/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010, 2011,2012,2013 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. ChibiOS/RT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /** * @file STM32F30x/adc_lld.c * @brief STM32F30x ADC subsystem low level driver source. * * @addtogroup ADC * @{ */ #include "ch.h" #include "hal.h" #if HAL_USE_ADC || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver local definitions. */ /*===========================================================================*/ #if STM32_ADC_DUAL_MODE #if STM32_ADC_COMPACT_SAMPLES /* Compact type dual mode.*/ #define ADC_DMA_SIZE (STM32_DMA_CR_MSIZE_HWORD | STM32_DMA_CR_PSIZE_HWORD) #define ADC_DMA_MDMA ADC_CCR_MDMA_HWORD #else /* !STM32_ADC_COMPACT_SAMPLES */ /* Large type dual mode.*/ #define ADC_DMA_SIZE (STM32_DMA_CR_MSIZE_WORD | STM32_DMA_CR_PSIZE_WORD) #define ADC_DMA_MDMA ADC_CCR_MDMA_WORD #endif /* !STM32_ADC_COMPACT_SAMPLES */ #else /* !STM32_ADC_DUAL_MODE */ #if STM32_ADC_COMPACT_SAMPLES /* Compact type single mode.*/ #define ADC_DMA_SIZE (STM32_DMA_CR_MSIZE_BYTE | STM32_DMA_CR_PSIZE_BYTE) #define ADC_DMA_MDMA ADC_CCR_MDMA_DISABLED #else /* !STM32_ADC_COMPACT_SAMPLES */ /* Large type single mode.*/ #define ADC_DMA_SIZE (STM32_DMA_CR_MSIZE_HWORD | STM32_DMA_CR_PSIZE_HWORD) #define ADC_DMA_MDMA ADC_CCR_MDMA_DISABLED #endif /* !STM32_ADC_COMPACT_SAMPLES */ #endif /* !STM32_ADC_DUAL_MODE */ /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ /** @brief ADC1 driver identifier.*/ #if STM32_ADC_USE_ADC1 || defined(__DOXYGEN__) ADCDriver ADCD1; #endif /** @brief ADC1 driver identifier.*/ #if STM32_ADC_USE_ADC3 || defined(__DOXYGEN__) ADCDriver ADCD3; #endif /*===========================================================================*/ /* Driver local variables and types. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ /** * @brief Enables the ADC voltage regulator. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_vreg_on(ADCDriver *adcp) { adcp->adcm->CR = 0; /* RM 12.4.3.*/ adcp->adcm->CR = ADC_CR_ADVREGEN_0; #if STM32_ADC_DUAL_MODE adcp->adcs->CR = ADC_CR_ADVREGEN_0; #endif halPolledDelay(US2RTT(10)); } /** * @brief Disables the ADC voltage regulator. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_vreg_off(ADCDriver *adcp) { adcp->adcm->CR = 0; /* RM 12.4.3.*/ adcp->adcm->CR = ADC_CR_ADVREGEN_1; #if STM32_ADC_DUAL_MODE adcp->adcs->CR = ADC_CR_ADVREGEN_1; #endif } /** * @brief Enables the ADC analog circuit. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_analog_on(ADCDriver *adcp) { adcp->adcm->CR |= ADC_CR_ADEN; while ((adcp->adcm->ISR & ADC_ISR_ADRDY) == 0) ; #if STM32_ADC_DUAL_MODE adcp->adcs->CR |= ADC_CR_ADEN; while ((adcp->adcs->ISR & ADC_ISR_ADRDY) == 0) ; #endif } /** * @brief Disables the ADC analog circuit. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_analog_off(ADCDriver *adcp) { adcp->adcm->CR |= ADC_CR_ADDIS; while ((adcp->adcm->CR & ADC_CR_ADDIS) != 0) ; #if STM32_ADC_DUAL_MODE adcp->adcs->CR |= ADC_CR_ADDIS; while ((adcp->adcs->CR & ADC_CR_ADDIS) != 0) ; #endif } /** * @brief Calibrates and ADC unit. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_calibrate(ADCDriver *adcp) { chDbgAssert(adcp->adcm->CR == ADC_CR_ADVREGEN_0, "adc_lld_calibrate(), #1", "invalid register state"); adcp->adcm->CR |= ADC_CR_ADCAL; while ((adcp->adcm->CR & ADC_CR_ADCAL) != 0) ; #if STM32_ADC_DUAL_MODE chDbgAssert(adcp->adcs->CR == ADC_CR_ADVREGEN_0, "adc_lld_calibrate(), #2", "invalid register state"); adcp->adcs->CR |= ADC_CR_ADCAL; while ((adcp->adcs->CR & ADC_CR_ADCAL) != 0) ; #endif } /** * @brief Stops an ongoing conversion, if any. * * @param[in] adcp pointer to the @p ADCDriver object */ static void adc_lld_stop_adc(ADCDriver *adcp) { if (adcp->adcm->CR & ADC_CR_ADSTART) { adcp->adcm->CR |= ADC_CR_ADSTP; while (adcp->adcm->CR & ADC_CR_ADSTP) ; } } /** * @brief ADC DMA ISR service routine. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] flags pre-shifted content of the ISR register */ static void adc_lld_serve_dma_interrupt(ADCDriver *adcp, uint32_t flags) { /* DMA errors handling.*/ if ((flags & (STM32_DMA_ISR_TEIF | STM32_DMA_ISR_DMEIF)) != 0) { /* DMA, this could help only if the DMA tries to access an unmapped address space or violates alignment rules.*/ _adc_isr_error_code(adcp, ADC_ERR_DMAFAILURE); } else { /* It is possible that the conversion group has already be reset by the ADC error handler, in this case this interrupt is spurious.*/ if (adcp->grpp != NULL) { if ((flags & STM32_DMA_ISR_HTIF) != 0) { /* Half transfer processing.*/ _adc_isr_half_code(adcp); } if ((flags & STM32_DMA_ISR_TCIF) != 0) { /* Transfer complete processing.*/ _adc_isr_full_code(adcp); } } } } /** * @brief ADC ISR service routine. * * @param[in] adcp pointer to the @p ADCDriver object * @param[in] isr content of the ISR register */ static void adc_lld_serve_interrupt(ADCDriver *adcp, uint32_t isr) { /* It could be a spurious interrupt caused by overflows after DMA disabling, just ignore it in this case.*/ if (adcp->grpp != NULL) { /* Note, an overflow may occur after the conversion ended before the driver is able to stop the ADC, this is why the DMA channel is checked too.*/ if ((isr & ADC_ISR_OVR) && (dmaStreamGetTransactionSize(adcp->dmastp) > 0)) { /* ADC overflow condition, this could happen only if the DMA is unable to read data fast enough.*/ _adc_isr_error_code(adcp, ADC_ERR_OVERFLOW); } if (isr & ADC_ISR_AWD1) { /* Analog watchdog error.*/ _adc_isr_error_code(adcp, ADC_ERR_AWD1); } if (isr & ADC_ISR_AWD2) { /* Analog watchdog error.*/ _adc_isr_error_code(adcp, ADC_ERR_AWD2); } if (isr & ADC_ISR_AWD3) { /* Analog watchdog error.*/ _adc_isr_error_code(adcp, ADC_ERR_AWD3); } } } /*===========================================================================*/ /* Driver interrupt handlers. */ /*===========================================================================*/ #if STM32_ADC_USE_ADC1 || defined(__DOXYGEN__) /** * @brief ADC1/ADC2 interrupt handler. * * @isr */ CH_IRQ_HANDLER(Vector88) { uint32_t isr; CH_IRQ_PROLOGUE(); #if STM32_ADC_DUAL_MODE isr = ADC1->ISR; isr |= ADC2->ISR; ADC1->ISR = isr; ADC2->ISR = isr; #else /* !STM32_ADC_DUAL_MODE */ isr = ADC1->ISR; ADC1->ISR = isr; #endif /* !STM32_ADC_DUAL_MODE */ adc_lld_serve_interrupt(&ADCD1, isr); CH_IRQ_EPILOGUE(); } #endif /* STM32_ADC_USE_ADC1 */ #if STM32_ADC_USE_ADC3 || defined(__DOXYGEN__) /** * @brief ADC3 interrupt handler. * * @isr */ CH_IRQ_HANDLER(VectorFC) { uint32_t isr; CH_IRQ_PROLOGUE(); isr = ADC3->ISR; ADC3->ISR = isr; adc_lld_serve_interrupt(&ADCD3, isr); CH_IRQ_EPILOGUE(); } #if STM32_ADC_DUAL_MODE /** * @brief ADC4 interrupt handler (as ADC3 slave). * * @isr */ CH_IRQ_HANDLER(Vector134) { uint32_t isr; CH_IRQ_PROLOGUE(); isr = ADC4->ISR; ADC4->ISR = isr; adc_lld_serve_interrupt(&ADCD3, isr); CH_IRQ_EPILOGUE(); } #endif /* STM32_ADC_DUAL_MODE */ #endif /* STM32_ADC_USE_ADC3 */ /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief Low level ADC driver initialization. * * @notapi */ void adc_lld_init(void) { #if STM32_ADC_USE_ADC1 /* Driver initialization.*/ adcObjectInit(&ADCD1); ADCD1.adcc = ADC1_2; ADCD1.adcm = ADC1; #if STM32_ADC_DUAL_MODE ADCD1.adcs = ADC2; #endif ADCD1.dmastp = STM32_DMA1_STREAM1; ADCD1.dmamode = ADC_DMA_SIZE | STM32_DMA_CR_PL(STM32_ADC_ADC12_DMA_PRIORITY) | STM32_DMA_CR_DIR_P2M | STM32_DMA_CR_MINC | STM32_DMA_CR_TCIE | STM32_DMA_CR_DMEIE | STM32_DMA_CR_TEIE; nvicEnableVector(ADC1_2_IRQn, CORTEX_PRIORITY_MASK(STM32_ADC_ADC12_IRQ_PRIORITY)); #endif /* STM32_ADC_USE_ADC1 */ #if STM32_ADC_USE_ADC3 /* Driver initialization.*/ adcObjectInit(&ADCD1); ADCD3.adcc = ADC3_4; ADCD3.adcm = ADC3; #if STM32_ADC_DUAL_MODE ADCD3.adcs = ADC4; #endif ADCD3.dmastp = STM32_DMA2_STREAM5; ADCD3.dmamode = ADC_DMA_SIZE | STM32_DMA_CR_PL(STM32_ADC_ADC12_DMA_PRIORITY) | STM32_DMA_CR_DIR_P2M | STM32_DMA_CR_MINC | STM32_DMA_CR_TCIE | STM32_DMA_CR_DMEIE | STM32_DMA_CR_TEIE; nvicEnableVector(ADC3_IRQn, CORTEX_PRIORITY_MASK(STM32_ADC_ADC34_IRQ_PRIORITY)); #if STM32_ADC_DUAL_MODE nvicEnableVector(ADC4_IRQn, CORTEX_PRIORITY_MASK(STM32_ADC_ADC34_IRQ_PRIORITY)); #endif #endif /* STM32_ADC_USE_ADC3 */ } /** * @brief Configures and activates the ADC peripheral. * * @param[in] adcp pointer to the @p ADCDriver object * * @notapi */ void adc_lld_start(ADCDriver *adcp) { /* If in stopped state then enables the ADC and DMA clocks.*/ if (adcp->state == ADC_STOP) { #if STM32_ADC_USE_ADC1 if (&ADCD1 == adcp) { bool_t b; b = dmaStreamAllocate(adcp->dmastp, STM32_ADC_ADC12_DMA_IRQ_PRIORITY, (stm32_dmaisr_t)adc_lld_serve_dma_interrupt, (void *)adcp); chDbgAssert(!b, "adc_lld_start(), #1", "stream already allocated"); rccEnableADC12(FALSE); } #endif /* STM32_ADC_USE_ADC1 */ #if STM32_ADC_USE_ADC3 if (&ADCD3 == adcp) { bool_t b; b = dmaStreamAllocate(adcp->dmastp, STM32_ADC_ADC34_DMA_IRQ_PRIORITY, (stm32_dmaisr_t)adc_lld_serve_dma_interrupt, (void *)adcp); chDbgAssert(!b, "adc_lld_start(), #2", "stream already allocated"); rccEnableADC34(FALSE); } #endif /* STM32_ADC_USE_ADC2 */ /* Setting DMA peripheral-side pointer.*/ #if STM32_ADC_DUAL_MODE dmaStreamSetPeripheral(adcp->dmastp, &adcp->adcc->CDR); #else dmaStreamSetPeripheral(adcp->dmastp, &adcp->adcm->DR); #endif /* Clock source setting.*/ adcp->adcc->CCR = STM32_ADC_ADC12_CLOCK_MODE | ADC_DMA_MDMA; /* Master ADC calibration.*/ adc_lld_vreg_on(adcp); adc_lld_calibrate(adcp); /* Master ADC enabled here in order to reduce conversions latencies.*/ adc_lld_analog_on(adcp); } } /** * @brief Deactivates the ADC peripheral. * * @param[in] adcp pointer to the @p ADCDriver object * * @notapi */ void adc_lld_stop(ADCDriver *adcp) { /* If in ready state then disables the ADC clock and analog part.*/ if (adcp->state == ADC_READY) { /* Releasing the associated DMA channel.*/ dmaStreamRelease(adcp->dmastp); /* Stopping the ongoing conversion, if any.*/ adc_lld_stop_adc(adcp); /* Disabling ADC analog circuit and regulator.*/ adc_lld_analog_off(adcp); adc_lld_vreg_off(adcp); #if STM32_ADC_USE_ADC1 if (&ADCD1 == adcp) rccDisableADC12(FALSE); #endif #if STM32_ADC_USE_ADC3 if (&ADCD1 == adcp) rccDisableADC34(FALSE); #endif } } /** * @brief Starts an ADC conversion. * * @param[in] adcp pointer to the @p ADCDriver object * * @notapi */ void adc_lld_start_conversion(ADCDriver *adcp) { uint32_t dmamode, ccr, cfgr; const ADCConversionGroup *grpp = adcp->grpp; chDbgAssert(!STM32_ADC_DUAL_MODE || ((grpp->num_channels & 1) == 0), "adc_lld_start_conversion(), #1", "odd number of channels in dual mode"); /* Calculating control registers values.*/ dmamode = adcp->dmamode; ccr = grpp->ccr | (adcp->adcc->CCR & (ADC_CCR_CKMODE_MASK | ADC_CCR_MDMA_MASK)); cfgr = grpp->cfgr | ADC_CFGR_CONT | ADC_CFGR_DMAEN; if (grpp->circular) { dmamode |= STM32_DMA_CR_CIRC; #if STM32_ADC_DUAL_MODE ccr |= ADC_CCR_DMACFG_CIRCULAR; #else cfgr |= ADC_CFGR_DMACFG_CIRCULAR; #endif } /* DMA setup.*/ if (adcp->depth > 1) { /* If the buffer depth is greater than one then the half transfer interrupt interrupt is enabled in order to allows streaming processing.*/ dmamode |= STM32_DMA_CR_HTIE; } dmaStreamSetMemory0(adcp->dmastp, adcp->samples); #if STM32_ADC_DUAL_MODE dmaStreamSetTransactionSize(adcp->dmastp, ((uint32_t)grpp->num_channels/2) * (uint32_t)adcp->depth); #else dmaStreamSetTransactionSize(adcp->dmastp, (uint32_t)grpp->num_channels * (uint32_t)adcp->depth); #endif dmaStreamSetMode(adcp->dmastp, dmamode); dmaStreamEnable(adcp->dmastp); /* Configuring the CCR register with the static settings ORed with the user-specified settings in the conversion group configuration structure.*/ adcp->adcc->CCR = ccr; /* ADC setup, if it is defined a callback for the analog watch dog then it is enabled.*/ adcp->adcm->ISR = adcp->adcm->ISR; adcp->adcm->IER = ADC_IER_OVR | ADC_IER_AWD1; adcp->adcm->TR1 = grpp->tr1; #if STM32_ADC_DUAL_MODE adcp->adcm->SMPR1 = grpp->smpr[0]; adcp->adcm->SMPR2 = grpp->smpr[1]; adcp->adcm->SQR1 = grpp->sqr[0] | ADC_SQR1_NUM_CH(grpp->num_channels / 2); adcp->adcm->SQR2 = grpp->sqr[1]; adcp->adcm->SQR3 = grpp->sqr[2]; adcp->adcm->SQR4 = grpp->sqr[3]; adcp->adcs->SMPR1 = grpp->ssmpr[0]; adcp->adcs->SMPR2 = grpp->ssmpr[1]; adcp->adcs->SQR1 = grpp->ssqr[0] | ADC_SQR1_NUM_CH(grpp->num_channels / 2); adcp->adcs->SQR2 = grpp->ssqr[1]; adcp->adcs->SQR3 = grpp->ssqr[2]; adcp->adcs->SQR4 = grpp->ssqr[3]; #else /* !STM32_ADC_DUAL_MODE */ adcp->adcm->SMPR1 = grpp->smpr[0]; adcp->adcm->SMPR2 = grpp->smpr[1]; adcp->adcm->SQR1 = grpp->sqr[0] | ADC_SQR1_NUM_CH(grpp->num_channels); adcp->adcm->SQR2 = grpp->sqr[1]; adcp->adcm->SQR3 = grpp->sqr[2]; adcp->adcm->SQR4 = grpp->sqr[3]; #endif /* !STM32_ADC_DUAL_MODE */ /* ADC configuration.*/ adcp->adcm->CFGR = cfgr; /* Starting conversion.*/ adcp->adcm->CR |= ADC_CR_ADSTART; } /** * @brief Stops an ongoing conversion. * * @param[in] adcp pointer to the @p ADCDriver object * * @notapi */ void adc_lld_stop_conversion(ADCDriver *adcp) { dmaStreamDisable(adcp->dmastp); adc_lld_stop_adc(adcp); } #endif /* HAL_USE_ADC */ /** @} */