// // Created by MightyPork on 2017/11/26. // #include "platform.h" #include "utils/avrlibc.h" #include "hw_utils.h" /** Convert pin number to LL bitfield */ uint32_t hw_pin2ll(uint8_t pin_number, bool *suc) { assert_param(suc != NULL); if(pin_number > 15) { dbg("Bad pin: %d", pin_number); // TODO proper report *suc = false; return 0; } return LL_GPIO_PINS[pin_number]; } /** Convert port name (A,B,C...) to peripheral struct pointer */ GPIO_TypeDef *hw_port2periph(char port_name, bool *suc) { assert_param(suc != NULL); if(port_name < 'A' || port_name >= ('A'+PORTS_COUNT)) { dbg("Bad port: %c", port_name); // TODO proper report *suc = false; return NULL; } uint8_t num = (uint8_t) (port_name - 'A'); return GPIO_PERIPHS[num]; } /** Convert a pin to resource handle */ Resource hw_pin2resource(char port_name, uint8_t pin_number, bool *suc) { assert_param(suc != NULL); if(port_name < 'A' || port_name >= ('A'+PORTS_COUNT)) { dbg("Bad port: %c", port_name); // TODO proper report *suc = false; return R_NONE; } if(pin_number > 15) { dbg("Bad pin: %d", pin_number); // TODO proper report *suc = false; return R_NONE; } uint8_t num = (uint8_t) (port_name - 'A'); return R_PA0 + num*16 + pin_number; } /** Parse single pin */ bool parse_pin(const char *value, char *targetName, uint8_t *targetNumber) { // discard leading 'P' if (value[0] == 'P') { value++; } size_t len = strlen(value); if (len<2||len>3) return false; *targetName = (uint8_t) value[0]; if (!(*targetName >= 'A' && *targetName <= 'H')) return false; // lets just hope it's OK *targetNumber = (uint8_t) avr_atoi(value + 1); return true; } /** Parse port name */ bool parse_port_name(const char *value, char *targetName) { *targetName = (uint8_t) value[0]; if (!(*targetName >= 'A' && *targetName < 'A' + PORTS_COUNT)) return false; return true; } /** Parse a list of pin numbers with ranges and commans/semicolons to a bitmask */ uint16_t parse_pinmask(const char *value, bool *suc) { uint32_t bits = 0; uint32_t acu = 0; bool inrange = false; uint32_t rangestart = 0; // shortcut if none are set if (value[0] == 0) return 0; char c; do { c = *value++; if (c == ' ' || c == '\t') { // skip } else if (c >= '0' && c <= '9') { acu = acu*10 + (c-'0'); } else if (c == ',' || c == ';' || c == 0) { // end of number or range if (!inrange) rangestart = acu; // swap them if they're in the wrong order if (acu < rangestart) { uint32_t swp = acu; acu = rangestart; rangestart = swp; } for(uint32_t i=rangestart; i<=acu; i++) { bits |= 1< 0xFFFF) *suc = false; return (uint16_t) bits; } /** Convert a pin bitmask to the ASCII format understood by str_parse_pinmask() */ char * pinmask2str(uint16_t pins, char *buffer) { char *b = buffer; uint32_t start = 0; bool on = false; bool first = true; // shortcut if none are set if (pins == 0) { buffer[0] = 0; return buffer; } for (int32_t i = 15; i >= -1; i--) { bool bit; if (i == -1) { bit = false; } else { bit = 0 != (pins & 0x8000); pins <<= 1; } if (bit) { if (!on) { start = (uint32_t) i; on = true; } } else { if (on) { if (!first) { b += SPRINTF(b, ", "); } if (start == (uint32_t)(i+1)) { b += SPRINTF(b, "%"PRIu32, start); } else { b += SPRINTF(b, "%"PRIu32"-%"PRIu32, start, i + 1); } first = false; on = false; } } } return buffer; } char * pinmask2str_up(uint16_t pins, char *buffer) { char *b = buffer; uint32_t start = 0; bool on = false; bool first = true; // shortcut if none are set if (pins == 0) { buffer[0] = 0; return buffer; } for (int32_t i = 0; i <= 16; i++) { bool bit; if (i == 16) { bit = false; } else { bit = 0 != (pins & 1); pins >>= 1; } if (bit) { if (!on) { start = (uint32_t) i; on = true; } } else { if (on) { if (!first) { b += SPRINTF(b, ", "); } if (start == (uint32_t)(i-1)) { b += SPRINTF(b, "%"PRIu32, start); } else { b += SPRINTF(b, "%"PRIu32"-%"PRIu32, start, i - 1); } first = false; on = false; } } } return buffer; } /** Spread packed port pins using a mask */ uint16_t pinmask_spread(uint16_t packed, uint16_t mask) { uint16_t result = 0; uint16_t poke = 1; for (int i = 0; i<16; i++) { if (mask & (1<resources, rsc)) { rsc_dbg("Freeing pin %s", rsc_get_name((Resource)rsc)); GPIO_TypeDef *port = GPIO_PERIPHS[(rsc-R_PA0) / 16]; uint32_t ll_pin = LL_GPIO_PINS[(rsc-R_PA0)%16]; LL_GPIO_SetPinMode(port, ll_pin, LL_GPIO_MODE_ANALOG); } } } /** Configure a pin to alternate function */ error_t hw_configure_gpio_af(char port_name, uint8_t pin_num, uint32_t ll_af) { #if PLAT_NO_AFNUM trap("Illegal call to hw_configure_gpio_af() on this platform"); #else bool suc = true; GPIO_TypeDef *port = hw_port2periph(port_name, &suc); uint32_t ll_pin = hw_pin2ll(pin_num, &suc); if (!suc) return E_BAD_CONFIG; if (pin_num < 8) LL_GPIO_SetAFPin_0_7(port, ll_pin, ll_af); else LL_GPIO_SetAFPin_8_15(port, ll_pin, ll_af); LL_GPIO_SetPinMode(port, ll_pin, LL_GPIO_MODE_ALTERNATE); #endif return E_SUCCESS; } /** Configure pins using sparse map */ error_t hw_configure_sparse_pins(char port_name, uint16_t mask, GPIO_TypeDef **port_dest, uint32_t ll_mode, uint32_t ll_otype) { bool suc = true; GPIO_TypeDef *port = hw_port2periph(port_name, &suc); if (!suc) return E_BAD_CONFIG; for (int i = 0; i < 16; i++) { if (mask & (1< ceil) { wPresc <<= 1; wCount >>= 1; } if (wPresc > ceil || count == 0) { return false; } *count = wCount; *presc = (uint16_t) wPresc; if (wPresc * wCount == 0) return false; if (real_freq != NULL) { *real_freq = (base_freq / (wPresc * wCount)); } return true; } void hw_periph_clock_enable(void *periph) { // GPIOs are enabled by default on start-up // --- USART --- if (periph == USART1) __HAL_RCC_USART1_CLK_ENABLE(); else if (periph == USART2) __HAL_RCC_USART2_CLK_ENABLE(); #ifdef USART3 else if (periph == USART3) __HAL_RCC_USART3_CLK_ENABLE(); #endif #ifdef USART4 else if (periph == USART4) __HAL_RCC_USART4_CLK_ENABLE(); #endif #ifdef USART5 else if (periph == USART5) __HAL_RCC_USART5_CLK_ENABLE(); #endif // --- SPI --- else if (periph == SPI1) __HAL_RCC_SPI1_CLK_ENABLE(); #ifdef SPI2 else if (periph == SPI2) __HAL_RCC_SPI2_CLK_ENABLE(); #endif #ifdef SPI3 else if (periph == SPI3) __HAL_RCC_SPI3_CLK_ENABLE(); #endif // --- I2C --- else if (periph == I2C1) __HAL_RCC_I2C1_CLK_ENABLE(); else if (periph == I2C2) __HAL_RCC_I2C2_CLK_ENABLE(); #ifdef I2C3 else if (periph == I2C3) __HAL_RCC_I2C3_CLK_ENABLE(); #endif // --- DMA --- else if (periph == DMA1) __HAL_RCC_DMA1_CLK_ENABLE(); #ifdef DMA2 else if (periph == DMA2) __HAL_RCC_DMA2_CLK_ENABLE(); #endif // --- TIM --- else if (periph == TIM1) __HAL_RCC_TIM1_CLK_ENABLE(); else if (periph == TIM2) __HAL_RCC_TIM2_CLK_ENABLE(); else if (periph == TIM3) __HAL_RCC_TIM3_CLK_ENABLE(); #ifdef TIM4 else if (periph == TIM4) __HAL_RCC_TIM4_CLK_ENABLE(); #endif #ifdef TIM5 else if (periph == TIM5) __HAL_RCC_TIM5_CLK_ENABLE(); #endif #ifdef TIM6 else if (periph == TIM6) __HAL_RCC_TIM7_CLK_ENABLE(); #endif #ifdef TIM7 else if (periph == TIM7) __HAL_RCC_TIM7_CLK_ENABLE(); #endif #ifdef TIM8 else if (periph == TIM8) __HAL_RCC_TIM8_CLK_ENABLE(); #endif #ifdef TIM9 else if (periph == TIM9) __HAL_RCC_TIM9_CLK_ENABLE(); #endif #ifdef TIM11 else if (periph == TIM11) __HAL_RCC_TIM11_CLK_ENABLE(); #endif #ifdef TIM12 else if (periph == TIM12) __HAL_RCC_TIM12_CLK_ENABLE(); #endif #ifdef TIM13 else if (periph == TIM13) __HAL_RCC_TIM13_CLK_ENABLE(); #endif #ifdef TIM14 else if (periph == TIM14) __HAL_RCC_TIM14_CLK_ENABLE(); #endif #ifdef TIM15 else if (periph == TIM15) __HAL_RCC_TIM15_CLK_ENABLE(); #endif #ifdef TIM16 else if (periph == TIM16) __HAL_RCC_TIM15_CLK_ENABLE(); #endif #ifdef TIM17 else if (periph == TIM17) __HAL_RCC_TIM17_CLK_ENABLE(); #endif // --- ADC --- #ifdef ADC1 else if (periph == ADC1) __HAL_RCC_ADC1_CLK_ENABLE(); #endif #ifdef ADC2 else if (periph == ADC2) __HAL_RCC_ADC2_CLK_ENABLE(); #endif // --- DAC --- #ifdef DAC1 else if (periph == DAC1) __HAL_RCC_DAC1_CLK_ENABLE(); #endif #ifdef DAC2 else if (periph == DAC2) __HAL_RCC_DAC2_CLK_ENABLE(); #endif else { dbg("Periph 0x%p missing in hw clock enable func", periph); trap("BUG"); } } void hw_periph_clock_disable(void *periph) { // GPIOs are enabled by default on start-up // --- USART --- if (periph == USART1) __HAL_RCC_USART1_CLK_DISABLE(); else if (periph == USART2) __HAL_RCC_USART2_CLK_DISABLE(); #ifdef USART3 else if (periph == USART3) __HAL_RCC_USART3_CLK_DISABLE(); #endif #ifdef USART4 else if (periph == USART4) __HAL_RCC_USART4_CLK_DISABLE(); #endif #ifdef USART5 else if (periph == USART5) __HAL_RCC_USART5_CLK_DISABLE(); #endif // --- SPI --- else if (periph == SPI1) __HAL_RCC_SPI1_CLK_DISABLE(); #ifdef SPI2 else if (periph == SPI2) __HAL_RCC_SPI2_CLK_DISABLE(); #endif #ifdef SPI3 else if (periph == SPI3) __HAL_RCC_SPI3_CLK_DISABLE(); #endif // --- I2C --- else if (periph == I2C1) __HAL_RCC_I2C1_CLK_DISABLE(); else if (periph == I2C2) __HAL_RCC_I2C2_CLK_DISABLE(); #ifdef I2C3 else if (periph == I2C3) __HAL_RCC_I2C3_CLK_DISABLE(); #endif // --- DMA --- else if (periph == DMA1) __HAL_RCC_DMA1_CLK_DISABLE(); #ifdef DMA2 else if (periph == DMA2) __HAL_RCC_DMA2_CLK_DISABLE(); #endif // --- TIM --- else if (periph == TIM1) __HAL_RCC_TIM1_CLK_DISABLE(); else if (periph == TIM2) __HAL_RCC_TIM2_CLK_DISABLE(); else if (periph == TIM3) __HAL_RCC_TIM3_CLK_DISABLE(); #ifdef TIM4 else if (periph == TIM4) __HAL_RCC_TIM4_CLK_DISABLE(); #endif #ifdef TIM5 else if (periph == TIM5) __HAL_RCC_TIM5_CLK_DISABLE(); #endif #ifdef TIM6 else if (periph == TIM6) __HAL_RCC_TIM7_CLK_DISABLE(); #endif #ifdef TIM7 else if (periph == TIM7) __HAL_RCC_TIM7_CLK_DISABLE(); #endif #ifdef TIM8 else if (periph == TIM8) __HAL_RCC_TIM8_CLK_DISABLE(); #endif #ifdef TIM9 else if (periph == TIM9) __HAL_RCC_TIM9_CLK_DISABLE(); #endif #ifdef TIM11 else if (periph == TIM11) __HAL_RCC_TIM11_CLK_DISABLE(); #endif #ifdef TIM12 else if (periph == TIM12) __HAL_RCC_TIM12_CLK_DISABLE(); #endif #ifdef TIM13 else if (periph == TIM13) __HAL_RCC_TIM13_CLK_DISABLE(); #endif #ifdef TIM14 else if (periph == TIM14) __HAL_RCC_TIM14_CLK_DISABLE(); #endif #ifdef TIM15 else if (periph == TIM15) __HAL_RCC_TIM15_CLK_DISABLE(); #endif #ifdef TIM16 else if (periph == TIM16) __HAL_RCC_TIM15_CLK_DISABLE(); #endif #ifdef TIM17 else if (periph == TIM17) __HAL_RCC_TIM17_CLK_DISABLE(); #endif // --- ADC --- #ifdef ADC1 else if (periph == ADC1) __HAL_RCC_ADC1_CLK_DISABLE(); #endif #ifdef ADC2 else if (periph == ADC2) __HAL_RCC_ADC2_CLK_DISABLE(); #endif // --- DAC --- #ifdef DAC1 else if (periph == DAC1) __HAL_RCC_DAC1_CLK_DISABLE(); #endif #ifdef DAC2 else if (periph == DAC2) __HAL_RCC_DAC2_CLK_DISABLE(); #endif else { dbg("Periph 0x%p missing in hw clock disable func", periph); trap("BUG"); } }