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1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287 1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332 1333 1334 1335 1336 1337 1338 1339 1340 1341 1342 1343 1344 1345 1346 1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366 1367 1368 1369 1370 1371 1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385 1386 1387 1388 1389 1390 1391 1392 1393 1394 1395 1396 1397 1398 1399 1400 1401 1402 1403 1404 1405 1406 1407 | /* * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016-2017 NXP * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * o Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "fsl_flexcan.h" /******************************************************************************* * Definitons ******************************************************************************/ #define FLEXCAN_TIME_QUANTA_NUM (10) /*! @brief FlexCAN Internal State. */ enum _flexcan_state { kFLEXCAN_StateIdle = 0x0, /*!< MB/RxFIFO idle.*/ kFLEXCAN_StateRxData = 0x1, /*!< MB receiving.*/ kFLEXCAN_StateRxRemote = 0x2, /*!< MB receiving remote reply.*/ kFLEXCAN_StateTxData = 0x3, /*!< MB transmitting.*/ kFLEXCAN_StateTxRemote = 0x4, /*!< MB transmitting remote request.*/ kFLEXCAN_StateRxFifo = 0x5, /*!< RxFIFO receiving.*/ }; /*! @brief FlexCAN message buffer CODE for Rx buffers. */ enum _flexcan_mb_code_rx { kFLEXCAN_RxMbInactive = 0x0, /*!< MB is not active.*/ kFLEXCAN_RxMbFull = 0x2, /*!< MB is full.*/ kFLEXCAN_RxMbEmpty = 0x4, /*!< MB is active and empty.*/ kFLEXCAN_RxMbOverrun = 0x6, /*!< MB is overwritten into a full buffer.*/ kFLEXCAN_RxMbBusy = 0x8, /*!< FlexCAN is updating the contents of the MB.*/ /*! The CPU must not access the MB.*/ kFLEXCAN_RxMbRanswer = 0xA, /*!< A frame was configured to recognize a Remote Request Frame */ /*! and transmit a Response Frame in return.*/ kFLEXCAN_RxMbNotUsed = 0xF, /*!< Not used.*/ }; /*! @brief FlexCAN message buffer CODE FOR Tx buffers. */ enum _flexcan_mb_code_tx { kFLEXCAN_TxMbInactive = 0x8, /*!< MB is not active.*/ kFLEXCAN_TxMbAbort = 0x9, /*!< MB is aborted.*/ kFLEXCAN_TxMbDataOrRemote = 0xC, /*!< MB is a TX Data Frame(when MB RTR = 0) or */ /*!< MB is a TX Remote Request Frame (when MB RTR = 1).*/ kFLEXCAN_TxMbTanswer = 0xE, /*!< MB is a TX Response Request Frame from */ /*! an incoming Remote Request Frame.*/ kFLEXCAN_TxMbNotUsed = 0xF, /*!< Not used.*/ }; /* Typedef for interrupt handler. */ typedef void (*flexcan_isr_t)(CAN_Type *base, flexcan_handle_t *handle); /******************************************************************************* * Prototypes ******************************************************************************/ /*! * @brief Get the FlexCAN instance from peripheral base address. * * @param base FlexCAN peripheral base address. * @return FlexCAN instance. */ uint32_t FLEXCAN_GetInstance(CAN_Type *base); /*! * @brief Enter FlexCAN Freeze Mode. * * This function makes the FlexCAN work under Freeze Mode. * * @param base FlexCAN peripheral base address. */ static void FLEXCAN_EnterFreezeMode(CAN_Type *base); /*! * @brief Exit FlexCAN Freeze Mode. * * This function makes the FlexCAN leave Freeze Mode. * * @param base FlexCAN peripheral base address. */ static void FLEXCAN_ExitFreezeMode(CAN_Type *base); #if !defined(NDEBUG) /*! * @brief Check if Message Buffer is occupied by Rx FIFO. * * This function check if Message Buffer is occupied by Rx FIFO. * * @param base FlexCAN peripheral base address. * @param mbIdx The FlexCAN Message Buffer index. */ static bool FLEXCAN_IsMbOccupied(CAN_Type *base, uint8_t mbIdx); #endif #if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) /*! * @brief Get the first valid Message buffer ID of give FlexCAN instance. * * This function is a helper function for Errata 5641 workaround. * * @param base FlexCAN peripheral base address. * @return The first valid Message Buffer Number. */ static uint32_t FLEXCAN_GetFirstValidMb(CAN_Type *base); #endif /*! * @brief Check if Message Buffer interrupt is enabled. * * This function check if Message Buffer interrupt is enabled. * * @param base FlexCAN peripheral base address. * @param mbIdx The FlexCAN Message Buffer index. */ static bool FLEXCAN_IsMbIntEnabled(CAN_Type *base, uint8_t mbIdx); /*! * @brief Reset the FlexCAN Instance. * * Restores the FlexCAN module to reset state, notice that this function * will set all the registers to reset state so the FlexCAN module can not work * after calling this API. * * @param base FlexCAN peripheral base address. */ static void FLEXCAN_Reset(CAN_Type *base); /*! * @brief Set Baud Rate of FlexCAN. * * This function set the baud rate of FlexCAN. * * @param base FlexCAN peripheral base address. * @param sourceClock_Hz Source Clock in Hz. * @param baudRate_Bps Baud Rate in Bps. */ static void FLEXCAN_SetBaudRate(CAN_Type *base, uint32_t sourceClock_Hz, uint32_t baudRate_Bps); /******************************************************************************* * Variables ******************************************************************************/ /* Array of FlexCAN peripheral base address. */ static CAN_Type *const s_flexcanBases[] = CAN_BASE_PTRS; /* Array of FlexCAN IRQ number. */ static const IRQn_Type s_flexcanRxWarningIRQ[] = CAN_Rx_Warning_IRQS; static const IRQn_Type s_flexcanTxWarningIRQ[] = CAN_Tx_Warning_IRQS; static const IRQn_Type s_flexcanWakeUpIRQ[] = CAN_Wake_Up_IRQS; static const IRQn_Type s_flexcanErrorIRQ[] = CAN_Error_IRQS; static const IRQn_Type s_flexcanBusOffIRQ[] = CAN_Bus_Off_IRQS; static const IRQn_Type s_flexcanMbIRQ[] = CAN_ORed_Message_buffer_IRQS; /* Array of FlexCAN handle. */ static flexcan_handle_t *s_flexcanHandle[ARRAY_SIZE(s_flexcanBases)]; #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) /* Array of FlexCAN clock name. */ static const clock_ip_name_t s_flexcanClock[] = FLEXCAN_CLOCKS; #if defined(FLEXCAN_PERIPH_CLOCKS) /* Array of FlexCAN serial clock name. */ static const clock_ip_name_t s_flexcanPeriphClock[] = FLEXCAN_PERIPH_CLOCKS; #endif /* FLEXCAN_PERIPH_CLOCKS */ #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ /* FlexCAN ISR for transactional APIs. */ static flexcan_isr_t s_flexcanIsr; /******************************************************************************* * Code ******************************************************************************/ uint32_t FLEXCAN_GetInstance(CAN_Type *base) { uint32_t instance; /* Find the instance index from base address mappings. */ for (instance = 0; instance < ARRAY_SIZE(s_flexcanBases); instance++) { if (s_flexcanBases[instance] == base) { break; } } assert(instance < ARRAY_SIZE(s_flexcanBases)); return instance; } static void FLEXCAN_EnterFreezeMode(CAN_Type *base) { /* Set Freeze, Halt bits. */ base->MCR |= CAN_MCR_HALT_MASK; /* Wait until the FlexCAN Module enter freeze mode. */ while (!(base->MCR & CAN_MCR_FRZACK_MASK)) { } } static void FLEXCAN_ExitFreezeMode(CAN_Type *base) { /* Clear Freeze, Halt bits. */ base->MCR &= ~CAN_MCR_HALT_MASK; /* Wait until the FlexCAN Module exit freeze mode. */ while (base->MCR & CAN_MCR_FRZACK_MASK) { } } #if !defined(NDEBUG) static bool FLEXCAN_IsMbOccupied(CAN_Type *base, uint8_t mbIdx) { uint8_t lastOccupiedMb; /* Is Rx FIFO enabled? */ if (base->MCR & CAN_MCR_RFEN_MASK) { /* Get RFFN value. */ lastOccupiedMb = ((base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT); /* Calculate the number of last Message Buffer occupied by Rx FIFO. */ lastOccupiedMb = ((lastOccupiedMb + 1) * 2) + 5; #if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) if (mbIdx <= (lastOccupiedMb + 1)) #else if (mbIdx <= lastOccupiedMb) #endif { return true; } else { return false; } } else { #if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) if (0 == mbIdx) { return true; } else { return false; } #else return false; #endif } } #endif #if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) static uint32_t FLEXCAN_GetFirstValidMb(CAN_Type *base) { uint32_t firstValidMbNum; if (base->MCR & CAN_MCR_RFEN_MASK) { firstValidMbNum = ((base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT); firstValidMbNum = ((firstValidMbNum + 1) * 2) + 6; } else { firstValidMbNum = 0; } return firstValidMbNum; } #endif static bool FLEXCAN_IsMbIntEnabled(CAN_Type *base, uint8_t mbIdx) { /* Assertion. */ assert(mbIdx < FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base)); #if (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0) if (mbIdx < 32) { #endif if (base->IMASK1 & ((uint32_t)(1 << mbIdx))) { return true; } else { return false; } #if (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0) } else { if (base->IMASK2 & ((uint32_t)(1 << (mbIdx - 32)))) { return true; } else { return false; } } #endif } static void FLEXCAN_Reset(CAN_Type *base) { /* The module must should be first exit from low power * mode, and then soft reset can be applied. */ assert(!(base->MCR & CAN_MCR_MDIS_MASK)); uint8_t i; #if (FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT != 0) /* De-assert DOZE Enable Bit. */ base->MCR &= ~CAN_MCR_DOZE_MASK; #endif /* Wait until FlexCAN exit from any Low Power Mode. */ while (base->MCR & CAN_MCR_LPMACK_MASK) { } /* Assert Soft Reset Signal. */ base->MCR |= CAN_MCR_SOFTRST_MASK; /* Wait until FlexCAN reset completes. */ while (base->MCR & CAN_MCR_SOFTRST_MASK) { } /* Reset MCR rigister. */ #if (defined(FSL_FEATURE_FLEXCAN_HAS_GLITCH_FILTER) && FSL_FEATURE_FLEXCAN_HAS_GLITCH_FILTER) base->MCR |= CAN_MCR_WRNEN_MASK | CAN_MCR_WAKSRC_MASK | CAN_MCR_MAXMB(FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base) - 1); #else base->MCR |= CAN_MCR_WRNEN_MASK | CAN_MCR_MAXMB(FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base) - 1); #endif /* Reset CTRL1 and CTRL2 rigister. */ base->CTRL1 = CAN_CTRL1_SMP_MASK; base->CTRL2 = CAN_CTRL2_TASD(0x16) | CAN_CTRL2_RRS_MASK | CAN_CTRL2_EACEN_MASK; /* Clean all individual Rx Mask of Message Buffers. */ for (i = 0; i < FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); i++) { base->RXIMR[i] = 0x3FFFFFFF; } /* Clean Global Mask of Message Buffers. */ base->RXMGMASK = 0x3FFFFFFF; /* Clean Global Mask of Message Buffer 14. */ base->RX14MASK = 0x3FFFFFFF; /* Clean Global Mask of Message Buffer 15. */ base->RX15MASK = 0x3FFFFFFF; /* Clean Global Mask of Rx FIFO. */ base->RXFGMASK = 0x3FFFFFFF; /* Clean all Message Buffer CS fields. */ for (i = 0; i < FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); i++) { base->MB[i].CS = 0x0; } } static void FLEXCAN_SetBaudRate(CAN_Type *base, uint32_t sourceClock_Hz, uint32_t baudRate_Bps) { flexcan_timing_config_t timingConfig; uint32_t priDiv = baudRate_Bps * FLEXCAN_TIME_QUANTA_NUM; /* Assertion: Desired baud rate is too high. */ assert(baudRate_Bps <= 1000000U); /* Assertion: Source clock should greater than baud rate * FLEXCAN_TIME_QUANTA_NUM. */ assert(priDiv <= sourceClock_Hz); if (0 == priDiv) { priDiv = 1; } priDiv = (sourceClock_Hz / priDiv) - 1; /* Desired baud rate is too low. */ if (priDiv > 0xFF) { priDiv = 0xFF; } /* FlexCAN timing setting formula: * FLEXCAN_TIME_QUANTA_NUM = 1 + (PSEG1 + 1) + (PSEG2 + 1) + (PROPSEG + 1); */ timingConfig.preDivider = priDiv; timingConfig.phaseSeg1 = 3; timingConfig.phaseSeg2 = 2; timingConfig.propSeg = 1; timingConfig.rJumpwidth = 1; /* Update actual timing characteristic. */ FLEXCAN_SetTimingConfig(base, &timingConfig); } void FLEXCAN_Init(CAN_Type *base, const flexcan_config_t *config, uint32_t sourceClock_Hz) { uint32_t mcrTemp; #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) uint32_t instance; #endif /* Assertion. */ assert(config); assert((config->maxMbNum > 0) && (config->maxMbNum <= FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base))); #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) instance = FLEXCAN_GetInstance(base); /* Enable FlexCAN clock. */ CLOCK_EnableClock(s_flexcanClock[instance]); #if defined(FLEXCAN_PERIPH_CLOCKS) /* Enable FlexCAN serial clock. */ CLOCK_EnableClock(s_flexcanPeriphClock[instance]); #endif /* FLEXCAN_PERIPH_CLOCKS */ #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ #if (!defined(FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE)) || !FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE /* Disable FlexCAN Module. */ FLEXCAN_Enable(base, false); /* Protocol-Engine clock source selection, This bit must be set * when FlexCAN Module in Disable Mode. */ base->CTRL1 = (kFLEXCAN_ClkSrcOsc == config->clkSrc) ? base->CTRL1 & ~CAN_CTRL1_CLKSRC_MASK : base->CTRL1 | CAN_CTRL1_CLKSRC_MASK; #endif /* FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE */ /* Enable FlexCAN Module for configuartion. */ FLEXCAN_Enable(base, true); /* Reset to known status. */ FLEXCAN_Reset(base); /* Save current MCR value and enable to enter Freeze mode(enabled by default). */ mcrTemp = base->MCR; /* Set the maximum number of Message Buffers */ mcrTemp = (mcrTemp & ~CAN_MCR_MAXMB_MASK) | CAN_MCR_MAXMB(config->maxMbNum - 1); /* Enable Loop Back Mode? */ base->CTRL1 = (config->enableLoopBack) ? base->CTRL1 | CAN_CTRL1_LPB_MASK : base->CTRL1 & ~CAN_CTRL1_LPB_MASK; /* Enable Self Wake Up Mode? */ mcrTemp = (config->enableSelfWakeup) ? mcrTemp | CAN_MCR_SLFWAK_MASK : mcrTemp & ~CAN_MCR_SLFWAK_MASK; /* Enable Individual Rx Masking? */ mcrTemp = (config->enableIndividMask) ? mcrTemp | CAN_MCR_IRMQ_MASK : mcrTemp & ~CAN_MCR_IRMQ_MASK; #if (defined(FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) && FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) /* Enable Doze Mode? */ mcrTemp = (config->enableDoze) ? mcrTemp | CAN_MCR_DOZE_MASK : mcrTemp & ~CAN_MCR_DOZE_MASK; #endif /* Save MCR Configuation. */ base->MCR = mcrTemp; /* Baud Rate Configuration.*/ FLEXCAN_SetBaudRate(base, sourceClock_Hz, config->baudRate); } void FLEXCAN_Deinit(CAN_Type *base) { #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) uint32_t instance; #endif /* Reset all Register Contents. */ FLEXCAN_Reset(base); /* Disable FlexCAN module. */ FLEXCAN_Enable(base, false); #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) instance = FLEXCAN_GetInstance(base); #if defined(FLEXCAN_PERIPH_CLOCKS) /* Disable FlexCAN serial clock. */ CLOCK_DisableClock(s_flexcanPeriphClock[instance]); #endif /* FLEXCAN_PERIPH_CLOCKS */ /* Disable FlexCAN clock. */ CLOCK_DisableClock(s_flexcanClock[instance]); #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ } void FLEXCAN_GetDefaultConfig(flexcan_config_t *config) { /* Assertion. */ assert(config); /* Initialize FlexCAN Module config struct with default value. */ #if (!defined(FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE)) || !FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE config->clkSrc = kFLEXCAN_ClkSrcOsc; #endif /* FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE */ config->baudRate = 125000U; config->maxMbNum = 16; config->enableLoopBack = false; config->enableSelfWakeup = false; config->enableIndividMask = false; #if (defined(FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) && FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) config->enableDoze = false; #endif } void FLEXCAN_SetTimingConfig(CAN_Type *base, const flexcan_timing_config_t *config) { /* Assertion. */ assert(config); /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Cleaning previous Timing Setting. */ base->CTRL1 &= ~(CAN_CTRL1_PRESDIV_MASK | CAN_CTRL1_RJW_MASK | CAN_CTRL1_PSEG1_MASK | CAN_CTRL1_PSEG2_MASK | CAN_CTRL1_PROPSEG_MASK); /* Updating Timing Setting according to configuration structure. */ base->CTRL1 |= (CAN_CTRL1_PRESDIV(config->preDivider) | CAN_CTRL1_RJW(config->rJumpwidth) | CAN_CTRL1_PSEG1(config->phaseSeg1) | CAN_CTRL1_PSEG2(config->phaseSeg2) | CAN_CTRL1_PROPSEG(config->propSeg)); /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } void FLEXCAN_SetRxMbGlobalMask(CAN_Type *base, uint32_t mask) { /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Setting Rx Message Buffer Global Mask value. */ base->RXMGMASK = mask; base->RX14MASK = mask; base->RX15MASK = mask; /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } void FLEXCAN_SetRxFifoGlobalMask(CAN_Type *base, uint32_t mask) { /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Setting Rx FIFO Global Mask value. */ base->RXFGMASK = mask; /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } void FLEXCAN_SetRxIndividualMask(CAN_Type *base, uint8_t maskIdx, uint32_t mask) { assert(maskIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Setting Rx Individual Mask value. */ base->RXIMR[maskIdx] = mask; /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } void FLEXCAN_SetTxMbConfig(CAN_Type *base, uint8_t mbIdx, bool enable) { /* Assertion. */ assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); /* Inactivate Message Buffer. */ if (enable) { base->MB[mbIdx].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive); } else { base->MB[mbIdx].CS = 0; } /* Clean Message Buffer content. */ base->MB[mbIdx].ID = 0x0; base->MB[mbIdx].WORD0 = 0x0; base->MB[mbIdx].WORD1 = 0x0; } void FLEXCAN_SetRxMbConfig(CAN_Type *base, uint8_t mbIdx, const flexcan_rx_mb_config_t *config, bool enable) { /* Assertion. */ assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(((config) || (false == enable))); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); uint32_t cs_temp = 0; /* Inactivate Message Buffer. */ base->MB[mbIdx].CS = 0; /* Clean Message Buffer content. */ base->MB[mbIdx].ID = 0x0; base->MB[mbIdx].WORD0 = 0x0; base->MB[mbIdx].WORD1 = 0x0; if (enable) { /* Setup Message Buffer ID. */ base->MB[mbIdx].ID = config->id; /* Setup Message Buffer format. */ if (kFLEXCAN_FrameFormatExtend == config->format) { cs_temp |= CAN_CS_IDE_MASK; } /* Setup Message Buffer type. */ if (kFLEXCAN_FrameTypeRemote == config->type) { cs_temp |= CAN_CS_RTR_MASK; } /* Activate Rx Message Buffer. */ cs_temp |= CAN_CS_CODE(kFLEXCAN_RxMbEmpty); base->MB[mbIdx].CS = cs_temp; } } void FLEXCAN_SetRxFifoConfig(CAN_Type *base, const flexcan_rx_fifo_config_t *config, bool enable) { /* Assertion. */ assert((config) || (false == enable)); volatile uint32_t *idFilterRegion = (volatile uint32_t *)(&base->MB[6].CS); uint8_t setup_mb, i, rffn = 0; /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); if (enable) { assert(config->idFilterNum <= 128); /* Get the setup_mb value. */ setup_mb = (base->MCR & CAN_MCR_MAXMB_MASK) >> CAN_MCR_MAXMB_SHIFT; setup_mb = (setup_mb < FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base)) ? setup_mb : FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); /* Determine RFFN value. */ for (i = 0; i <= 0xF; i++) { if ((8 * (i + 1)) >= config->idFilterNum) { rffn = i; assert(((setup_mb - 8) - (2 * rffn)) > 0); base->CTRL2 = (base->CTRL2 & ~CAN_CTRL2_RFFN_MASK) | CAN_CTRL2_RFFN(rffn); break; } } } else { rffn = (base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT; } /* Clean ID filter table occuyied Message Buffer Region. */ rffn = (rffn + 1) * 8; for (i = 0; i < rffn; i++) { idFilterRegion[i] = 0x0; } if (enable) { /* Disable unused Rx FIFO Filter. */ for (i = config->idFilterNum; i < rffn; i++) { idFilterRegion[i] = 0xFFFFFFFFU; } /* Copy ID filter table to Message Buffer Region. */ for (i = 0; i < config->idFilterNum; i++) { idFilterRegion[i] = config->idFilterTable[i]; } /* Setup ID Fitlter Type. */ switch (config->idFilterType) { case kFLEXCAN_RxFifoFilterTypeA: base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x0); break; case kFLEXCAN_RxFifoFilterTypeB: base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x1); break; case kFLEXCAN_RxFifoFilterTypeC: base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x2); break; case kFLEXCAN_RxFifoFilterTypeD: /* All frames rejected. */ base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x3); break; default: break; } /* Setting Message Reception Priority. */ base->CTRL2 = (config->priority == kFLEXCAN_RxFifoPrioHigh) ? base->CTRL2 & ~CAN_CTRL2_MRP_MASK : base->CTRL2 | CAN_CTRL2_MRP_MASK; /* Enable Rx Message FIFO. */ base->MCR |= CAN_MCR_RFEN_MASK; } else { /* Disable Rx Message FIFO. */ base->MCR &= ~CAN_MCR_RFEN_MASK; /* Clean MB0 ~ MB5. */ FLEXCAN_SetRxMbConfig(base, 0, NULL, false); FLEXCAN_SetRxMbConfig(base, 1, NULL, false); FLEXCAN_SetRxMbConfig(base, 2, NULL, false); FLEXCAN_SetRxMbConfig(base, 3, NULL, false); FLEXCAN_SetRxMbConfig(base, 4, NULL, false); FLEXCAN_SetRxMbConfig(base, 5, NULL, false); } /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } #if (defined(FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA) && FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA) void FLEXCAN_EnableRxFifoDMA(CAN_Type *base, bool enable) { if (enable) { /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Enable FlexCAN DMA. */ base->MCR |= CAN_MCR_DMA_MASK; /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } else { /* Enter Freeze Mode. */ FLEXCAN_EnterFreezeMode(base); /* Disable FlexCAN DMA. */ base->MCR &= ~CAN_MCR_DMA_MASK; /* Exit Freeze Mode. */ FLEXCAN_ExitFreezeMode(base); } } #endif /* FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA */ status_t FLEXCAN_WriteTxMb(CAN_Type *base, uint8_t mbIdx, const flexcan_frame_t *txFrame) { /* Assertion. */ assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(txFrame); assert(txFrame->length <= 8); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); uint32_t cs_temp = 0; /* Check if Message Buffer is available. */ if (CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) != (base->MB[mbIdx].CS & CAN_CS_CODE_MASK)) { /* Inactive Tx Message Buffer. */ base->MB[mbIdx].CS = (base->MB[mbIdx].CS & ~CAN_CS_CODE_MASK) | CAN_CS_CODE(kFLEXCAN_TxMbInactive); /* Fill Message ID field. */ base->MB[mbIdx].ID = txFrame->id; /* Fill Message Format field. */ if (kFLEXCAN_FrameFormatExtend == txFrame->format) { cs_temp |= CAN_CS_SRR_MASK | CAN_CS_IDE_MASK; } /* Fill Message Type field. */ if (kFLEXCAN_FrameTypeRemote == txFrame->type) { cs_temp |= CAN_CS_RTR_MASK; } cs_temp |= CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) | CAN_CS_DLC(txFrame->length); /* Load Message Payload. */ base->MB[mbIdx].WORD0 = txFrame->dataWord0; base->MB[mbIdx].WORD1 = txFrame->dataWord1; /* Activate Tx Message Buffer. */ base->MB[mbIdx].CS = cs_temp; #if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) base->MB[FLEXCAN_GetFirstValidMb(base)].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive); base->MB[FLEXCAN_GetFirstValidMb(base)].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive); #endif return kStatus_Success; } else { /* Tx Message Buffer is activated, return immediately. */ return kStatus_Fail; } } status_t FLEXCAN_ReadRxMb(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *rxFrame) { /* Assertion. */ assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(rxFrame); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); uint32_t cs_temp; uint8_t rx_code; /* Read CS field of Rx Message Buffer to lock Message Buffer. */ cs_temp = base->MB[mbIdx].CS; /* Get Rx Message Buffer Code field. */ rx_code = (cs_temp & CAN_CS_CODE_MASK) >> CAN_CS_CODE_SHIFT; /* Check to see if Rx Message Buffer is full. */ if ((kFLEXCAN_RxMbFull == rx_code) || (kFLEXCAN_RxMbOverrun == rx_code)) { /* Store Message ID. */ rxFrame->id = base->MB[mbIdx].ID & (CAN_ID_EXT_MASK | CAN_ID_STD_MASK); /* Get the message ID and format. */ rxFrame->format = (cs_temp & CAN_CS_IDE_MASK) ? kFLEXCAN_FrameFormatExtend : kFLEXCAN_FrameFormatStandard; /* Get the message type. */ rxFrame->type = (cs_temp & CAN_CS_RTR_MASK) ? kFLEXCAN_FrameTypeRemote : kFLEXCAN_FrameTypeData; /* Get the message length. */ rxFrame->length = (cs_temp & CAN_CS_DLC_MASK) >> CAN_CS_DLC_SHIFT; /* Store Message Payload. */ rxFrame->dataWord0 = base->MB[mbIdx].WORD0; rxFrame->dataWord1 = base->MB[mbIdx].WORD1; /* Read free-running timer to unlock Rx Message Buffer. */ (void)base->TIMER; if (kFLEXCAN_RxMbFull == rx_code) { return kStatus_Success; } else { return kStatus_FLEXCAN_RxOverflow; } } else { /* Read free-running timer to unlock Rx Message Buffer. */ (void)base->TIMER; return kStatus_Fail; } } status_t FLEXCAN_ReadRxFifo(CAN_Type *base, flexcan_frame_t *rxFrame) { /* Assertion. */ assert(rxFrame); uint32_t cs_temp; /* Check if Rx FIFO is Enabled. */ if (base->MCR & CAN_MCR_RFEN_MASK) { /* Read CS field of Rx Message Buffer to lock Message Buffer. */ cs_temp = base->MB[0].CS; /* Read data from Rx FIFO output port. */ /* Store Message ID. */ rxFrame->id = base->MB[0].ID & (CAN_ID_EXT_MASK | CAN_ID_STD_MASK); /* Get the message ID and format. */ rxFrame->format = (cs_temp & CAN_CS_IDE_MASK) ? kFLEXCAN_FrameFormatExtend : kFLEXCAN_FrameFormatStandard; /* Get the message type. */ rxFrame->type = (cs_temp & CAN_CS_RTR_MASK) ? kFLEXCAN_FrameTypeRemote : kFLEXCAN_FrameTypeData; /* Get the message length. */ rxFrame->length = (cs_temp & CAN_CS_DLC_MASK) >> CAN_CS_DLC_SHIFT; /* Store Message Payload. */ rxFrame->dataWord0 = base->MB[0].WORD0; rxFrame->dataWord1 = base->MB[0].WORD1; /* Store ID Filter Hit Index. */ rxFrame->idhit = (uint8_t)(base->RXFIR & CAN_RXFIR_IDHIT_MASK); /* Read free-running timer to unlock Rx Message Buffer. */ (void)base->TIMER; return kStatus_Success; } else { return kStatus_Fail; } } status_t FLEXCAN_TransferSendBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *txFrame) { /* Write Tx Message Buffer to initiate a data sending. */ if (kStatus_Success == FLEXCAN_WriteTxMb(base, mbIdx, txFrame)) { /* Wait until CAN Message send out. */ while (!FLEXCAN_GetMbStatusFlags(base, 1 << mbIdx)) { } /* Clean Tx Message Buffer Flag. */ FLEXCAN_ClearMbStatusFlags(base, 1 << mbIdx); return kStatus_Success; } else { return kStatus_Fail; } } status_t FLEXCAN_TransferReceiveBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *rxFrame) { /* Wait until Rx Message Buffer non-empty. */ while (!FLEXCAN_GetMbStatusFlags(base, 1 << mbIdx)) { } /* Clean Rx Message Buffer Flag. */ FLEXCAN_ClearMbStatusFlags(base, 1 << mbIdx); /* Read Received CAN Message. */ return FLEXCAN_ReadRxMb(base, mbIdx, rxFrame); } status_t FLEXCAN_TransferReceiveFifoBlocking(CAN_Type *base, flexcan_frame_t *rxFrame) { status_t rxFifoStatus; /* Wait until Rx FIFO non-empty. */ while (!FLEXCAN_GetMbStatusFlags(base, kFLEXCAN_RxFifoFrameAvlFlag)) { } /* */ rxFifoStatus = FLEXCAN_ReadRxFifo(base, rxFrame); /* Clean Rx Fifo available flag. */ FLEXCAN_ClearMbStatusFlags(base, kFLEXCAN_RxFifoFrameAvlFlag); return rxFifoStatus; } void FLEXCAN_TransferCreateHandle(CAN_Type *base, flexcan_handle_t *handle, flexcan_transfer_callback_t callback, void *userData) { assert(handle); uint8_t instance; /* Clean FlexCAN transfer handle. */ memset(handle, 0, sizeof(*handle)); /* Get instance from peripheral base address. */ instance = FLEXCAN_GetInstance(base); /* Save the context in global variables to support the double weak mechanism. */ s_flexcanHandle[instance] = handle; /* Register Callback function. */ handle->callback = callback; handle->userData = userData; s_flexcanIsr = FLEXCAN_TransferHandleIRQ; /* We Enable Error & Status interrupt here, because this interrupt just * report current status of FlexCAN module through Callback function. * It is insignificance without a available callback function. */ if (handle->callback != NULL) { FLEXCAN_EnableInterrupts(base, kFLEXCAN_BusOffInterruptEnable | kFLEXCAN_ErrorInterruptEnable | kFLEXCAN_RxWarningInterruptEnable | kFLEXCAN_TxWarningInterruptEnable | kFLEXCAN_WakeUpInterruptEnable); } else { FLEXCAN_DisableInterrupts(base, kFLEXCAN_BusOffInterruptEnable | kFLEXCAN_ErrorInterruptEnable | kFLEXCAN_RxWarningInterruptEnable | kFLEXCAN_TxWarningInterruptEnable | kFLEXCAN_WakeUpInterruptEnable); } /* Enable interrupts in NVIC. */ EnableIRQ((IRQn_Type)(s_flexcanRxWarningIRQ[instance])); EnableIRQ((IRQn_Type)(s_flexcanTxWarningIRQ[instance])); EnableIRQ((IRQn_Type)(s_flexcanWakeUpIRQ[instance])); EnableIRQ((IRQn_Type)(s_flexcanErrorIRQ[instance])); EnableIRQ((IRQn_Type)(s_flexcanBusOffIRQ[instance])); EnableIRQ((IRQn_Type)(s_flexcanMbIRQ[instance])); } status_t FLEXCAN_TransferSendNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *xfer) { /* Assertion. */ assert(handle); assert(xfer); assert(xfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(!FLEXCAN_IsMbOccupied(base, xfer->mbIdx)); /* Check if Message Buffer is idle. */ if (kFLEXCAN_StateIdle == handle->mbState[xfer->mbIdx]) { /* Distinguish transmit type. */ if (kFLEXCAN_FrameTypeRemote == xfer->frame->type) { handle->mbState[xfer->mbIdx] = kFLEXCAN_StateTxRemote; /* Register user Frame buffer to receive remote Frame. */ handle->mbFrameBuf[xfer->mbIdx] = xfer->frame; } else { handle->mbState[xfer->mbIdx] = kFLEXCAN_StateTxData; } if (kStatus_Success == FLEXCAN_WriteTxMb(base, xfer->mbIdx, xfer->frame)) { /* Enable Message Buffer Interrupt. */ FLEXCAN_EnableMbInterrupts(base, 1 << xfer->mbIdx); return kStatus_Success; } else { handle->mbState[xfer->mbIdx] = kFLEXCAN_StateIdle; return kStatus_Fail; } } else { return kStatus_FLEXCAN_TxBusy; } } status_t FLEXCAN_TransferReceiveNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *xfer) { /* Assertion. */ assert(handle); assert(xfer); assert(xfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(!FLEXCAN_IsMbOccupied(base, xfer->mbIdx)); /* Check if Message Buffer is idle. */ if (kFLEXCAN_StateIdle == handle->mbState[xfer->mbIdx]) { handle->mbState[xfer->mbIdx] = kFLEXCAN_StateRxData; /* Register Message Buffer. */ handle->mbFrameBuf[xfer->mbIdx] = xfer->frame; /* Enable Message Buffer Interrupt. */ FLEXCAN_EnableMbInterrupts(base, 1 << xfer->mbIdx); return kStatus_Success; } else { return kStatus_FLEXCAN_RxBusy; } } status_t FLEXCAN_TransferReceiveFifoNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_fifo_transfer_t *xfer) { /* Assertion. */ assert(handle); assert(xfer); /* Check if Message Buffer is idle. */ if (kFLEXCAN_StateIdle == handle->rxFifoState) { handle->rxFifoState = kFLEXCAN_StateRxFifo; /* Register Message Buffer. */ handle->rxFifoFrameBuf = xfer->frame; /* Enable Message Buffer Interrupt. */ FLEXCAN_EnableMbInterrupts( base, kFLEXCAN_RxFifoOverflowFlag | kFLEXCAN_RxFifoWarningFlag | kFLEXCAN_RxFifoFrameAvlFlag); return kStatus_Success; } else { return kStatus_FLEXCAN_RxFifoBusy; } } void FLEXCAN_TransferAbortSend(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx) { /* Assertion. */ assert(handle); assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); /* Disable Message Buffer Interrupt. */ FLEXCAN_DisableMbInterrupts(base, 1 << mbIdx); /* Un-register handle. */ handle->mbFrameBuf[mbIdx] = 0x0; /* Clean Message Buffer. */ FLEXCAN_SetTxMbConfig(base, mbIdx, true); handle->mbState[mbIdx] = kFLEXCAN_StateIdle; } void FLEXCAN_TransferAbortReceive(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx) { /* Assertion. */ assert(handle); assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK)); assert(!FLEXCAN_IsMbOccupied(base, mbIdx)); /* Disable Message Buffer Interrupt. */ FLEXCAN_DisableMbInterrupts(base, 1 << mbIdx); /* Un-register handle. */ handle->mbFrameBuf[mbIdx] = 0x0; handle->mbState[mbIdx] = kFLEXCAN_StateIdle; } void FLEXCAN_TransferAbortReceiveFifo(CAN_Type *base, flexcan_handle_t *handle) { /* Assertion. */ assert(handle); /* Check if Rx FIFO is enabled. */ if (base->MCR & CAN_MCR_RFEN_MASK) { /* Disable Rx Message FIFO Interrupts. */ FLEXCAN_DisableMbInterrupts( base, kFLEXCAN_RxFifoOverflowFlag | kFLEXCAN_RxFifoWarningFlag | kFLEXCAN_RxFifoFrameAvlFlag); /* Un-register handle. */ handle->rxFifoFrameBuf = 0x0; } handle->rxFifoState = kFLEXCAN_StateIdle; } void FLEXCAN_TransferHandleIRQ(CAN_Type *base, flexcan_handle_t *handle) { /* Assertion. */ assert(handle); status_t status = kStatus_FLEXCAN_UnHandled; uint32_t result; /* Store Current FlexCAN Module Error and Status. */ result = base->ESR1; do { /* Solve FlexCAN Error and Status Interrupt. */ if (result & (kFLEXCAN_TxWarningIntFlag | kFLEXCAN_RxWarningIntFlag | kFLEXCAN_BusOffIntFlag | kFLEXCAN_ErrorIntFlag | kFLEXCAN_WakeUpIntFlag)) { status = kStatus_FLEXCAN_ErrorStatus; /* Clear FlexCAN Error and Status Interrupt. */ FLEXCAN_ClearStatusFlags(base, kFLEXCAN_TxWarningIntFlag | kFLEXCAN_RxWarningIntFlag | kFLEXCAN_BusOffIntFlag | kFLEXCAN_ErrorIntFlag | kFLEXCAN_WakeUpIntFlag); } /* Solve FlexCAN Rx FIFO & Message Buffer Interrupt. */ else { /* For this implementation, we solve the Message with lowest MB index first. */ for (result = 0; result < FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); result++) { /* Get the lowest unhandled Message Buffer */ if ((FLEXCAN_GetMbStatusFlags(base, 1 << result)) && (FLEXCAN_IsMbIntEnabled(base, result))) { break; } } /* Does not find Message to deal with. */ if (result == FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base)) { break; } /* Solve Rx FIFO interrupt. */ if ((kFLEXCAN_StateIdle != handle->rxFifoState) && ((1 << result) <= kFLEXCAN_RxFifoOverflowFlag)) { switch (1 << result) { case kFLEXCAN_RxFifoOverflowFlag: status = kStatus_FLEXCAN_RxFifoOverflow; break; case kFLEXCAN_RxFifoWarningFlag: status = kStatus_FLEXCAN_RxFifoWarning; break; case kFLEXCAN_RxFifoFrameAvlFlag: status = FLEXCAN_ReadRxFifo(base, handle->rxFifoFrameBuf); if (kStatus_Success == status) { status = kStatus_FLEXCAN_RxFifoIdle; } FLEXCAN_TransferAbortReceiveFifo(base, handle); break; default: status = kStatus_FLEXCAN_UnHandled; break; } } else { /* Get current State of Message Buffer. */ switch (handle->mbState[result]) { /* Solve Rx Data Frame. */ case kFLEXCAN_StateRxData: status = FLEXCAN_ReadRxMb(base, result, handle->mbFrameBuf[result]); if (kStatus_Success == status) { status = kStatus_FLEXCAN_RxIdle; } FLEXCAN_TransferAbortReceive(base, handle, result); break; /* Solve Rx Remote Frame. */ case kFLEXCAN_StateRxRemote: status = FLEXCAN_ReadRxMb(base, result, handle->mbFrameBuf[result]); if (kStatus_Success == status) { status = kStatus_FLEXCAN_RxIdle; } FLEXCAN_TransferAbortReceive(base, handle, result); break; /* Solve Tx Data Frame. */ case kFLEXCAN_StateTxData: status = kStatus_FLEXCAN_TxIdle; FLEXCAN_TransferAbortSend(base, handle, result); break; /* Solve Tx Remote Frame. */ case kFLEXCAN_StateTxRemote: handle->mbState[result] = kFLEXCAN_StateRxRemote; status = kStatus_FLEXCAN_TxSwitchToRx; break; default: status = kStatus_FLEXCAN_UnHandled; break; } } /* Clear resolved Message Buffer IRQ. */ FLEXCAN_ClearMbStatusFlags(base, 1 << result); } /* Calling Callback Function if has one. */ if (handle->callback != NULL) { handle->callback(base, handle, status, result, handle->userData); } /* Reset return status */ status = kStatus_FLEXCAN_UnHandled; /* Store Current FlexCAN Module Error and Status. */ result = base->ESR1; } #if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0) while ((0 != FLEXCAN_GetMbStatusFlags(base, 0xFFFFFFFFFFFFFFFFU)) || (0 != (result & (kFLEXCAN_TxWarningIntFlag | kFLEXCAN_RxWarningIntFlag | kFLEXCAN_BusOffIntFlag | kFLEXCAN_ErrorIntFlag | kFLEXCAN_WakeUpIntFlag)))); #else while ((0 != FLEXCAN_GetMbStatusFlags(base, 0xFFFFFFFFU)) || (0 != (result & (kFLEXCAN_TxWarningIntFlag | kFLEXCAN_RxWarningIntFlag | kFLEXCAN_BusOffIntFlag | kFLEXCAN_ErrorIntFlag | kFLEXCAN_WakeUpIntFlag)))); #endif } #if defined(CAN0) void CAN0_DriverIRQHandler(void) { assert(s_flexcanHandle[0]); s_flexcanIsr(CAN0, s_flexcanHandle[0]); } #endif #if defined(CAN1) void CAN1_DriverIRQHandler(void) { assert(s_flexcanHandle[1]); s_flexcanIsr(CAN1, s_flexcanHandle[1]); } #endif #if defined(CAN2) void CAN2_DriverIRQHandler(void) { assert(s_flexcanHandle[2]); s_flexcanIsr(CAN2, s_flexcanHandle[2]); } #endif #if defined(CAN3) void CAN3_DriverIRQHandler(void) { assert(s_flexcanHandle[3]); s_flexcanIsr(CAN3, s_flexcanHandle[3]); } #endif #if defined(CAN4) void CAN4_DriverIRQHandler(void) { assert(s_flexcanHandle[4]); s_flexcanIsr(CAN4, s_flexcanHandle[4]); } #endif #if defined(DMA_CAN0) void DMA_FLEXCAN0_DriverIRQHandler(void) { assert(s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN0)]); s_flexcanIsr(DMA_CAN0, s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN0)]); } #endif #if defined(DMA_CAN1) void DMA_FLEXCAN1_DriverIRQHandler(void) { assert(s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN1)]); s_flexcanIsr(DMA_CAN0, s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN1)]); } #endif #if defined(DMA_CAN2) void DMA_FLEXCAN2_DriverIRQHandler(void) { assert(s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN2)]); s_flexcanIsr(DMA_CAN2, s_flexcanHandle[FLEXCAN_GetInstance(DMA_CAN2)]); } #endif |