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Optimize SPI functions, lowering ROM usage by 70 bytes.

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- Have only one transfer function, to minimize duplicate code.
- Remove address assignments that does not make a difference.
This commit is contained in:
Daniel Jobson 2024-09-30 11:29:08 +02:00
parent 9fabff90cb
commit 6ac874584d
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GPG key ID: 3707A9DBF4BB8F1A
3 changed files with 29 additions and 41 deletions
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40
hw/application_fpga/fw/tk1/flash.c
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@ -17,7 +17,7 @@ static volatile uint32_t *timer_ctrl = (volatile uint32_t *)TK1_MMIO_TIMER_CTRL
// clang-format on
// CPU clock frequency in Hz
#define CPUFREQ 18000000
#define CPUFREQ 21000000
#define PAGE_SIZE 256
static void delay(int timeout_ms)
@ -40,7 +40,7 @@ bool flash_is_busy(void)
uint8_t tx_buf = READ_STATUS_REG_1;
uint8_t rx_buf = {0x00};
spi_transfer(&tx_buf, sizeof(tx_buf), &rx_buf, sizeof(rx_buf));
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, &rx_buf, sizeof(rx_buf));
if (rx_buf & (1 << STATUS_REG_BUSY_BIT)) {
return true;
@ -61,14 +61,14 @@ void flash_write_enable(void)
{
uint8_t tx_buf = WRITE_ENABLE;
spi_write(&tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
}
void flash_write_disable(void)
{
uint8_t tx_buf = WRITE_DISABLE;
spi_write(&tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
}
void flash_sector_erase(uint32_t address)
@ -77,10 +77,10 @@ void flash_sector_erase(uint32_t address)
tx_buf[0] = SECTOR_ERASE;
tx_buf[1] = (address >> ADDR_BYTE_3_BIT) & 0xFF;
tx_buf[2] = (address >> ADDR_BYTE_2_BIT) & 0xFF;
tx_buf[3] = (address >> ADDR_BYTE_1_BIT) & 0xFF;
/* tx_buf[3] is within a sector, and hence does not make a difference */
flash_write_enable();
spi_write(tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
flash_wait_busy();
}
@ -93,20 +93,21 @@ void flash_block_32_erase(uint32_t address)
tx_buf[3] = (address >> ADDR_BYTE_1_BIT) & 0xFF;
flash_write_enable();
spi_write(tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
flash_wait_busy();
}
// 64 KiB block erase, only cares about address bits 16 and above.
void flash_block_64_erase(uint32_t address)
{
uint8_t tx_buf[4] = {0x00};
tx_buf[0] = BLOCK_ERASE_64K;
tx_buf[1] = (address >> ADDR_BYTE_3_BIT) & 0xFF;
tx_buf[2] = (address >> ADDR_BYTE_2_BIT) & 0xFF;
tx_buf[3] = (address >> ADDR_BYTE_1_BIT) & 0xFF;
/* tx_buf[2] and tx_buf[3] is within a block, and hence does not make a
* difference */
flash_write_enable();
spi_write(tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
flash_wait_busy();
}
@ -115,14 +116,14 @@ void flash_release_powerdown(void)
uint8_t tx_buf[4] = {0x00};
tx_buf[0] = RELEASE_POWER_DOWN;
spi_write(tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
}
void flash_powerdown(void)
{
uint8_t tx_buf = POWER_DOWN;
spi_write(&tx_buf, sizeof(tx_buf), NULL, 0);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, NULL, 0);
}
void flash_read_manufacturer_device_id(uint8_t *device_id)
@ -130,14 +131,14 @@ void flash_read_manufacturer_device_id(uint8_t *device_id)
uint8_t tx_buf[4] = {0x00};
tx_buf[0] = READ_MANUFACTURER_ID;
spi_transfer(tx_buf, sizeof(tx_buf), device_id, 2);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, device_id, 2);
}
void flash_read_jedec_id(uint8_t *jedec_id)
{
uint8_t tx_buf = READ_JEDEC_ID;
spi_transfer(&tx_buf, sizeof(tx_buf), jedec_id, 3);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, jedec_id, 3);
}
void flash_read_unique_id(uint8_t *unique_id)
@ -145,17 +146,17 @@ void flash_read_unique_id(uint8_t *unique_id)
uint8_t tx_buf[5] = {0x00};
tx_buf[0] = READ_UNIQUE_ID;
spi_transfer(tx_buf, sizeof(tx_buf), unique_id, 8);
spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, unique_id, 8);
}
void flash_read_status(uint8_t *status_reg)
{
uint8_t tx_buf = READ_STATUS_REG_1;
spi_transfer(&tx_buf, sizeof(tx_buf), status_reg, 1);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, status_reg, 1);
tx_buf = READ_STATUS_REG_2;
spi_transfer(&tx_buf, sizeof(tx_buf), status_reg + 1, 1);
spi_transfer(&tx_buf, sizeof(tx_buf), NULL, 0, status_reg + 1, 1);
}
int flash_read_data(uint32_t address, uint8_t *dest_buf, size_t size)
@ -166,7 +167,7 @@ int flash_read_data(uint32_t address, uint8_t *dest_buf, size_t size)
tx_buf[2] = (address >> ADDR_BYTE_2_BIT) & 0xFF;
tx_buf[3] = (address >> ADDR_BYTE_1_BIT) & 0xFF;
return spi_transfer(tx_buf, sizeof(tx_buf), dest_buf, size);
return spi_transfer(tx_buf, sizeof(tx_buf), NULL, 0, dest_buf, size);
}
// Only handles writes where the least significant byte of the start address is
@ -197,7 +198,8 @@ int flash_write_data(uint32_t address, uint8_t *data, size_t size)
flash_write_enable();
if (spi_write(tx_buf, sizeof(tx_buf), p_data, n_bytes) != 0) {
if (spi_transfer(tx_buf, sizeof(tx_buf), p_data, n_bytes, NULL,
0) != 0) {
return -1;
}