/***********************************************************************//** * @file lpc17xx_gpdma.c * @brief Contains all functions support for GPDMA firmware library on LPC17xx * @version 2.0 * @date 21. May. 2010 * @author NXP MCU SW Application Team ************************************************************************** * Software that is described herein is for illustrative purposes only * which provides customers with programming information regarding the * products. This software is supplied "AS IS" without any warranties. * NXP Semiconductors assumes no responsibility or liability for the * use of the software, conveys no license or title under any patent, * copyright, or mask work right to the product. NXP Semiconductors * reserves the right to make changes in the software without * notification. NXP Semiconductors also make no representation or * warranty that such application will be suitable for the specified * use without further testing or modification. **********************************************************************/ /* Peripheral group ----------------------------------------------------------- */ /** @addtogroup GPDMA * @{ */ /* Includes ------------------------------------------------------------------- */ #include "lpc17xx_gpdma.h" #include "lpc17xx_clkpwr.h" /* If this source file built with example, the LPC17xx FW library configuration * file in each example directory ("lpc17xx_libcfg.h") must be included, * otherwise the default FW library configuration file must be included instead */ #ifdef __BUILD_WITH_EXAMPLE__ #include "lpc17xx_libcfg.h" #else #include "lpc17xx_libcfg_default.h" #endif /* __BUILD_WITH_EXAMPLE__ */ #ifdef _GPDMA /* Private Variables ---------------------------------------------------------- */ /** @defgroup GPDMA_Private_Variables GPDMA Private Variables * @{ */ /** * @brief Lookup Table of Connection Type matched with * Peripheral Data (FIFO) register base address */ #ifdef __IAR_SYSTEMS_ICC__ volatile const void *GPDMA_LUTPerAddr[] = { (&LPC_SSP0->DR), // SSP0 Tx (&LPC_SSP0->DR), // SSP0 Rx (&LPC_SSP1->DR), // SSP1 Tx (&LPC_SSP1->DR), // SSP1 Rx (&LPC_ADC->ADGDR), // ADC (&LPC_I2S->I2STXFIFO), // I2S Tx (&LPC_I2S->I2SRXFIFO), // I2S Rx (&LPC_DAC->DACR), // DAC (&LPC_UART0->/*RBTHDLR.*/THR), // UART0 Tx (&LPC_UART0->/*RBTHDLR.*/RBR), // UART0 Rx (&LPC_UART1->/*RBTHDLR.*/THR), // UART1 Tx (&LPC_UART1->/*RBTHDLR.*/RBR), // UART1 Rx (&LPC_UART2->/*RBTHDLR.*/THR), // UART2 Tx (&LPC_UART2->/*RBTHDLR.*/RBR), // UART2 Rx (&LPC_UART3->/*RBTHDLR.*/THR), // UART3 Tx (&LPC_UART3->/*RBTHDLR.*/RBR), // UART3 Rx (&LPC_TIM0->MR0), // MAT0.0 (&LPC_TIM0->MR1), // MAT0.1 (&LPC_TIM1->MR0), // MAT1.0 (&LPC_TIM1->MR1), // MAT1.1 (&LPC_TIM2->MR0), // MAT2.0 (&LPC_TIM2->MR1), // MAT2.1 (&LPC_TIM3->MR0), // MAT3.0 (&LPC_TIM3->MR1), // MAT3.1 }; #else const uint32_t GPDMA_LUTPerAddr[] = { ((uint32_t)&LPC_SSP0->DR), // SSP0 Tx ((uint32_t)&LPC_SSP0->DR), // SSP0 Rx ((uint32_t)&LPC_SSP1->DR), // SSP1 Tx ((uint32_t)&LPC_SSP1->DR), // SSP1 Rx ((uint32_t)&LPC_ADC->ADGDR), // ADC ((uint32_t)&LPC_I2S->I2STXFIFO), // I2S Tx ((uint32_t)&LPC_I2S->I2SRXFIFO), // I2S Rx ((uint32_t)&LPC_DAC->DACR), // DAC ((uint32_t)&LPC_UART0->/*RBTHDLR.*/THR), // UART0 Tx ((uint32_t)&LPC_UART0->/*RBTHDLR.*/RBR), // UART0 Rx ((uint32_t)&LPC_UART1->/*RBTHDLR.*/THR), // UART1 Tx ((uint32_t)&LPC_UART1->/*RBTHDLR.*/RBR), // UART1 Rx ((uint32_t)&LPC_UART2->/*RBTHDLR.*/THR), // UART2 Tx ((uint32_t)&LPC_UART2->/*RBTHDLR.*/RBR), // UART2 Rx ((uint32_t)&LPC_UART3->/*RBTHDLR.*/THR), // UART3 Tx ((uint32_t)&LPC_UART3->/*RBTHDLR.*/RBR), // UART3 Rx ((uint32_t)&LPC_TIM0->MR0), // MAT0.0 ((uint32_t)&LPC_TIM0->MR1), // MAT0.1 ((uint32_t)&LPC_TIM1->MR0), // MAT1.0 ((uint32_t)&LPC_TIM1->MR1), // MAT1.1 ((uint32_t)&LPC_TIM2->MR0), // MAT2.0 ((uint32_t)&LPC_TIM2->MR1), // MAT2.1 ((uint32_t)&LPC_TIM3->MR0), // MAT3.0 ((uint32_t)&LPC_TIM3->MR1), // MAT3.1 }; #endif /** * @brief Lookup Table of GPDMA Channel Number matched with * GPDMA channel pointer */ const LPC_GPDMACH_TypeDef *pGPDMACh[8] = { LPC_GPDMACH0, // GPDMA Channel 0 LPC_GPDMACH1, // GPDMA Channel 1 LPC_GPDMACH2, // GPDMA Channel 2 LPC_GPDMACH3, // GPDMA Channel 3 LPC_GPDMACH4, // GPDMA Channel 4 LPC_GPDMACH5, // GPDMA Channel 5 LPC_GPDMACH6, // GPDMA Channel 6 LPC_GPDMACH7, // GPDMA Channel 7 }; /** * @brief Optimized Peripheral Source and Destination burst size */ const uint8_t GPDMA_LUTPerBurst[] = { GPDMA_BSIZE_4, // SSP0 Tx GPDMA_BSIZE_4, // SSP0 Rx GPDMA_BSIZE_4, // SSP1 Tx GPDMA_BSIZE_4, // SSP1 Rx GPDMA_BSIZE_4, // ADC GPDMA_BSIZE_32, // I2S channel 0 GPDMA_BSIZE_32, // I2S channel 1 GPDMA_BSIZE_1, // DAC GPDMA_BSIZE_1, // UART0 Tx GPDMA_BSIZE_1, // UART0 Rx GPDMA_BSIZE_1, // UART1 Tx GPDMA_BSIZE_1, // UART1 Rx GPDMA_BSIZE_1, // UART2 Tx GPDMA_BSIZE_1, // UART2 Rx GPDMA_BSIZE_1, // UART3 Tx GPDMA_BSIZE_1, // UART3 Rx GPDMA_BSIZE_1, // MAT0.0 GPDMA_BSIZE_1, // MAT0.1 GPDMA_BSIZE_1, // MAT1.0 GPDMA_BSIZE_1, // MAT1.1 GPDMA_BSIZE_1, // MAT2.0 GPDMA_BSIZE_1, // MAT2.1 GPDMA_BSIZE_1, // MAT3.0 GPDMA_BSIZE_1, // MAT3.1 }; /** * @brief Optimized Peripheral Source and Destination transfer width */ const uint8_t GPDMA_LUTPerWid[] = { GPDMA_WIDTH_BYTE, // SSP0 Tx GPDMA_WIDTH_BYTE, // SSP0 Rx GPDMA_WIDTH_BYTE, // SSP1 Tx GPDMA_WIDTH_BYTE, // SSP1 Rx GPDMA_WIDTH_WORD, // ADC GPDMA_WIDTH_WORD, // I2S channel 0 GPDMA_WIDTH_WORD, // I2S channel 1 GPDMA_WIDTH_BYTE, // DAC GPDMA_WIDTH_BYTE, // UART0 Tx GPDMA_WIDTH_BYTE, // UART0 Rx GPDMA_WIDTH_BYTE, // UART1 Tx GPDMA_WIDTH_BYTE, // UART1 Rx GPDMA_WIDTH_BYTE, // UART2 Tx GPDMA_WIDTH_BYTE, // UART2 Rx GPDMA_WIDTH_BYTE, // UART3 Tx GPDMA_WIDTH_BYTE, // UART3 Rx GPDMA_WIDTH_WORD, // MAT0.0 GPDMA_WIDTH_WORD, // MAT0.1 GPDMA_WIDTH_WORD, // MAT1.0 GPDMA_WIDTH_WORD, // MAT1.1 GPDMA_WIDTH_WORD, // MAT2.0 GPDMA_WIDTH_WORD, // MAT2.1 GPDMA_WIDTH_WORD, // MAT3.0 GPDMA_WIDTH_WORD, // MAT3.1 }; /** * @} */ /* Public Functions ----------------------------------------------------------- */ /** @addtogroup GPDMA_Public_Functions * @{ */ /********************************************************************//** * @brief Initialize GPDMA controller * @param None * @return None *********************************************************************/ void GPDMA_Init(void) { /* Enable GPDMA clock */ CLKPWR_ConfigPPWR (CLKPWR_PCONP_PCGPDMA, ENABLE); // Reset all channel configuration register LPC_GPDMACH0->DMACCConfig = 0; LPC_GPDMACH1->DMACCConfig = 0; LPC_GPDMACH2->DMACCConfig = 0; LPC_GPDMACH3->DMACCConfig = 0; LPC_GPDMACH4->DMACCConfig = 0; LPC_GPDMACH5->DMACCConfig = 0; LPC_GPDMACH6->DMACCConfig = 0; LPC_GPDMACH7->DMACCConfig = 0; /* Clear all DMA interrupt and error flag */ LPC_GPDMA->DMACIntTCClear = 0xFF; LPC_GPDMA->DMACIntErrClr = 0xFF; } /********************************************************************//** * @brief Setup GPDMA channel peripheral according to the specified * parameters in the GPDMAChannelConfig. * @param[in] GPDMAChannelConfig Pointer to a GPDMA_CH_CFG_Type * structure that contains the configuration * information for the specified GPDMA channel peripheral. * @return ERROR if selected channel is enabled before * or SUCCESS if channel is configured successfully *********************************************************************/ Status GPDMA_Setup(GPDMA_Channel_CFG_Type *GPDMAChannelConfig) { LPC_GPDMACH_TypeDef *pDMAch; uint32_t tmp1, tmp2; if (LPC_GPDMA->DMACEnbldChns & (GPDMA_DMACEnbldChns_Ch(GPDMAChannelConfig->ChannelNum))) { // This channel is enabled, return ERROR, need to release this channel first return ERROR; } // Get Channel pointer pDMAch = (LPC_GPDMACH_TypeDef *) pGPDMACh[GPDMAChannelConfig->ChannelNum]; // Reset the Interrupt status LPC_GPDMA->DMACIntTCClear = GPDMA_DMACIntTCClear_Ch(GPDMAChannelConfig->ChannelNum); LPC_GPDMA->DMACIntErrClr = GPDMA_DMACIntErrClr_Ch(GPDMAChannelConfig->ChannelNum); // Clear DMA configure pDMAch->DMACCControl = 0x00; pDMAch->DMACCConfig = 0x00; /* Assign Linker List Item value */ pDMAch->DMACCLLI = GPDMAChannelConfig->DMALLI; /* Set value to Channel Control Registers */ switch (GPDMAChannelConfig->TransferType) { // Memory to memory case GPDMA_TRANSFERTYPE_M2M: // Assign physical source and destination address pDMAch->DMACCSrcAddr = GPDMAChannelConfig->SrcMemAddr; pDMAch->DMACCDestAddr = GPDMAChannelConfig->DstMemAddr; pDMAch->DMACCControl = GPDMA_DMACCxControl_TransferSize(GPDMAChannelConfig->TransferSize) \ | GPDMA_DMACCxControl_SBSize(GPDMA_BSIZE_32) \ | GPDMA_DMACCxControl_DBSize(GPDMA_BSIZE_32) \ | GPDMA_DMACCxControl_SWidth(GPDMAChannelConfig->TransferWidth) \ | GPDMA_DMACCxControl_DWidth(GPDMAChannelConfig->TransferWidth) \ | GPDMA_DMACCxControl_SI \ | GPDMA_DMACCxControl_DI \ | GPDMA_DMACCxControl_I; break; // Memory to peripheral case GPDMA_TRANSFERTYPE_M2P: // Assign physical source pDMAch->DMACCSrcAddr = GPDMAChannelConfig->SrcMemAddr; // Assign peripheral destination address pDMAch->DMACCDestAddr = (uint32_t)GPDMA_LUTPerAddr[GPDMAChannelConfig->DstConn]; pDMAch->DMACCControl = GPDMA_DMACCxControl_TransferSize((uint32_t)GPDMAChannelConfig->TransferSize) \ | GPDMA_DMACCxControl_SBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_DBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_SWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_DWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_SI \ | GPDMA_DMACCxControl_I; break; // Peripheral to memory case GPDMA_TRANSFERTYPE_P2M: // Assign peripheral source address pDMAch->DMACCSrcAddr = (uint32_t)GPDMA_LUTPerAddr[GPDMAChannelConfig->SrcConn]; // Assign memory destination address pDMAch->DMACCDestAddr = GPDMAChannelConfig->DstMemAddr; pDMAch->DMACCControl = GPDMA_DMACCxControl_TransferSize((uint32_t)GPDMAChannelConfig->TransferSize) \ | GPDMA_DMACCxControl_SBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_DBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_SWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_DWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_DI \ | GPDMA_DMACCxControl_I; break; // Peripheral to peripheral case GPDMA_TRANSFERTYPE_P2P: // Assign peripheral source address pDMAch->DMACCSrcAddr = (uint32_t)GPDMA_LUTPerAddr[GPDMAChannelConfig->SrcConn]; // Assign peripheral destination address pDMAch->DMACCDestAddr = (uint32_t)GPDMA_LUTPerAddr[GPDMAChannelConfig->DstConn]; pDMAch->DMACCControl = GPDMA_DMACCxControl_TransferSize((uint32_t)GPDMAChannelConfig->TransferSize) \ | GPDMA_DMACCxControl_SBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_DBSize((uint32_t)GPDMA_LUTPerBurst[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_SWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->SrcConn]) \ | GPDMA_DMACCxControl_DWidth((uint32_t)GPDMA_LUTPerWid[GPDMAChannelConfig->DstConn]) \ | GPDMA_DMACCxControl_I; break; // Do not support any more transfer type, return ERROR default: return ERROR; } /* Re-Configure DMA Request Select for source peripheral */ if (GPDMAChannelConfig->SrcConn > 15) { DMAREQSEL |= (1<<(GPDMAChannelConfig->SrcConn - 16)); } else { DMAREQSEL &= ~(1<<(GPDMAChannelConfig->SrcConn - 8)); } /* Re-Configure DMA Request Select for Destination peripheral */ if (GPDMAChannelConfig->DstConn > 15) { DMAREQSEL |= (1<<(GPDMAChannelConfig->DstConn - 16)); } else { DMAREQSEL &= ~(1<<(GPDMAChannelConfig->DstConn - 8)); } /* Enable DMA channels, little endian */ LPC_GPDMA->DMACConfig = GPDMA_DMACConfig_E; while (!(LPC_GPDMA->DMACConfig & GPDMA_DMACConfig_E)); // Calculate absolute value for Connection number tmp1 = GPDMAChannelConfig->SrcConn; tmp1 = ((tmp1 > 15) ? (tmp1 - 8) : tmp1); tmp2 = GPDMAChannelConfig->DstConn; tmp2 = ((tmp2 > 15) ? (tmp2 - 8) : tmp2); // Configure DMA Channel, enable Error Counter and Terminate counter pDMAch->DMACCConfig = GPDMA_DMACCxConfig_IE | GPDMA_DMACCxConfig_ITC /*| GPDMA_DMACCxConfig_E*/ \ | GPDMA_DMACCxConfig_TransferType((uint32_t)GPDMAChannelConfig->TransferType) \ | GPDMA_DMACCxConfig_SrcPeripheral(tmp1) \ | GPDMA_DMACCxConfig_DestPeripheral(tmp2); return SUCCESS; } /*********************************************************************//** * @brief Enable/Disable DMA channel * @param[in] channelNum GPDMA channel, should be in range from 0 to 7 * @param[in] NewState New State of this command, should be: * - ENABLE. * - DISABLE. * @return None **********************************************************************/ void GPDMA_ChannelCmd(uint8_t channelNum, FunctionalState NewState) { LPC_GPDMACH_TypeDef *pDMAch; // Get Channel pointer pDMAch = (LPC_GPDMACH_TypeDef *) pGPDMACh[channelNum]; if (NewState == ENABLE) { pDMAch->DMACCConfig |= GPDMA_DMACCxConfig_E; } else { pDMAch->DMACCConfig &= ~GPDMA_DMACCxConfig_E; } } /*********************************************************************//** * @brief Check if corresponding channel does have an active interrupt * request or not * @param[in] type type of status, should be: * - GPDMA_STAT_INT: GPDMA Interrupt Status * - GPDMA_STAT_INTTC: GPDMA Interrupt Terminal Count Request Status * - GPDMA_STAT_INTERR: GPDMA Interrupt Error Status * - GPDMA_STAT_RAWINTTC: GPDMA Raw Interrupt Terminal Count Status * - GPDMA_STAT_RAWINTERR: GPDMA Raw Error Interrupt Status * - GPDMA_STAT_ENABLED_CH:GPDMA Enabled Channel Status * @param[in] channel GPDMA channel, should be in range from 0 to 7 * @return IntStatus status of DMA channel interrupt after masking * Should be: * - SET: the corresponding channel has no active interrupt request * - RESET: the corresponding channel does have an active interrupt request **********************************************************************/ IntStatus GPDMA_IntGetStatus(GPDMA_Status_Type type, uint8_t channel) { CHECK_PARAM(PARAM_GPDMA_STAT(type)); CHECK_PARAM(PARAM_GPDMA_CHANNEL(channel)); switch (type) { case GPDMA_STAT_INT: //check status of DMA channel interrupts if (LPC_GPDMA->DMACIntStat & (GPDMA_DMACIntStat_Ch(channel))) return SET; return RESET; case GPDMA_STAT_INTTC: // check terminal count interrupt request status for DMA if (LPC_GPDMA->DMACIntTCStat & GPDMA_DMACIntTCStat_Ch(channel)) return SET; return RESET; case GPDMA_STAT_INTERR: //check interrupt status for DMA channels if (LPC_GPDMA->DMACIntErrStat & GPDMA_DMACIntTCClear_Ch(channel)) return SET; return RESET; case GPDMA_STAT_RAWINTTC: //check status of the terminal count interrupt for DMA channels if (LPC_GPDMA->DMACRawIntErrStat & GPDMA_DMACRawIntTCStat_Ch(channel)) return SET; return RESET; case GPDMA_STAT_RAWINTERR: //check status of the error interrupt for DMA channels if (LPC_GPDMA->DMACRawIntTCStat & GPDMA_DMACRawIntErrStat_Ch(channel)) return SET; return RESET; default: //check enable status for DMA channels if (LPC_GPDMA->DMACEnbldChns & GPDMA_DMACEnbldChns_Ch(channel)) return SET; return RESET; } } /*********************************************************************//** * @brief Clear one or more interrupt requests on DMA channels * @param[in] type type of interrupt request, should be: * - GPDMA_STATCLR_INTTC: GPDMA Interrupt Terminal Count Request Clear * - GPDMA_STATCLR_INTERR: GPDMA Interrupt Error Clear * @param[in] channel GPDMA channel, should be in range from 0 to 7 * @return None **********************************************************************/ void GPDMA_ClearIntPending(GPDMA_StateClear_Type type, uint8_t channel) { CHECK_PARAM(PARAM_GPDMA_STATCLR(type)); CHECK_PARAM(PARAM_GPDMA_CHANNEL(channel)); if (type == GPDMA_STATCLR_INTTC) // clears the terminal count interrupt request on DMA channel LPC_GPDMA->DMACIntTCClear = GPDMA_DMACIntTCClear_Ch(channel); else // clear the error interrupt request LPC_GPDMA->DMACIntErrClr = GPDMA_DMACIntErrClr_Ch(channel); } /** * @} */ #endif /* _GPDMA */ /** * @} */ /* --------------------------------- End Of File ------------------------------ */