//########################################################################### // // FILE: F2837xD_DMA.c // // TITLE: F2837xD Device DMA Initialization & Support Functions. // //########################################################################### // // $Release Date: $ // $Copyright: // Copyright (C) 2013-2022 Texas Instruments Incorporated - http://www.ti.com/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // // Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // 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. // // Neither the name of Texas Instruments Incorporated 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 // OWNER 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. // $ //########################################################################### // // Included Files // #include "F2837xD_device.h" #include "F2837xD_Examples.h" // // DMAInitialize - This function initializes the DMA to a known state. // void DMAInitialize(void) { EALLOW; // // Perform a hard reset on DMA // DmaRegs.DMACTRL.bit.HARDRESET = 1; __asm (" nop"); // one NOP required after HARDRESET // // Allow DMA to run free on emulation suspend // DmaRegs.DEBUGCTRL.bit.FREE = 1; EDIS; } // // DMACH1AddrConfig - DMA Channel 1 Address Configuration // void DMACH1AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH1.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to // beginning of // source buffer DmaRegs.CH1.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH1.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to // beginning of // destination buffer DmaRegs.CH1.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH1BurstConfig - DMA Channel 1 Burst size configuration // void DMACH1BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH1.BURST_SIZE.all = bsize; // Number of words(X-1) // x-ferred in a burst. DmaRegs.CH1.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH1.DST_BURST_STEP = desbstep; // Increment dest addr between // each word x-ferred. EDIS; } // // DMACH1TransferConfig - DMA Channel 1 Transfer size configuration // void DMACH1TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH1.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH1.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored // when WRAP occurs. DmaRegs.CH1.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored // when WRAP occurs. EDIS; } // // DMACH1WrapConfig - DMA Channel 1 Wrap size configuration // void DMACH1WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH1.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH1.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH1.DST_WRAP_SIZE = deswsize; // Wrap destination address after // N bursts. DmaRegs.CH1.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH1ModeConfig - DMA Channel 1 Mode configuration // void DMACH1ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL1.bit.CH1 = persel; DmaRegs.CH1.MODE.bit.PERINTSEL = 1; DmaRegs.CH1.MODE.bit.PERINTE = perinte; DmaRegs.CH1.MODE.bit.ONESHOT = oneshot; DmaRegs.CH1.MODE.bit.CONTINUOUS = cont; DmaRegs.CH1.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH1.MODE.bit.DATASIZE = datasize; DmaRegs.CH1.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH1.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: interrupt and sync error flags // DmaRegs.CH1.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH1.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH1 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx1 = 1; EDIS; } // // StartDMACH1 - This function starts DMA Channel 1. // void StartDMACH1(void) { EALLOW; DmaRegs.CH1.CONTROL.bit.RUN = 1; EDIS; } // // DMACH2AddrConfig - DMA Channel 2 Address Configuration // void DMACH2AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH2.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to // beginning of // source buffer. DmaRegs.CH2.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH2.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH2.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH2BurstConfig - DMA Channel 2 Burst size configuration // void DMACH2BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH2.BURST_SIZE.all = bsize; // Number of words(X-1) x-ferred in // a burst. DmaRegs.CH2.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH2.DST_BURST_STEP = desbstep; // Increment dest addr between each // word x-ferred. EDIS; } // // DMACH2TransferConfig - DMA Channel 2 Transfer size Configuration // void DMACH2TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH2.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH2.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored when // WRAP occurs. DmaRegs.CH2.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored when // WRAP occurs. EDIS; } // // DMACH2WrapConfig - DMA Channel 2 Wrap size configuration // void DMACH2WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH2.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH2.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH2.DST_WRAP_SIZE = deswsize; // Wrap destination address after // N bursts. DmaRegs.CH2.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH2ModeConfig - DMA Channel 2 Mode configuration // void DMACH2ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL1.bit.CH2 = persel; DmaRegs.CH2.MODE.bit.PERINTSEL = 2; DmaRegs.CH2.MODE.bit.PERINTE = perinte; DmaRegs.CH2.MODE.bit.ONESHOT = oneshot; DmaRegs.CH2.MODE.bit.CONTINUOUS = cont; DmaRegs.CH2.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH2.MODE.bit.DATASIZE = datasize; DmaRegs.CH2.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH2.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: Interrupt flags and sync error flags // DmaRegs.CH2.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH2.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH2 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx2 = 1; EDIS; } // // StartDMACH2 - This function starts DMA Channel 2. // void StartDMACH2(void) { EALLOW; DmaRegs.CH2.CONTROL.bit.RUN = 1; EDIS; } // // DMACH3AddrConfig - DMA Channel 3 Address configuration // void DMACH3AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH3.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer. DmaRegs.CH3.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH3.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH3.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH3BurstConfig - DMA Channel 3 burst size configuration // void DMACH3BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH3.BURST_SIZE.all = bsize; // Number of words(X-1) x-ferred in // a burst. DmaRegs.CH3.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH3.DST_BURST_STEP = desbstep; // Increment dest addr between each // word x-ferred. EDIS; } // // DMACH3TransferConfig - DMA channel 3 transfer size configuration // void DMACH3TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH3.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH3.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored when // WRAP occurs. DmaRegs.CH3.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored when // WRAP occurs. EDIS; } // // DMACH3WrapConfig - DMA Channel 3 wrap size configuration // void DMACH3WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH3.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH3.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH3.DST_WRAP_SIZE = deswsize; // Wrap destination address after N // bursts. DmaRegs.CH3.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH3ModeConfig - DMA Channel 3 mode configuration // void DMACH3ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL1.bit.CH3 = persel; DmaRegs.CH3.MODE.bit.PERINTSEL = 3; DmaRegs.CH3.MODE.bit.PERINTE = perinte; DmaRegs.CH3.MODE.bit.ONESHOT = oneshot; DmaRegs.CH3.MODE.bit.CONTINUOUS = cont; DmaRegs.CH3.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH3.MODE.bit.DATASIZE = datasize; DmaRegs.CH3.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH3.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: interrupt flags and sync error flags // DmaRegs.CH3.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH3.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH3 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx3 = 1; EDIS; } // // StartDMACH3 - This function starts DMA Channel 3. // void StartDMACH3(void) { EALLOW; DmaRegs.CH3.CONTROL.bit.RUN = 1; EDIS; } // // DMACH4AddrConfig - DMA Channel 4 address configuration // void DMACH4AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH4.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer. DmaRegs.CH4.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH4.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH4.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH4BurstConfig - DMA Channel 4 burst size configuration // void DMACH4BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH4.BURST_SIZE.all = bsize; // Number of words(X-1) x-ferred in // a burst. DmaRegs.CH4.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH4.DST_BURST_STEP = desbstep; // Increment dest addr between each // word x-ferred. EDIS; } // // DMACH4TransferConfig - DMA channel 4 transfer size configuration // void DMACH4TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH4.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH4.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored when // WRAP occurs. DmaRegs.CH4.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored when // WRAP occurs. EDIS; } // // DMACH4WrapConfig - DMA channel 4 wrap size configuration // void DMACH4WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH4.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH4.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH4.DST_WRAP_SIZE = deswsize; // Wrap destination address after // N bursts. DmaRegs.CH4.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH4ModeConfig - DMA Channel 4 mode configuration // void DMACH4ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL1.bit.CH4 = persel; DmaRegs.CH4.MODE.bit.PERINTSEL = 4; DmaRegs.CH4.MODE.bit.PERINTE = perinte; DmaRegs.CH4.MODE.bit.ONESHOT = oneshot; DmaRegs.CH4.MODE.bit.CONTINUOUS = cont; DmaRegs.CH4.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH4.MODE.bit.DATASIZE = datasize; DmaRegs.CH4.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH4.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: Interrupt flags and sync error flags // DmaRegs.CH4.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH4.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH4 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx4 = 1; EDIS; } // // StartDMACH4 - This function starts DMA Channel 4. // void StartDMACH4(void) { EALLOW; DmaRegs.CH4.CONTROL.bit.RUN = 1; EDIS; } // // DMACH5AddrConfig - DMA channel 5 address configuration // void DMACH5AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH5.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH5.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH5.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH5.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH5BurstConfig - DMA Channel 5 burst size configuration // void DMACH5BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH5.BURST_SIZE.all = bsize; // Number of words(X-1) x-ferred in // a burst. DmaRegs.CH5.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH5.DST_BURST_STEP = desbstep; // Increment dest addr between each // word x-ferred. EDIS; } // // DMACH5TransferConfig - DMA channel 5 transfer size configuration // void DMACH5TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH5.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH5.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored when // WRAP occurs. DmaRegs.CH5.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored when // WRAP occurs. EDIS; } // // DMACH5WrapConfig - DMA Channel 5 wrap size configuration // void DMACH5WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH5.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH5.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH5.DST_WRAP_SIZE = deswsize; // Wrap destination address after // N bursts. DmaRegs.CH5.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH5ModeConfig - DMA Channel 5 mode configuration // void DMACH5ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL2.bit.CH5 = persel; DmaRegs.CH5.MODE.bit.PERINTSEL = 5; DmaRegs.CH5.MODE.bit.PERINTE = perinte; DmaRegs.CH5.MODE.bit.ONESHOT = oneshot; DmaRegs.CH5.MODE.bit.CONTINUOUS = cont; DmaRegs.CH5.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH5.MODE.bit.DATASIZE = datasize; DmaRegs.CH5.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH5.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: Interrupt flags and sync error flags // DmaRegs.CH5.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH5.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH5 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx5 = 1; EDIS; } // // StartDMACH5 - This function starts DMA Channel 5. // void StartDMACH5(void) { EALLOW; DmaRegs.CH5.CONTROL.bit.RUN = 1; EDIS; } // // DMACH6AddrConfig - DMA Channel 6 address configuration // void DMACH6AddrConfig(volatile Uint16 *DMA_Dest,volatile Uint16 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH6.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer. DmaRegs.CH6.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH6.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH6.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH6BurstConfig - DMA Channel 6 burst size configuration // void DMACH6BurstConfig(Uint16 bsize, int16 srcbstep, int16 desbstep) { EALLOW; // // Set up BURST registers: // DmaRegs.CH6.BURST_SIZE.all = bsize; // Number of words(X-1) x-ferred in // a burst. DmaRegs.CH6.SRC_BURST_STEP = srcbstep; // Increment source addr between // each word x-ferred. DmaRegs.CH6.DST_BURST_STEP = desbstep; // Increment dest addr between each // word x-ferred. EDIS; } // // DMACH6TransferConfig - DMA channel 6 transfer size configuration // void DMACH6TransferConfig(Uint16 tsize, int16 srctstep, int16 deststep) { EALLOW; // // Set up TRANSFER registers: // DmaRegs.CH6.TRANSFER_SIZE = tsize; // Number of bursts per transfer, // DMA interrupt will occur after // completed transfer. DmaRegs.CH6.SRC_TRANSFER_STEP = srctstep; // TRANSFER_STEP is ignored when // WRAP occurs. DmaRegs.CH6.DST_TRANSFER_STEP = deststep; // TRANSFER_STEP is ignored when // WRAP occurs. EDIS; } // // DMACH6WrapConfig - DMA Channel 6 wrap size configuration // void DMACH6WrapConfig(Uint16 srcwsize, int16 srcwstep, Uint16 deswsize, int16 deswstep) { EALLOW; // // Set up WRAP registers: // DmaRegs.CH6.SRC_WRAP_SIZE = srcwsize; // Wrap source address after N bursts DmaRegs.CH6.SRC_WRAP_STEP = srcwstep; // Step for source wrap DmaRegs.CH6.DST_WRAP_SIZE = deswsize; // Wrap destination address after N // bursts. DmaRegs.CH6.DST_WRAP_STEP = deswstep; // Step for destination wrap EDIS; } // // DMACH6ModeConfig - DMA Channel 6 mode configuration // void DMACH6ModeConfig(Uint16 persel, Uint16 perinte, Uint16 oneshot, Uint16 cont, Uint16 synce, Uint16 syncsel, Uint16 ovrinte, Uint16 datasize, Uint16 chintmode, Uint16 chinte) { EALLOW; // // Set up MODE Register: // persel - Source select // PERINTSEL - Should be hard coded to channel, above now selects source // PERINTE - Peripheral interrupt enable // ONESHOT - Oneshot enable // CONTINUOUS - Continuous enable // OVRINTE - Enable/disable the overflow interrupt // DATASIZE - 16-bit/32-bit data size transfers // CHINTMODE - Generate interrupt to CPU at beginning/end of transfer // CHINTE - Channel Interrupt to CPU enable // DmaClaSrcSelRegs.DMACHSRCSEL2.bit.CH6 = persel; DmaRegs.CH6.MODE.bit.PERINTSEL = 6; DmaRegs.CH6.MODE.bit.PERINTE = perinte; DmaRegs.CH6.MODE.bit.ONESHOT = oneshot; DmaRegs.CH6.MODE.bit.CONTINUOUS = cont; DmaRegs.CH6.MODE.bit.OVRINTE = ovrinte; DmaRegs.CH6.MODE.bit.DATASIZE = datasize; DmaRegs.CH6.MODE.bit.CHINTMODE = chintmode; DmaRegs.CH6.MODE.bit.CHINTE = chinte; // // Clear any spurious flags: Interrupt flags and sync error flags // DmaRegs.CH6.CONTROL.bit.PERINTCLR = 1; DmaRegs.CH6.CONTROL.bit.ERRCLR = 1; // // Initialize PIE vector for CPU interrupt: // Enable DMA CH6 interrupt in PIE // PieCtrlRegs.PIEIER7.bit.INTx6 = 1; EDIS; } // // StartDMACH6 - This function starts DMA Channel 6. // void StartDMACH6(void) { EALLOW; DmaRegs.CH6.CONTROL.bit.RUN = 1; EDIS; } // // NOTE: // Following functions are required for EMIF as the address is out of // 22bit range // // // DMACH1AddrConfig32bit - DMA Channel 1 address configuration for 32bit // void DMACH1AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH1.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH1.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH1.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer DmaRegs.CH1.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH2AddrConfig32bit - DMA Channel 2 address configuration for 32bit // void DMACH2AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH2.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH2.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH2.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer DmaRegs.CH2.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH3AddrConfig32bit - DMA Channel 3 address configuration for 32bit // void DMACH3AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH3.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH3.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH3.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer. DmaRegs.CH3.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH4AddrConfig32bit - DMA Channel 4 address configuration for 32bit // void DMACH4AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH4.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH4.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH4.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer DmaRegs.CH4.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH5AddrConfig32bit - DMA Channel 5 address configuration for 32bit // void DMACH5AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH5.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH5.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH5.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer DmaRegs.CH5.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // DMACH6AddrConfig32bit - DMA Channel 6 address configuration for 32bit // void DMACH6AddrConfig32bit(volatile Uint32 *DMA_Dest, volatile Uint32 *DMA_Source) { EALLOW; // // Set up SOURCE address: // DmaRegs.CH6.SRC_BEG_ADDR_SHADOW = (Uint32)DMA_Source; // Point to beginning // of source buffer DmaRegs.CH6.SRC_ADDR_SHADOW = (Uint32)DMA_Source; // // Set up DESTINATION address: // DmaRegs.CH6.DST_BEG_ADDR_SHADOW = (Uint32)DMA_Dest; // Point to beginning // of destination // buffer DmaRegs.CH6.DST_ADDR_SHADOW = (Uint32)DMA_Dest; EDIS; } // // End of file //