wait_for_program_and_erase(1);
#else
return 0;
#endif
}
int cad_qspi_enable(void)
{
int status;
mmio_setbits_32(CAD_QSPI_OFFSET + CAD_QSPI_CFG, CAD_QSPI_CFG_ENABLE);
#if CAD_QSPI_MICRON_N25Q_SUPPORT
status = cad_qspi_n25q_enable();
if (status != 0)
return status;
#endif
return 0;
}
int cad_qspi_enable_subsector_bank(uint32_t addr)
{
int status = 0;
status = cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_WREN, 0);
if (status != 0)
return status;
status = cad_qspi_stig_addr_cmd(CAD_QSPI_STIG_OPCODE_SUBSEC_ERASE, 0,
addr);
if (status != 0)
return status;
#if CAD_QSPI_MICRON_N25Q_SUPPORT
status = cad_qspi_n25q_wait_for_program_and_erase(0);
#endif
return status;
}
int cad_qspi_erase_subsector(uint32_t addr)
{
int status = 0;
status = cad_qspi_device_bank_select(addr >> 24);
if (status != 0)
return status;
return cad_qspi_enable_subsector_bank(addr);
}
int cad_qspi_erase_sector(uint32_t addr)
{
int status = 0;
status = cad_qspi_device_bank_select(addr >> 24);
if (status != 0)
return status;
status = cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_WREN, 0);
if (status != 0)
return status;
status = cad_qspi_stig_addr_cmd(CAD_QSPI_STIG_OPCODE_SEC_ERASE, 0,
addr);
if (status != 0)
return status;
#if CAD_QSPI_MICRON_N25Q_SUPPORT
status = cad_qspi_n25q_wait_for_program_and_erase(0);
#endif
return status;
}
void cad_qspi_calibration(uint32_t dev_clk, uint32_t qspi_clk_mhz)
{
int status;
uint32_t dev_sclk_mhz = 27; /*min value to get biggest 0xF div factor*/
uint32_t data_cap_delay;
uint32_t sample_rdid;
uint32_t rdid;
uint32_t div_actual;
uint32_t div_bits;
int first_pass, last_pass;
/*1. Set divider to bigger value (slowest SCLK)
*2. RDID and save the value
*/
div_actual = (qspi_clk_mhz + (dev_sclk_mhz - 1)) / dev_sclk_mhz;
div_bits = (((div_actual + 1) / 2) - 1);
status = cad_qspi_set_baudrate_div(0xf);
status = cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDID,
0, 3, &sample_rdid);
if (status != 0)
return;
/*3. Set divider to the intended frequency
*4. Set the read delay = 0
*5. RDID and check whether the value is same as item 2
*6. Increase read delay and compared the value against item 2
*7. Find the range of read delay that have same as
* item 2 and divide it to 2
*/
div_actual = (qspi_clk_mhz + (dev_clk - 1)) / dev_clk;
div_bits = (((div_actual + 1) / 2) - 1);
status = cad_qspi_set_baudrate_div(div_bits);
if (status != 0)
return;
data_cap_delay = 0;
first_pass = -1;
last_pass = -1;
do {
if (status != 0)
break;
status = cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDID, 0,
3, &rdid);
if (status != 0)
break;
if (rdid == sample_rdid) {
if (first_pass == -1)
first_pass = data_cap_delay;
else
last_pass = data_cap_delay;
}
data_cap_delay++;
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_RDDATACAP,
CAD_QSPI_RDDATACAP_BYP(1) |
CAD_QSPI_RDDATACAP_DELAY(data_cap_delay));
} while (data_cap_delay < 0x10);
if (first_pass > 0) {
int diff = first_pass - last_pass;
data_cap_delay = first_pass + diff / 2;
}
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_RDDATACAP,
CAD_QSPI_RDDATACAP_BYP(1) |
CAD_QSPI_RDDATACAP_DELAY(data_cap_delay));
status = cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDID, 0, 3, &rdid);
if (status != 0)
return;
}
int cad_qspi_int_disable(uint32_t mask)
{
if (cad_qspi_idle() == 0)
return -1;
if ((CAD_QSPI_INT_STATUS_ALL & mask) == 0)
return -1;
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_IRQMSK, mask);
return 0;
}
void cad_qspi_set_chip_select(int cs)
{
cad_qspi_cs = cs;
}
int cad_qspi_init(uint32_t desired_clk_freq, uint32_t clk_phase,
uint32_t clk_pol, uint32_t csda, uint32_t csdads,
uint32_t cseot, uint32_t cssot, uint32_t rddatacap)
{
int status = 0;
uint32_t qspi_desired_clk_freq;
uint32_t rdid = 0;
uint32_t cap_code;
INFO("Initializing Qspi\n");
if (cad_qspi_idle() == 0) {
ERROR("device not idle\n");
return -1;
}
status = cad_qspi_timing_config(clk_phase, clk_pol, csda, csdads,
cseot, cssot, rddatacap);
if (status != 0) {
ERROR("config set timing failure\n");
return status;
}
mmio_write_32(CAD_QSPI_OFFSET + CAD_QSPI_REMAPADDR,
CAD_QSPI_REMAPADDR_VALUE_SET(0));
status = cad_qspi_int_disable(CAD_QSPI_INT_STATUS_ALL);
if (status != 0) {
ERROR("failed disable\n");
return status;
}
cad_qspi_set_baudrate_div(0xf);
status = cad_qspi_enable();
if (status != 0) {
ERROR("failed enable\n");
return status;
}
qspi_desired_clk_freq = 100;
cad_qspi_calibration(qspi_desired_clk_freq, 50000000);
status = cad_qspi_stig_read_cmd(CAD_QSPI_STIG_OPCODE_RDID, 0, 3,
&rdid);
if (status != 0) {
ERROR("Error reading RDID\n");
return status;
}
/*
* NOTE: The Size code seems to be a form of BCD (binary coded decimal).
* The first nibble is the 10's digit and the second nibble is the 1's
* digit in the number of bytes.
*
* Capacity ID samples:
* 0x15 : 16 Mb => 2 MiB => 1 << 21 ; BCD=15
* 0x16 : 32 Mb => 4 MiB => 1 << 22 ; BCD=16
* 0x17 : 64 Mb => 8 MiB => 1 << 23 ; BCD=17
* 0x18 : 128 Mb => 16 MiB => 1 << 24 ; BCD=18
* 0x19 : 256 Mb => 32 MiB => 1 << 25 ; BCD=19
* 0x1a
* 0x1b
* 0x1c
* 0x1d
* 0x1e
* 0x1f
* 0x20 : 512 Mb => 64 MiB => 1 << 26 ; BCD=20
* 0x21 : 1024 Mb => 128 MiB => 1 << 27 ; BCD=21
*/
cap_code = CAD_QSPI_STIG_RDID_CAPACITYID(rdid);
if (!(((cap_code >> 4) > 0x9) || ((cap_code & 0xf) > 0x9))) {
uint32_t decoded_cap = ((cap_code >> 4) * 10) +
(cap_code & 0xf);
qspi_device_size = 1 << (decoded_cap + 6);
INFO("QSPI Capacity: %x\n\n", qspi_device_size);
} else {
ERROR("Invalid CapacityID encountered: 0x%02x\n",
cap_code);
return -1;
}
cad_qspi_configure_dev_size(INTEL_QSPI_ADDR_BYTES,
INTEL_QSPI_BYTES_PER_DEV,
INTEL_BYTES_PER_BLOCK);
INFO("Flash size: %d Bytes\n", qspi_device_size);
return status;
}
int cad_qspi_indirect_page_bound_write(uint32_t offset,
uint8_t *buffer, uint32_t len)
{
int status = 0, i;
uint32_t write_count, write_capacity, *write_data, space,
write_fill_level, sram_partition;
status = cad_qspi_indirect_write_start_bank(offset, len);
if (status != 0)
return status;
write_count = 0;
sram_partition = CAD_QSPI_SRAMPART_ADDR(mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_SRAMPART));
write_capacity = (uint32_t) CAD_QSPI_SRAM_FIFO_ENTRY_COUNT -
sram_partition;
while (write_count < len) {
write_fill_level = CAD_QSPI_SRAMFILL_INDWRPART(
mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_SRAMFILL));
space = LESS(write_capacity - write_fill_level,
(len - write_count) / sizeof(uint32_t));
write_data = (uint32_t *)(buffer + write_count);
for (i = 0; i < space; ++i)
mmio_write_32(CAD_QSPIDATA_OFST, *write_data++);
write_count += space * sizeof(uint32_t);
}
return cad_qspi_indirect_write_finish();
}
int cad_qspi_read_bank(uint8_t *buffer, uint32_t offset, uint32_t size)
{
int status;
uint32_t read_count = 0, *read_data;
int level = 1, count = 0, i;
status = cad_qspi_indirect_read_start_bank(offset, size);
if (status != 0)
return status;
while (read_count < size) {
do {
level = CAD_QSPI_SRAMFILL_INDRDPART(
mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_SRAMFILL));
read_data = (uint32_t *)(buffer + read_count);
for (i = 0; i < level; ++i)
*read_data++ = mmio_read_32(CAD_QSPIDATA_OFST);
read_count += level * sizeof(uint32_t);
count++;
} while (level > 0);
}
return 0;
}
int cad_qspi_write_bank(uint32_t offset, uint8_t *buffer, uint32_t size)
{
int status = 0;
uint32_t page_offset = offset & (CAD_QSPI_PAGE_SIZE - 1);
uint32_t write_size = LESS(size, CAD_QSPI_PAGE_SIZE - page_offset);
while (size) {
status = cad_qspi_indirect_page_bound_write(offset, buffer,
write_size);
if (status != 0)
break;
offset += write_size;
buffer += write_size;
size -= write_size;
write_size = LESS(size, CAD_QSPI_PAGE_SIZE);
}
return status;
}
int cad_qspi_read(void *buffer, uint32_t offset, uint32_t size)
{
uint32_t bank_count, bank_addr, bank_offset, copy_len;
uint8_t *read_data;
int i, status;
status = 0;
if ((offset >= qspi_device_size) ||
(offset + size - 1 >= qspi_device_size) ||
(size == 0) ||
((long) ((int *)buffer) & 0x3) ||
(offset & 0x3) ||
(size & 0x3)) {
ERROR("Invalid read parameter\n");
return -1;
}
if (CAD_QSPI_INDRD_RD_STAT(mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_INDRD))) {
ERROR("Read in progress\n");
return -1;
}
/*
* bank_count : Number of bank(s) affected, including partial banks.
* bank_addr : Aligned address of the first bank,
* including partial bank.
* bank_ofst : The offset of the bank to read.
* Only used when reading the first bank.
*/
bank_count = CAD_QSPI_BANK_ADDR(offset + size - 1) -
CAD_QSPI_BANK_ADDR(offset) + 1;
bank_addr = offset & CAD_QSPI_BANK_ADDR_MSK;
bank_offset = offset & (CAD_QSPI_BANK_SIZE - 1);
read_data = (uint8_t *)buffer;
copy_len = LESS(size, CAD_QSPI_BANK_SIZE - bank_offset);
for (i = 0; i < bank_count; ++i) {
status = cad_qspi_device_bank_select(CAD_QSPI_BANK_ADDR(
bank_addr));
if (status != 0)
break;
status = cad_qspi_read_bank(read_data, bank_offset, copy_len);
if (status != 0)
break;
bank_addr += CAD_QSPI_BANK_SIZE;
read_data += copy_len;
size -= copy_len;
bank_offset = 0;
copy_len = LESS(size, CAD_QSPI_BANK_SIZE);
}
return status;
}
int cad_qspi_erase(uint32_t offset, uint32_t size)
{
int status = 0;
uint32_t subsector_offset = offset & (CAD_QSPI_SUBSECTOR_SIZE - 1);
uint32_t erase_size = LESS(size,
CAD_QSPI_SUBSECTOR_SIZE - subsector_offset);
while (size) {
status = cad_qspi_erase_subsector(offset);
if (status != 0)
break;
offset += erase_size;
size -= erase_size;
erase_size = LESS(size, CAD_QSPI_SUBSECTOR_SIZE);
}
return status;
}
int cad_qspi_write(void *buffer, uint32_t offset, uint32_t size)
{
int status, i;
uint32_t bank_count, bank_addr, bank_offset, copy_len;
uint8_t *write_data;
status = 0;
if ((offset >= qspi_device_size) ||
(offset + size - 1 >= qspi_device_size) ||
(size == 0) ||
((long)buffer & 0x3) ||
(offset & 0x3) ||
(size & 0x3))
return -2;
if (CAD_QSPI_INDWR_RDSTAT(mmio_read_32(CAD_QSPI_OFFSET +
CAD_QSPI_INDWR))) {
ERROR("QSPI Error: Write in progress\n");
return -1;
}
bank_count = CAD_QSPI_BANK_ADDR(offset + size - 1) -
CAD_QSPI_BANK_ADDR(offset) + 1;
bank_addr = offset & CAD_QSPI_BANK_ADDR_MSK;
bank_offset = offset & (CAD_QSPI_BANK_SIZE - 1);
write_data = buffer;
copy_len = LESS(size, CAD_QSPI_BANK_SIZE - bank_offset);
for (i = 0; i < bank_count; ++i) {
status = cad_qspi_device_bank_select(
CAD_QSPI_BANK_ADDR(bank_addr));
if (status != 0)
break;
status = cad_qspi_write_bank(bank_offset, write_data,
copy_len);
if (status != 0)
break;
bank_addr += CAD_QSPI_BANK_SIZE;
write_data += copy_len;
size -= copy_len;
bank_offset = 0;
copy_len = LESS(size, CAD_QSPI_BANK_SIZE);
}
return status;
}
int cad_qspi_update(void *Buffer, uint32_t offset, uint32_t size)
{
int status = 0;
status = cad_qspi_erase(offset, size);
if (status != 0)
return status;
return cad_qspi_write(Buffer, offset, size);
}
void cad_qspi_reset(void)
{
cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_RESET_EN, 0);
cad_qspi_stig_cmd(CAD_QSPI_STIG_OPCODE_RESET_MEM, 0);
}