mirror of
https://github.com/DarkFlippers/unleashed-firmware
synced 2024-12-18 16:53:45 +00:00
33e8bae78b
* AVR_ISP: fix NULL pointer dereference * SubGhz: double back with a blocked transmission in this region * SubGhz: fix speaker, when a transmission is blocked in this region * SubGhz: fix speaker * SubGhz: return region * AVR Flasher: cleanup code Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
496 lines
No EOL
14 KiB
C
496 lines
No EOL
14 KiB
C
#include "avr_isp.h"
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#include "../lib/driver/avr_isp_prog_cmd.h"
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#include "../lib/driver/avr_isp_spi_sw.h"
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#include <furi.h>
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#define AVR_ISP_PROG_TX_RX_BUF_SIZE 320
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#define TAG "AvrIsp"
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struct AvrIsp {
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AvrIspSpiSw* spi;
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bool pmode;
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AvrIspCallback callback;
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void* context;
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};
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AvrIsp* avr_isp_alloc(void) {
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AvrIsp* instance = malloc(sizeof(AvrIsp));
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return instance;
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}
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void avr_isp_free(AvrIsp* instance) {
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furi_assert(instance);
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if(instance->spi) avr_isp_end_pmode(instance);
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free(instance);
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}
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void avr_isp_set_tx_callback(AvrIsp* instance, AvrIspCallback callback, void* context) {
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furi_assert(instance);
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furi_assert(context);
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instance->callback = callback;
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instance->context = context;
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}
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uint8_t avr_isp_spi_transaction(
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AvrIsp* instance,
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uint8_t cmd,
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uint8_t addr_hi,
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uint8_t addr_lo,
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uint8_t data) {
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furi_assert(instance);
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avr_isp_spi_sw_txrx(instance->spi, cmd);
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avr_isp_spi_sw_txrx(instance->spi, addr_hi);
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avr_isp_spi_sw_txrx(instance->spi, addr_lo);
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return avr_isp_spi_sw_txrx(instance->spi, data);
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}
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static bool avr_isp_set_pmode(AvrIsp* instance, uint8_t a, uint8_t b, uint8_t c, uint8_t d) {
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furi_assert(instance);
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uint8_t res = 0;
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avr_isp_spi_sw_txrx(instance->spi, a);
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avr_isp_spi_sw_txrx(instance->spi, b);
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res = avr_isp_spi_sw_txrx(instance->spi, c);
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avr_isp_spi_sw_txrx(instance->spi, d);
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return res == 0x53;
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}
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void avr_isp_end_pmode(AvrIsp* instance) {
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furi_assert(instance);
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if(instance->pmode) {
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avr_isp_spi_sw_res_set(instance->spi, true);
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// We're about to take the target out of reset
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// so configure SPI pins as input
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if(instance->spi) avr_isp_spi_sw_free(instance->spi);
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instance->spi = NULL;
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}
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instance->pmode = false;
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}
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static bool avr_isp_start_pmode(AvrIsp* instance, AvrIspSpiSwSpeed spi_speed) {
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furi_assert(instance);
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// Reset target before driving PIN_SCK or PIN_MOSI
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// SPI.begin() will configure SS as output,
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// so SPI master mode is selected.
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// We have defined RESET as pin 10,
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// which for many arduino's is not the SS pin.
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// So we have to configure RESET as output here,
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// (reset_target() first sets the correct level)
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if(instance->spi) avr_isp_spi_sw_free(instance->spi);
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instance->spi = avr_isp_spi_sw_init(spi_speed);
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avr_isp_spi_sw_res_set(instance->spi, false);
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// See avr datasheets, chapter "SERIAL_PRG Programming Algorithm":
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// Pulse RESET after PIN_SCK is low:
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avr_isp_spi_sw_sck_set(instance->spi, false);
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// discharge PIN_SCK, value arbitrally chosen
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furi_delay_ms(20);
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avr_isp_spi_sw_res_set(instance->spi, true);
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// Pulse must be minimum 2 target CPU speed cycles
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// so 100 usec is ok for CPU speeds above 20KHz
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furi_delay_ms(1);
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avr_isp_spi_sw_res_set(instance->spi, false);
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// Send the enable programming command:
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// datasheet: must be > 20 msec
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furi_delay_ms(50);
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if(avr_isp_set_pmode(instance, AVR_ISP_SET_PMODE)) {
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instance->pmode = true;
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return true;
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}
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return false;
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}
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bool avr_isp_auto_set_spi_speed_start_pmode(AvrIsp* instance) {
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furi_assert(instance);
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AvrIspSpiSwSpeed spi_speed[] = {
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AvrIspSpiSwSpeed1Mhz,
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AvrIspSpiSwSpeed400Khz,
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AvrIspSpiSwSpeed250Khz,
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AvrIspSpiSwSpeed125Khz,
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AvrIspSpiSwSpeed60Khz,
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AvrIspSpiSwSpeed40Khz,
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AvrIspSpiSwSpeed20Khz,
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AvrIspSpiSwSpeed10Khz,
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AvrIspSpiSwSpeed5Khz,
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AvrIspSpiSwSpeed1Khz,
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};
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for(uint8_t i = 0; i < COUNT_OF(spi_speed); i++) {
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if(avr_isp_start_pmode(instance, spi_speed[i])) {
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AvrIspSignature sig = avr_isp_read_signature(instance);
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AvrIspSignature sig_examination = avr_isp_read_signature(instance); //-V656
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uint8_t y = 0;
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while(y < 8) {
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if(memcmp((uint8_t*)&sig, (uint8_t*)&sig_examination, sizeof(AvrIspSignature)) !=
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0)
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break;
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sig_examination = avr_isp_read_signature(instance);
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y++;
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}
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if(y == 8) {
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if(spi_speed[i] > AvrIspSpiSwSpeed1Mhz) {
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if(i < (COUNT_OF(spi_speed) - 1)) {
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avr_isp_end_pmode(instance);
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i++;
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return avr_isp_start_pmode(instance, spi_speed[i]);
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}
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}
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return true;
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}
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}
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}
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if(instance->spi) {
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avr_isp_spi_sw_free(instance->spi);
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instance->spi = NULL;
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}
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return false;
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}
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static void avr_isp_commit(AvrIsp* instance, uint16_t addr, uint8_t data) {
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furi_assert(instance);
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avr_isp_spi_transaction(instance, AVR_ISP_COMMIT(addr));
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/* polling flash */
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if(data == 0xFF) {
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furi_delay_ms(5);
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} else {
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/* polling flash */
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 30) {
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FLASH_HI(addr)) != 0xFF) {
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break;
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};
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}
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}
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}
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static uint16_t avr_isp_current_page(AvrIsp* instance, uint32_t addr, uint16_t page_size) {
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furi_assert(instance);
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uint16_t page = 0;
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switch(page_size) {
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case 32:
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page = addr & 0xFFFFFFF0;
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break;
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case 64:
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page = addr & 0xFFFFFFE0;
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break;
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case 128:
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page = addr & 0xFFFFFFC0;
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break;
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case 256:
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page = addr & 0xFFFFFF80;
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break;
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default:
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page = addr;
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break;
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}
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return page;
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}
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static bool avr_isp_flash_write_pages(
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AvrIsp* instance,
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uint16_t addr,
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uint16_t page_size,
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uint8_t* data,
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uint32_t data_size) {
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furi_assert(instance);
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size_t x = 0;
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uint16_t page = avr_isp_current_page(instance, addr, page_size);
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while(x < data_size) {
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if(page != avr_isp_current_page(instance, addr, page_size)) {
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avr_isp_commit(instance, page, data[x - 1]);
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page = avr_isp_current_page(instance, addr, page_size);
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}
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_FLASH_LO(addr, data[x++]));
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_FLASH_HI(addr, data[x++]));
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addr++;
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}
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avr_isp_commit(instance, page, data[x - 1]);
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return true;
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}
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bool avr_isp_erase_chip(AvrIsp* instance) {
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furi_assert(instance);
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bool ret = false;
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if(!instance->pmode) avr_isp_auto_set_spi_speed_start_pmode(instance);
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if(instance->pmode) {
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avr_isp_spi_transaction(instance, AVR_ISP_ERASE_CHIP);
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furi_delay_ms(100);
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avr_isp_end_pmode(instance);
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ret = true;
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}
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return ret;
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}
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static bool
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avr_isp_eeprom_write(AvrIsp* instance, uint16_t addr, uint8_t* data, uint32_t data_size) {
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furi_assert(instance);
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for(uint16_t i = 0; i < data_size; i++) {
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_EEPROM(addr, data[i]));
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furi_delay_ms(10);
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addr++;
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}
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return true;
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}
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bool avr_isp_write_page(
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AvrIsp* instance,
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uint32_t mem_type,
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uint32_t mem_size,
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uint16_t addr,
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uint16_t page_size,
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uint8_t* data,
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uint32_t data_size) {
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furi_assert(instance);
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bool ret = false;
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switch(mem_type) {
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case STK_SET_FLASH_TYPE:
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if((addr + data_size / 2) <= mem_size) {
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ret = avr_isp_flash_write_pages(instance, addr, page_size, data, data_size);
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}
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break;
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case STK_SET_EEPROM_TYPE:
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if((addr + data_size) <= mem_size) {
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ret = avr_isp_eeprom_write(instance, addr, data, data_size);
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}
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break;
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default:
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furi_crash(TAG " Incorrect mem type.");
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break;
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}
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return ret;
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}
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static bool avr_isp_flash_read_page(
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AvrIsp* instance,
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uint16_t addr,
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uint16_t page_size,
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uint8_t* data,
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uint32_t data_size) {
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furi_assert(instance);
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if(page_size > data_size) return false;
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for(uint16_t i = 0; i < page_size; i += 2) {
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data[i] = avr_isp_spi_transaction(instance, AVR_ISP_READ_FLASH_LO(addr));
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data[i + 1] = avr_isp_spi_transaction(instance, AVR_ISP_READ_FLASH_HI(addr));
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addr++;
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}
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return true;
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}
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static bool avr_isp_eeprom_read_page(
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AvrIsp* instance,
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uint16_t addr,
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uint16_t page_size,
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uint8_t* data,
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uint32_t data_size) {
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furi_assert(instance);
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if(page_size > data_size) return false;
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for(uint16_t i = 0; i < page_size; i++) {
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data[i] = avr_isp_spi_transaction(instance, AVR_ISP_READ_EEPROM(addr));
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addr++;
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}
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return true;
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}
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bool avr_isp_read_page(
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AvrIsp* instance,
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uint32_t mem_type,
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uint16_t addr,
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uint16_t page_size,
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uint8_t* data,
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uint32_t data_size) {
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furi_assert(instance);
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bool res = false;
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if(mem_type == STK_SET_FLASH_TYPE)
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res = avr_isp_flash_read_page(instance, addr, page_size, data, data_size);
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if(mem_type == STK_SET_EEPROM_TYPE)
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res = avr_isp_eeprom_read_page(instance, addr, page_size, data, data_size);
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return res;
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}
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AvrIspSignature avr_isp_read_signature(AvrIsp* instance) {
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furi_assert(instance);
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AvrIspSignature signature;
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signature.vendor = avr_isp_spi_transaction(instance, AVR_ISP_READ_VENDOR);
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signature.part_family = avr_isp_spi_transaction(instance, AVR_ISP_READ_PART_FAMILY);
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signature.part_number = avr_isp_spi_transaction(instance, AVR_ISP_READ_PART_NUMBER);
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return signature;
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}
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uint8_t avr_isp_read_lock_byte(AvrIsp* instance) {
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furi_assert(instance);
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uint8_t data = 0;
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 300) {
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data = avr_isp_spi_transaction(instance, AVR_ISP_READ_LOCK_BYTE);
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_LOCK_BYTE) == data) {
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break;
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};
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data = 0x00;
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}
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return data;
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}
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bool avr_isp_write_lock_byte(AvrIsp* instance, uint8_t lock) {
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furi_assert(instance);
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bool ret = false;
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if(avr_isp_read_lock_byte(instance) == lock) {
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ret = true;
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} else {
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_LOCK_BYTE(lock));
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/* polling lock byte */
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 30) {
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_LOCK_BYTE) == lock) {
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ret = true;
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break;
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};
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}
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}
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return ret;
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}
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uint8_t avr_isp_read_fuse_low(AvrIsp* instance) {
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furi_assert(instance);
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uint8_t data = 0;
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 300) {
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data = avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_LOW);
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_LOW) == data) {
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break;
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};
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data = 0x00;
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}
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return data;
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}
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bool avr_isp_write_fuse_low(AvrIsp* instance, uint8_t lfuse) {
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furi_assert(instance);
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bool ret = false;
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if(avr_isp_read_fuse_low(instance) == lfuse) {
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ret = true;
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} else {
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_FUSE_LOW(lfuse));
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/* polling fuse */
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 30) {
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_LOW) == lfuse) {
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ret = true;
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break;
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};
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}
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}
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return ret;
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}
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uint8_t avr_isp_read_fuse_high(AvrIsp* instance) {
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furi_assert(instance);
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uint8_t data = 0;
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 300) {
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data = avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_HIGH);
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_HIGH) == data) {
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break;
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};
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data = 0x00;
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}
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return data;
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}
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bool avr_isp_write_fuse_high(AvrIsp* instance, uint8_t hfuse) {
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furi_assert(instance);
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bool ret = false;
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if(avr_isp_read_fuse_high(instance) == hfuse) {
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ret = true;
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} else {
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_FUSE_HIGH(hfuse));
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/* polling fuse */
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 30) {
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_HIGH) == hfuse) {
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ret = true;
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break;
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};
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}
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}
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return ret;
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}
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uint8_t avr_isp_read_fuse_extended(AvrIsp* instance) {
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furi_assert(instance);
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uint8_t data = 0;
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 300) {
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data = avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_EXTENDED);
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_EXTENDED) == data) {
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break;
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};
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data = 0x00;
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}
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return data;
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}
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bool avr_isp_write_fuse_extended(AvrIsp* instance, uint8_t efuse) {
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furi_assert(instance);
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bool ret = false;
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if(avr_isp_read_fuse_extended(instance) == efuse) {
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ret = true;
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} else {
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avr_isp_spi_transaction(instance, AVR_ISP_WRITE_FUSE_EXTENDED(efuse));
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/* polling fuse */
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uint32_t starttime = furi_get_tick();
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while((furi_get_tick() - starttime) < 30) {
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if(avr_isp_spi_transaction(instance, AVR_ISP_READ_FUSE_EXTENDED) == efuse) {
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ret = true;
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break;
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};
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}
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}
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return ret;
|
|
}
|
|
|
|
void avr_isp_write_extended_addr(AvrIsp* instance, uint8_t extended_addr) {
|
|
furi_assert(instance);
|
|
|
|
avr_isp_spi_transaction(instance, AVR_ISP_EXTENDED_ADDR(extended_addr));
|
|
furi_delay_ms(10);
|
|
} |