mirror of
https://github.com/DarkFlippers/unleashed-firmware
synced 2024-11-24 05:23:06 +00:00
851a44dc59
* Gui: input injection in screen stream * Cli: expose ASCII table in public header * SubGhz: dma output draft * SubGhz: output initialization cleanup * SubGhz: update dma send routine, add subghz_tx cli command. * SubGhz: proper register address for DMA * SubGhz: proper, fully working dma+tim2 configuration * SubGhz: transmit PT with cli. * Drivers: fix invalid size in CC1101 PA_TABLE loading routine. * Interrupts: configurable DMA isrs. * F5: backport fixes. * SubGhz: free buffer after use * SubGhz: use sleep instead of reset at the end * SubGhz: async tx repeat with circular DMA * SubGhz: disable dma channel on complete, adjust PT send timings * SubGhz: backport function singature change to F5 * SubGhz: add tx debug gpio
191 lines
5.9 KiB
C
191 lines
5.9 KiB
C
#include "cc1101.h"
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#include <cmsis_os2.h>
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#include <api-hal-delay.h>
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#include <assert.h>
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#include <string.h>
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CC1101Status cc1101_strobe(const ApiHalSpiDevice* device, uint8_t strobe) {
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uint8_t tx[1] = { strobe };
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CC1101Status rx[1] = { 0 };
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hal_gpio_write(device->chip_select, false);
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while(hal_gpio_read(device->bus->miso));
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api_hal_spi_bus_trx(device->bus, tx, (uint8_t*)rx, 1, CC1101_TIMEOUT);
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hal_gpio_write(device->chip_select, true);
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assert(rx[0].CHIP_RDYn == 0);
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return rx[0];
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}
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CC1101Status cc1101_write_reg(const ApiHalSpiDevice* device, uint8_t reg, uint8_t data) {
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uint8_t tx[2] = { reg, data };
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CC1101Status rx[2] = { 0 };
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hal_gpio_write(device->chip_select, false);
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while(hal_gpio_read(device->bus->miso));
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api_hal_spi_bus_trx(device->bus, tx, (uint8_t*)rx, 2, CC1101_TIMEOUT);
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hal_gpio_write(device->chip_select, true);
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assert((rx[0].CHIP_RDYn|rx[1].CHIP_RDYn) == 0);
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return rx[1];
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}
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CC1101Status cc1101_read_reg(const ApiHalSpiDevice* device, uint8_t reg, uint8_t* data) {
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assert(sizeof(CC1101Status) == 1);
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uint8_t tx[2] = { reg|CC1101_READ, 0};
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CC1101Status rx[2] = { 0 };
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hal_gpio_write(device->chip_select, false);
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while(hal_gpio_read(device->bus->miso));
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api_hal_spi_bus_trx(device->bus, tx, (uint8_t*)rx, 2, CC1101_TIMEOUT);
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hal_gpio_write(device->chip_select, true);
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assert((rx[0].CHIP_RDYn) == 0);
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*data = *(uint8_t*)&rx[1];
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return rx[0];
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}
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uint8_t cc1101_get_partnumber(const ApiHalSpiDevice* device) {
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uint8_t partnumber=0;
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cc1101_read_reg(device, CC1101_STATUS_PARTNUM|CC1101_BURST, &partnumber);
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return partnumber;
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}
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uint8_t cc1101_get_version(const ApiHalSpiDevice* device) {
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uint8_t version=0;
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cc1101_read_reg(device, CC1101_STATUS_VERSION|CC1101_BURST, &version);
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return version;
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}
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uint8_t cc1101_get_rssi(const ApiHalSpiDevice* device) {
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uint8_t rssi=0;
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cc1101_read_reg(device, CC1101_STATUS_RSSI|CC1101_BURST, &rssi);
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return rssi;
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}
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void cc1101_reset(const ApiHalSpiDevice* device) {
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hal_gpio_write(device->chip_select, false);
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delay_us(1000);
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hal_gpio_write(device->chip_select, true);
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delay_us(1000);
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cc1101_strobe(device, CC1101_STROBE_SRES);
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}
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CC1101Status cc1101_get_status(const ApiHalSpiDevice* device) {
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return cc1101_strobe(device, CC1101_STROBE_SNOP);
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}
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void cc1101_shutdown(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SPWD);
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}
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void cc1101_calibrate(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SCAL);
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}
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void cc1101_switch_to_idle(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SIDLE);
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}
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void cc1101_switch_to_rx(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SRX);
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}
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void cc1101_switch_to_tx(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_STX);
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}
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void cc1101_flush_rx(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SFRX);
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}
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void cc1101_flush_tx(const ApiHalSpiDevice* device) {
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cc1101_strobe(device, CC1101_STROBE_SFTX);
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}
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uint32_t cc1101_set_frequency(const ApiHalSpiDevice* device, uint32_t value) {
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uint64_t real_value = (uint64_t)value * CC1101_FDIV / CC1101_QUARTZ;
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// Sanity check
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assert((real_value & CC1101_FMASK) == real_value);
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cc1101_write_reg(device, CC1101_FREQ2, (real_value >> 16) & 0xFF);
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cc1101_write_reg(device, CC1101_FREQ1, (real_value >> 8 ) & 0xFF);
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cc1101_write_reg(device, CC1101_FREQ0, (real_value >> 0 ) & 0xFF);
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uint64_t real_frequency = real_value * CC1101_QUARTZ / CC1101_FDIV;
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return (uint32_t)real_frequency;
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}
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uint32_t cc1101_get_frequency_step(const ApiHalSpiDevice* device) {
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return CC1101_QUARTZ / CC1101_FDIV;
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}
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uint32_t cc1101_set_frequency_offset(const ApiHalSpiDevice* device, uint32_t value) {
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uint64_t real_value = value * CC1101_IFDIV / CC1101_QUARTZ;
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assert((real_value & 0xFF) == real_value);
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cc1101_write_reg(device, CC1101_FSCTRL0, (real_value >> 0 ) & 0xFF);
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uint64_t real_frequency = real_value * CC1101_QUARTZ / CC1101_IFDIV;
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return (uint32_t)real_frequency;
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}
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uint32_t cc1101_get_frequency_offset_step(const ApiHalSpiDevice* device) {
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return CC1101_QUARTZ / CC1101_IFDIV;
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}
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void cc1101_set_pa_table(const ApiHalSpiDevice* device, const uint8_t value[8]) {
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uint8_t tx[9] = { CC1101_PATABLE | CC1101_BURST };
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CC1101Status rx[9] = { 0 };
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memcpy(&tx[1], &value[0], 8);
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hal_gpio_write(device->chip_select, false);
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while(hal_gpio_read(device->bus->miso));
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api_hal_spi_bus_trx(device->bus, tx, (uint8_t*)rx, sizeof(rx), CC1101_TIMEOUT);
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hal_gpio_write(device->chip_select, true);
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assert((rx[0].CHIP_RDYn|rx[8].CHIP_RDYn) == 0);
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}
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uint8_t cc1101_write_fifo(const ApiHalSpiDevice* device, const uint8_t* data, uint8_t size) {
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uint8_t buff_tx[64];
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uint8_t buff_rx[64];
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buff_tx[0] = CC1101_FIFO | CC1101_BURST;
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memcpy(&buff_tx[1], data, size);
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// Start transaction
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hal_gpio_write(device->chip_select, false);
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// Wait IC to become ready
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while(hal_gpio_read(device->bus->miso));
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// Tell IC what we want
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api_hal_spi_bus_trx(device->bus, buff_tx, (uint8_t*) buff_rx, size + 1, CC1101_TIMEOUT);
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// Finish transaction
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hal_gpio_write(device->chip_select, true);
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return size;
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}
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uint8_t cc1101_read_fifo(const ApiHalSpiDevice* device, uint8_t* data, uint8_t* size) {
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uint8_t buff_tx[64];
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buff_tx[0] = CC1101_FIFO | CC1101_READ | CC1101_BURST;
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uint8_t buff_rx[2];
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// Start transaction
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hal_gpio_write(device->chip_select, false);
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// Wait IC to become ready
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while(hal_gpio_read(device->bus->miso));
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// First byte - packet length
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api_hal_spi_bus_trx(device->bus, buff_tx, buff_rx, 2, CC1101_TIMEOUT);
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*size = buff_rx[2];
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api_hal_spi_bus_trx(device->bus, &buff_tx[1], data, *size, CC1101_TIMEOUT);
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cc1101_flush_rx(device);
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hal_gpio_write(device->chip_select, true);
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return *size;
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}
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