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SPIRAM_23LC1024_DMA
SPI RAM 23LC1024 (Microchip) with DMA
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Revision 2:a3e0f7f37ac9, committed 2012-12-05
- Comitter:
- okini3939
- Date:
- Wed Dec 05 07:56:09 2012 +0000
- Parent:
- 1:a7b1803dfa44
- Commit message:
- DMX
Changed in this revision
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/CONFIG.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/CONFIG.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,95 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ + +#ifdef NOCOMPILE + +#ifndef MODDMA_CONFIG_H +#define MODDMA_CONFIG_H + +#include "mbed.h" + +namespace AjK { + +// Forward reference. +class MODDMA; + +class MODDMA_Channel_CFG_t { +public: + + // ***************************************** + // From GPDMA by NXP MCU SW Application Team + // ***************************************** + + uint32_t ChannelNum; //!< DMA channel number, should be in range from 0 to 7. + uint32_t TransferSize; //!< Length/Size of transfer + uint32_t TransferWidth; //!< Transfer width - used for TransferType is GPDMA_TRANSFERTYPE_m2m only + uint32_t SrcMemAddr; //!< Physical Src Addr, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::m2p + uint32_t DstMemAddr; //!< Physical Destination Address, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::p2m + uint32_t TransferType; //!< Transfer Type + uint32_t SrcConn; ///!< Peripheral Source Connection type, used in case TransferType is chosen as + uint32_t DstConn; //!< Peripheral Destination Connection type, used in case TransferType is chosen as + uint32_t DMALLI; //!< Linker List Item structure data address if there's no Linker List, set as '0' + + // Mbed specifics. + + MODDMA_Channel_CFG_t() { + isrIntTCStat = new FunctionPointer; + isrIntErrStat = new FunctionPointer; + } + + ~MODDMA_Channel_CFG_t() { + delete(isrIntTCStat); + delete(isrIntErrStat); + } + + class MODDMA_Channel_CFG_t * channelNum(uint32_t n) { ChannelNum = n; return this; } + class MODDMA_Channel_CFG_t * transferSize(uint32_t n) { TransferSize = n; return this; } + class MODDMA_Channel_CFG_t * transferWidth(uint32_t n) { TransferWidth = n; return this; } + class MODDMA_Channel_CFG_t * srcMemAddr(uint32_t n) { SrcMemAddr = n; return this; } + class MODDMA_Channel_CFG_t * dstMemAddr(uint32_t n) { DstMemAddr = n; return this; } + class MODDMA_Channel_CFG_t * transferType(uint32_t n) { TransferType = n; return this; } + class MODDMA_Channel_CFG_t * srcConn(uint32_t n) { SrcConn = n; return this; } + class MODDMA_Channel_CFG_t * dstConn(uint32_t n) { DstConn = n; return this; } + class MODDMA_Channel_CFG_t * dmaLLI(uint32_t n) { DMALLI = n; return this; } + + uint32_t channelNum(void) { return ChannelNum; } + + FunctionPointer *isrIntTCStat; + FunctionPointer *isrIntErrStat; +}; + +/** + * @brief GPDMA Linker List Item structure type definition + */ +class GPDMA_LLI_t +{ +public: + uint32_t SrcAddr; //!< Source Address + uint32_t DstAddr; //!< Destination address + uint32_t NextLLI; //!< Next LLI address, otherwise set to '0' + uint32_t Control; //!< GPDMA Control of this LLI +}; + +}; // namespace AjK ends. + +#endif +#endif
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/ChangeLog.c --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/ChangeLog.c Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,74 @@ +/* $Id:$ + +1.12- 14 Mar 2011 + + * Added example4.h that demonstrates alternately sending + two buffers (double buffering) to the DAC. All those + people building MP3 players may find this of interest. + +1.11- 13 Mar 2011 + + * Fixed a silly typo in the documentation of example3.h + +1.10- 13 Mar 2011 + + * The rescheduling showed the timer being stopped and restarted + to perform a new scheduled grab. This was changed to show the + timer free running and the reschedules being setup. + +1.9 - 13 Mar 2011 + + * Improved example3.h to add rescheduling additional grabs + based on the timer setup. + +1.8 - 13 Mar 2011 + + * Renamed example files to .h + * Added pseudo g2m and m2g transferTypes to support GPIO + "memory moves" but triggered by peripheral timer. To + support this new operating mode added example3.h + +1.7 - 13 Mar 2011 + + * Remove the test at the beginning of the channel setup. + +1.6 - 8 Mar 2011 + + * Fixed a typo bug. Reported by Wim van der Vegt + http://mbed.org/forum/mbed/topic/1798/?page=1#comment-9845 + +1.5 - 5 Feb 2011 + + * Found a bug in the NXP library that I had copied over. + http://mbed.org/forum/mbed/topic/1798 + * Added example2.cpp to support that forum thread. + +1.4 - 23/11/2010 + + * Added some extra overloaded methods to make calling certain + userland API methods simpler. + +1.3 - 23/10/2010 + + * Added the LLI class wrapper. + * Added checking channel's LLI for non-null before auto-disable + of a channel with the ISR. + * Tested with MODSERIAL which is now natively MODDMA "aware". + MODSERIAL can now, using MODDMA, send blocks of bytes out + of it's TX port under DMA control. + +1.2 - 23/10/2010 + + * Improved the IRQ callback attachment API to make + easier attachments when creating configurations. + +1.1 - 23/10/2010 + + * Tidied up example1.cpp + * Removed some unneeded methoids that cause compiler errs. + +1.0 - 23/11/2010 + + * First release + +*/
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/DATALUTS.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/DATALUTS.cpp Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,147 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ + +#include "MODDMA.h" + +#ifndef MBED_H +#include "mbed.h" +#endif + +#ifndef MODDMA_CONFIG_H +#include "CONFIG.h" +#endif + +namespace AjK { + +uint32_t +MODDMA::LUTPerAddr(int n) +{ + const uint32_t lut[] = { + (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->THR // UART0 Tx + , (uint32_t)&LPC_UART0->RBR // UART0 Rx + , (uint32_t)&LPC_UART1->THR // UART1 Tx + , (uint32_t)&LPC_UART1->RBR // UART1 Rx + , (uint32_t)&LPC_UART2->THR // UART2 Tx + , (uint32_t)&LPC_UART2->RBR // UART2 Rx + , (uint32_t)&LPC_UART3->THR // UART3 Tx + , (uint32_t)&LPC_UART3->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 + }; + return lut[n & 0xFF]; +} + +uint32_t +MODDMA::Channel_p(int channel) +{ + const uint32_t lut[] = { + (uint32_t)LPC_GPDMACH0 + , (uint32_t)LPC_GPDMACH1 + , (uint32_t)LPC_GPDMACH2 + , (uint32_t)LPC_GPDMACH3 + , (uint32_t)LPC_GPDMACH4 + , (uint32_t)LPC_GPDMACH5 + , (uint32_t)LPC_GPDMACH6 + , (uint32_t)LPC_GPDMACH7 + }; + return lut[channel & 0xFF]; +} + +uint8_t +MODDMA::LUTPerBurst(int n) +{ + const uint8_t lut[] = { + (uint8_t)_4 // SSP0 Tx + , (uint8_t)_4 // SSP0 Rx + , (uint8_t)_4 // SSP1 Tx + , (uint8_t)_4 // SSP1 Rx + , (uint8_t)_1 // ADC + , (uint8_t)_32 // I2S channel 0 + , (uint8_t)_32 // I2S channel 1 + , (uint8_t)_1 // DAC + , (uint8_t)_1 // UART0 Tx + , (uint8_t)_1 // UART0 Rx + , (uint8_t)_1 // UART1 Tx + , (uint8_t)_1 // UART1 Rx + , (uint8_t)_1 // UART2 Tx + , (uint8_t)_1 // UART2 Rx + , (uint8_t)_1 // UART3 Tx + , (uint8_t)_1 // UART3 Rx + , (uint8_t)_1 // MAT0.0 + , (uint8_t)_1 // MAT0.1 + , (uint8_t)_1 // MAT1.0 + , (uint8_t)_1 // MAT1.1 + , (uint8_t)_1 // MAT2.0 + , (uint8_t)_1 // MAT2.1 + , (uint8_t)_1 // MAT3.0 + , (uint8_t)_1 // MAT3.1 + }; + return lut[n & 0xFFF]; +} + +uint8_t +MODDMA::LUTPerWid(int n) +{ + const uint8_t lut[] = { + (uint8_t)byte // SSP0 Tx + , (uint8_t)byte // SSP0 Rx + , (uint8_t)byte // SSP1 Tx + , (uint8_t)byte // SSP1 Rx + , (uint8_t)word // ADC + , (uint8_t)word // I2S channel 0 + , (uint8_t)word // I2S channel 1 + , (uint8_t)word // DAC + , (uint8_t)byte // UART0 Tx + , (uint8_t)byte // UART0 Rx + , (uint8_t)byte // UART1 Tx + , (uint8_t)byte // UART1 Rx + , (uint8_t)byte // UART2 Tx + , (uint8_t)byte // UART2 Rx + , (uint8_t)byte // UART3 Tx + , (uint8_t)byte // UART3 Rx + , (uint8_t)word // MAT0.0 + , (uint8_t)word // MAT0.1 + , (uint8_t)word // MAT1.0 + , (uint8_t)word // MAT1.1 + , (uint8_t)word // MAT2.0 + , (uint8_t)word // MAT2.1 + , (uint8_t)word // MAT3.0 + , (uint8_t)word // MAT3.1 + }; + return lut[n & 0xFFF]; +} + +}; // namespace AjK ends
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/INIT.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/INIT.cpp Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,69 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ + +#include "MODDMA.h" + +namespace AjK { + +extern uint32_t oldDMAHandler; +extern "C" void MODDMA_IRQHandler(void); +extern class MODDMA *moddma_p; + +void +MODDMA::init(bool isConstructorCalling, int Channels, int Tc, int Err) +{ + if (isConstructorCalling) { + if (LPC_SC->PCONP & (1UL << 29)) { + if (LPC_GPDMA->DMACConfig & 1) { + error("Only one instance of MODDMA can exist."); + } + } + LPC_SC->PCONP |= (1UL << 29); + LPC_GPDMA->DMACConfig = 1; + moddma_p = this; + for (int i = 0; i < 8; i++) { + setups[i] = (MODDMA_Config *)NULL; + } + } + + // Reset channel configuration register(s) + if (Channels & 0x01) LPC_GPDMACH0->DMACCConfig = 0; + if (Channels & 0x02) LPC_GPDMACH1->DMACCConfig = 0; + if (Channels & 0x04) LPC_GPDMACH2->DMACCConfig = 0; + if (Channels & 0x08) LPC_GPDMACH3->DMACCConfig = 0; + if (Channels & 0x10) LPC_GPDMACH4->DMACCConfig = 0; + if (Channels & 0x20) LPC_GPDMACH5->DMACCConfig = 0; + if (Channels & 0x40) LPC_GPDMACH6->DMACCConfig = 0; + if (Channels & 0x80) LPC_GPDMACH7->DMACCConfig = 0; + + /* Clear DMA interrupt and error flag */ + LPC_GPDMA->DMACIntTCClear = Tc; + LPC_GPDMA->DMACIntErrClr = Err; + + if (isConstructorCalling) { + oldDMAHandler = NVIC_GetVector(DMA_IRQn); + NVIC_SetVector(DMA_IRQn, (uint32_t)MODDMA_IRQHandler); + NVIC_EnableIRQ(DMA_IRQn); + } +} + +}; // namespace AjK ends
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/MODDMA.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/MODDMA.cpp Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,157 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ +#include "iomacros.h" +#include "MODDMA.h" + +namespace AjK { + +// Create a "hook" for our ISR to make callbacks. Set by init() +class MODDMA *moddma_p = (class MODDMA *)NULL; + +void +MODDMA::Enable(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + pChannel->DMACCConfig |= _E; +} + +bool +MODDMA::Enabled(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + return (bool)(pChannel->DMACCConfig & _E); +} + +void +MODDMA::Disable(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + pChannel->DMACCConfig &= ~(_E); +} + +bool +MODDMA::isActive(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + return (bool)( pChannel->DMACCConfig & CxConfig_A() ) ; +} + +void +MODDMA::haltChannel(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + pChannel->DMACCConfig |= CxConfig_H(); +} + +uint32_t +MODDMA::getControl(CHANNELS ChannelNumber) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber ); + return pChannel->DMACCControl; +} + +uint32_t oldDMAHandler = 0; +typedef void (*MODDMA_FN)(void); + +extern "C" void MODDMA_IRQHandler(void) { + uint32_t channel_mask; + + if (moddma_p == (class MODDMA *)NULL) { + if (oldDMAHandler) { + ((MODDMA_FN)oldDMAHandler)(); + return; + } + else { + error("Interrupt without instance"); + } + } + + for (int channel_number = 0; channel_number < 8; channel_number++) { + channel_mask = (1UL << channel_number); + if (LPC_GPDMA->DMACIntStat & channel_mask) { + if (LPC_GPDMA->DMACIntTCStat & channel_mask) { + if (moddma_p->setups[channel_number] != (MODDMA_Config *)NULL) { + moddma_p->setIrqProcessingChannel((MODDMA::CHANNELS)channel_number); + moddma_p->setIrqType(MODDMA::TcIrq); + moddma_p->setups[channel_number]->isrIntTCStat->call(); + moddma_p->isrIntTCStat.call(); + // The user callback should clear the IRQ. But if they forget + // then the Mbed will lockup. So, check to see if the IRQ has + // been dismissed, if not, we will dismiss it here. + if (LPC_GPDMA->DMACIntTCStat & channel_mask) { + LPC_GPDMA->DMACIntTCClear = channel_mask; + } + // If the user has left the channel enabled, disable it. + // Note, we don't check Active here as it may block inside + // an ISR, we just shut it down immediately. If the user + // must wait for completion they should implement their + // own ISR. But only disable if the LLI linked list register + // is null otherwise we can crap out a series of transfers. + if (moddma_p->Enabled( (MODDMA::CHANNELS)channel_number )) { + if (moddma_p->lli( (MODDMA::CHANNELS)channel_number ) == 0 ) { + moddma_p->Disable( (MODDMA::CHANNELS)channel_number ); + } + } + } + } + + if (LPC_GPDMA->DMACIntErrStat & channel_mask) { + if (moddma_p->setups[channel_number] != (MODDMA_Config *)NULL) { + moddma_p->setIrqProcessingChannel((MODDMA::CHANNELS)channel_number); + moddma_p->setIrqType(MODDMA::ErrIrq); + moddma_p->setups[channel_number]->isrIntErrStat->call(); + moddma_p->isrIntErrStat.call(); + // The user callback should clear the IRQ. But if they forget + // then the Mbed will lockup. So, check to see if the IRQ has + // been dismissed, if not, we will dismiss it here. + if (LPC_GPDMA->DMACIntErrStat & channel_mask) { + LPC_GPDMA->DMACIntErrClr = channel_mask; + } + // If the user has left the channel enabled, disable it. + // Not, we don't check Active here as it may block inside + // an ISR, we just shut it down immediately. If the user + // must wait for completion they should implement their + // own ISR. But only disable if the LLI linked list register + // is null otherwise we can crap out a series of transfers. + if (moddma_p->Enabled( (MODDMA::CHANNELS)channel_number )) { + if (moddma_p->lli( (MODDMA::CHANNELS)channel_number ) == 0 ) { + moddma_p->Disable( (MODDMA::CHANNELS)channel_number ); + } + } + } + } + } + } + + /* IRQ should be handled by now, check to make sure. */ + if (LPC_GPDMA->DMACIntStat) { + ((MODDMA_FN)oldDMAHandler)(); + LPC_GPDMA->DMACIntTCClear = (uint32_t)0xFF; /* If not, clear anyway! */ + } + if (LPC_GPDMA->DMACIntErrStat) { + ((MODDMA_FN)oldDMAHandler)(); + LPC_GPDMA->DMACIntErrClr = (uint32_t)0xFF; /* If not, clear anyway! */ + } +} + +}; // namespace AjK ends +
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/MODDMA.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/MODDMA.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,693 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. + + @file MODDMA.h + @purpose Adds DMA controller and multiple transfer configurations + @version see ChangeLog.c + @date Nov 2010 + @author Andy Kirkham +*/ + +#ifndef MODDMA_H +#define MODDMA_H + +/** @defgroup API The MODDMA API */ +/** @defgroup MISC Misc MODSERIAL functions */ +/** @defgroup INTERNALS MODSERIAL Internals */ + +#include "mbed.h" +#include "iomacros.h" + +namespace AjK { + +/** + * @brief The MODDMA configuration system + * @author Andy Kirkham + * @see http://mbed.org/cookbook/MODDMA_Config + * @see MODDMA + * @see API + * + * <b>MODDMA_Config</b> defines a configuration that can be passed to the MODDMA controller + * instance to perform a GPDMA data transfer. + */ +class MODDMA_Config { +protected: + + // ***************************************** + // From GPDMA by NXP MCU SW Application Team + // ***************************************** + + uint32_t ChannelNum; //!< DMA channel number, should be in range from 0 to 7. + uint32_t TransferSize; //!< Length/Size of transfer + uint32_t TransferWidth; //!< Transfer width - used for TransferType is GPDMA_TRANSFERTYPE_m2m only + uint32_t SrcMemAddr; //!< Physical Src Addr, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::m2p + uint32_t DstMemAddr; //!< Physical Destination Address, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::p2m + uint32_t TransferType; //!< Transfer Type + uint32_t SrcConn; //!< Peripheral Source Connection type, used in case TransferType is chosen as + uint32_t DstConn; //!< Peripheral Destination Connection type, used in case TransferType is chosen as + uint32_t DMALLI; //!< Linker List Item structure data address if there's no Linker List, set as '0' + uint32_t DMACSync; //!< DMACSync if required. + + // Mbed specifics. + +public: + + MODDMA_Config() { + isrIntTCStat = new FunctionPointer; + isrIntErrStat = new FunctionPointer; + ChannelNum = 0xFFFF; + TransferSize = 0; + TransferWidth = 0; + SrcMemAddr = 0; + DstMemAddr = 0; + TransferType = 0; + SrcConn = 0; + DstConn = 0; + DMALLI = 0; + DMACSync = 0; + } + + ~MODDMA_Config() { + delete(isrIntTCStat); + delete(isrIntErrStat); + } + + class MODDMA_Config * channelNum(uint32_t n) { ChannelNum = n & 0x7; return this; } + class MODDMA_Config * transferSize(uint32_t n) { TransferSize = n; return this; } + class MODDMA_Config * transferWidth(uint32_t n) { TransferWidth = n; return this; } + class MODDMA_Config * srcMemAddr(uint32_t n) { SrcMemAddr = n; return this; } + class MODDMA_Config * dstMemAddr(uint32_t n) { DstMemAddr = n; return this; } + class MODDMA_Config * transferType(uint32_t n) { TransferType = n; return this; } + class MODDMA_Config * srcConn(uint32_t n) { SrcConn = n; return this; } + class MODDMA_Config * dstConn(uint32_t n) { DstConn = n; return this; } + class MODDMA_Config * dmaLLI(uint32_t n) { DMALLI = n; return this; } + class MODDMA_Config * dmacSync(uint32_t n) { DMACSync = n; return this; } + + uint32_t channelNum(void) { return ChannelNum; } + uint32_t transferSize(void) { return TransferSize; } + uint32_t transferWidth(void) { return TransferWidth; } + uint32_t srcMemAddr(void) { return SrcMemAddr; } + uint32_t dstMemAddr(void) { return DstMemAddr; } + uint32_t transferType(void) { return TransferType; } + uint32_t srcConn(void) { return SrcConn; } + uint32_t dstConn(void) { return DstConn; } + uint32_t dmaLLI(void) { return DMALLI; } + uint32_t dmacSync(void) { return DMACSync; } + + /** + * Attach a callback to the TC IRQ configuration. + * + * @param fptr A function pointer to call + * @return this + */ + class MODDMA_Config * attach_tc(void (*fptr)(void)) { + isrIntTCStat->attach(fptr); + return this; + } + + /** + * Attach a callback to the ERR IRQ configuration. + * + * @param fptr A function pointer to call + * @return this + */ + class MODDMA_Config * attach_err(void (*fptr)(void)) { + isrIntErrStat->attach(fptr); + return this; + } + + /** + * Attach a callback to the TC IRQ configuration. + * + * @param tptr A template pointer to the calling object + * @param mptr A method pointer within the object to call. + * @return this + */ + template<typename T> + class MODDMA_Config * attach_tc(T* tptr, void (T::*mptr)(void)) { + if((mptr != NULL) && (tptr != NULL)) { + isrIntTCStat->attach(tptr, mptr); + } + return this; + } + + /** + * Attach a callback to the ERR IRQ configuration. + * + * @param tptr A template pointer to the calling object + * @param mptr A method pointer within the object to call. + * @return this + */ + template<typename T> + class MODDMA_Config * attach_err(T* tptr, void (T::*mptr)(void)) { + if((mptr != NULL) && (tptr != NULL)) { + isrIntErrStat->attach(tptr, mptr); + } + return this; + } + FunctionPointer *isrIntTCStat; + FunctionPointer *isrIntErrStat; +}; + +/** + * @brief The MODDMA configuration system (linked list items) + * @author Andy Kirkham + * @see http://mbed.org/cookbook/MODDMA_Config + * @see MODDMA + * @see MODDMA_Config + * @see API + */ +class MODDMA_LLI { +public: + class MODDMA_LLI *srcAddr(uint32_t n) { SrcAddr = n; return this; } + class MODDMA_LLI *dstAddr(uint32_t n) { DstAddr = n; return this; } + class MODDMA_LLI *nextLLI(uint32_t n) { NextLLI = n; return this; } + class MODDMA_LLI *control(uint32_t n) { Control = n; return this; } + uint32_t srcAddr(void) { return SrcAddr; } + uint32_t dstAddr(void) { return DstAddr; } + uint32_t nextLLI(void) { return NextLLI; } + uint32_t control(void) { return Control; } + + uint32_t SrcAddr; //!< Source Address + uint32_t DstAddr; //!< Destination address + uint32_t NextLLI; //!< Next LLI address, otherwise set to '0' + uint32_t Control; //!< GPDMA Control of this LLI +}; + + + + /** + * @brief MODDMA GPDMA Controller + * @author Andy Kirkham + * @see http://mbed.org/cookbook/MODDMA + * @see example1.cpp + * @see API + * + * <b>MODDMA</b> defines a GPDMA controller and multiple DMA configurations that allow for DMA + * transfers from memory to memory, memory to peripheral or peripheral to memory. + * + * At the heart of the library is the MODDMA class that defines a single instance controller that + * manages all the GPDMA hardware registers and interrupts. The controller can accept multiple + * configurations that define the channel transfers. Each configuration specifies the source and + * destination information and other associated parts to maintain the transfer process. + * + * Standard example: + * @code + * #include "mbed.h" + * #include "MODDMA.h" + * + * DigitalOut led1(LED1); + * Serial pc(USBTX, USBRX); // tx, rx + * MODDMA dma; + * + * int main() { + * + * // Create a string buffer to send directly to a Uart/Serial + * char s[] = "***DMA*** ABCDEFGHIJKLMNOPQRSTUVWXYZ ***DMA***"; + * + * // Create a transfer configuarion + * MODDMA_Config *config = new MODDMA_Config; + * + * // Provide a "minimal" setup for demo purposes. + * config + * ->channelNum ( MODDMA::Channel_0 ) // The DMA channel to use. + * ->srcMemAddr ( (uint32_t) &s ) // A pointer to the buffer to send. + * ->transferSize ( sizeof(s) ) // The size of that buffer. + * ->transferType ( MODDMA::m2p ) // Source is memory, destination is peripheral + * ->dstConn ( MODDMA::UART0_Tx ) // Specifically, peripheral is Uart0 TX (USBTX, USBRX) + * ; // config end. + * + * // Pass the configuration to the MODDMA controller. + * dma.Setup( config ); + * + * // Enable the channel and begin transfer. + * dma.Enable( config->channelNum() ); + * + * while(1) { + * led1 = !led1; + * wait(0.25); + * } + * } + * @endcode + */ +class MODDMA +{ +public: + + //! Channel definitions. + enum CHANNELS { + Channel_0 = 0 /*!< Channel 0 */ + , Channel_1 /*!< Channel 1 */ + , Channel_2 /*!< Channel 2 */ + , Channel_3 /*!< Channel 3 */ + , Channel_4 /*!< Channel 4 */ + , Channel_5 /*!< Channel 5 */ + , Channel_6 /*!< Channel 6 */ + , Channel_7 /*!< Channel 7 */ + }; + + //! Interrupt callback types. + enum IrqType_t { + TcIrq = 0 /*!< Terminal Count interrupt */ + , ErrIrq /*!< Error interrupt */ + }; + + //! Return status codes. + enum Status { + Ok = 0 /*!< Ok, suceeded */ + , Error = -1 /*!< General error */ + , ErrChInUse = -2 /*!< Specific error, channel in use */ + }; + + //! DMA Connection number definitions + enum GPDMA_CONNECTION { + SSP0_Tx = 0UL /*!< SSP0 Tx */ + , SSP0_Rx = 1UL /*!< SSP0 Rx */ + , SSP1_Tx = 2UL /*!< SSP1 Tx */ + , SSP1_Rx = 3UL /*!< SSP1 Rx */ + , ADC = 4UL /*!< ADC */ + , I2S_Channel_0 = 5UL /*!< I2S channel 0 */ + , I2S_Channel_1 = 6UL /*!< I2S channel 1 */ + , DAC = 7UL /*!< DAC */ + , UART0_Tx = 8UL /*!< UART0 Tx */ + , UART0_Rx = 9UL /*!< UART0 Rx */ + , UART1_Tx = 10UL /*!< UART1 Tx */ + , UART1_Rx = 11UL /*!< UART1 Rx */ + , UART2_Tx = 12UL /*!< UART2 Tx */ + , UART2_Rx = 13UL /*!< UART2 Rx */ + , UART3_Tx = 14UL /*!< UART3 Tx */ + , UART3_Rx = 15UL /*!< UART3 Rx */ + , MAT0_0 = 16UL /*!< MAT0.0 */ + , MAT0_1 = 17UL /*!< MAT0.1 */ + , MAT1_0 = 18UL /*!< MAT1.0 */ + , MAT1_1 = 19UL /*!< MAT1.1 */ + , MAT2_0 = 20UL /**< MAT2.0 */ + , MAT2_1 = 21UL /*!< MAT2.1 */ + , MAT3_0 = 22UL /*!< MAT3.0 */ + , MAT3_1 = 23UL /*!< MAT3.1 */ + }; + + //! GPDMA Transfer type definitions + enum GPDMA_TRANSFERTYPE { + m2m = 0UL /*!< Memory to memory - DMA control */ + , m2p = 1UL /*!< Memory to peripheral - DMA control */ + , p2m = 2UL /*!< Peripheral to memory - DMA control */ + , p2p = 3UL /*!< Src peripheral to dest peripheral - DMA control */ + , g2m = 4UL /*!< Psuedo special case for reading "peripheral GPIO" that's memory mapped. */ + , m2g = 5UL /*!< Psuedo Special case for writing "peripheral GPIO" that's memory mapped. */ + }; + + //! Burst size in Source and Destination definitions */ + enum GPDMA_BSIZE { + _1 = 0UL /*!< Burst size = 1 */ + , _4 = 1UL /*!< Burst size = 4 */ + , _8 = 2UL /*!< Burst size = 8 */ + , _16 = 3UL /*!< Burst size = 16 */ + , _32 = 4UL /*!< Burst size = 32 */ + , _64 = 5UL /*!< Burst size = 64 */ + , _128 = 6UL /*!< Burst size = 128 */ + , _256 = 7UL /*!< Burst size = 256 */ + }; + + //! Width in Src transfer width and Dest transfer width definitions */ + enum GPDMA_WIDTH { + byte = 0UL /*!< Width = 1 byte */ + , halfword = 1UL /*!< Width = 2 bytes */ + , word = 2UL /*!< Width = 4 bytes */ + }; + + //! DMA Request Select Mode definitions. */ + enum GPDMA_REQSEL { + uart = 0UL /*!< UART TX/RX is selected */ + , timer = 1UL /*!< Timer match is selected */ + }; + + //! GPDMA Control register bits. + enum Config { + _E = 1 /*!< DMA Controller enable */ + , _M = 2 /*!< AHB Master endianness configuration */ + }; + + //! GPDMA Channel config register bits. + enum CConfig { + _CE = (1UL << 0) /*!< Channel enable */ + , _IE = (1UL << 14) /*!< Interrupt error mask */ + , _ITC = (1UL << 15) /*!< Terminal count interrupt mask */ + , _L = (1UL << 16) /*!< Lock */ + , _A = (1UL << 17) /*!< Active */ + , _H = (1UL << 18) /*!< Halt */ + }; + + /** + * The MODDMA constructor is used to initialise the DMA controller object. + */ + MODDMA() { init(true); } + + /** + * The MODDMA destructor. + */ + ~MODDMA() {} + + /** + * Used to setup the DMA controller to prepare for a data transfer. + * + * @ingroup API + * @param isConstructorCalling Set true when called from teh constructor + * @param + */ + void init(bool isConstructorCalling, int Channels = 0xFF, int Tc = 0xFF, int Err = 0xFF); + + /** + * Used to setup and enable the DMA controller. + * + * @see Setup + * @see Enable + * @ingroup API + * @param c A pointer to an instance of MODDMA_Config to setup. + */ + uint32_t Prepare(MODDMA_Config *c) { + uint32_t u = Setup(c); + if (u) Enable(c); + return u; + } + + /** + * Used to setup the DMA controller to prepare for a data transfer. + * + * @ingroup API + * @param c A pointer to an instance of MODDMA_Config to setup. + */ + uint32_t Setup(MODDMA_Config *c); + + /** + * Enable and begin data transfer. + * + * @ingroup API + * @param ChannelNumber Type CHANNELS, the channel number to enable + */ + void Enable(CHANNELS ChannelNumber); + + /** + * Enable and begin data transfer (overloaded function) + * + * @ingroup API + * @param ChannelNumber Type uin32_t, the channel number to enable + */ + void Enable(uint32_t ChannelNumber) { Enable((CHANNELS)(ChannelNumber & 0x7)); } + + /** + * Enable and begin data transfer (overloaded function) + * + * @ingroup API + * @param config A pointer to teh configuration + */ + void Enable(MODDMA_Config *config) { Enable( config->channelNum() ); } + + + /** + * Disable a channel and end data transfer. + * + * @ingroup API + * @param ChannelNumber Type CHANNELS, the channel number to enable + */ + void Disable(CHANNELS ChannelNumber); + + /** + * Disable a channel and end data transfer (overloaded function) + * + * @ingroup API + * @param ChannelNumber Type uin32_t, the channel number to disable + */ + void Disable(uint32_t ChannelNumber) { Disable((CHANNELS)(ChannelNumber & 0x7)); } + + /** + * Is the specified channel enabled? + * + * @ingroup API + * @param ChannelNumber Type CHANNELS, the channel number to test + * @return bool true if enabled, false otherwise. + */ + bool Enabled(CHANNELS ChannelNumber); + + /** + * Is the specified channel enabled? (overloaded function) + * + * @ingroup API + * @param ChannelNumber Type uin32_t, the channel number to test + * @return bool true if enabled, false otherwise. + */ + bool Enabled(uint32_t ChannelNumber) { return Enabled((CHANNELS)(ChannelNumber & 0x7)); } + + __INLINE uint32_t IntStat(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t IntTCStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t IntTCClear_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t IntErrStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t IntErrClr_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t RawIntErrStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t EnbldChns_Ch(uint32_t n) { return (1UL << n) & 0xFF; } + __INLINE uint32_t SoftBReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; } + __INLINE uint32_t SoftSReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; } + __INLINE uint32_t SoftLBReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; } + __INLINE uint32_t SoftLSReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; } + __INLINE uint32_t Sync_Src(uint32_t n) { return (1UL << n) & 0xFFFF; } + __INLINE uint32_t ReqSel_Input(uint32_t n) { return (1UL << (n - 8)) & 0xFF; } + + + __INLINE uint32_t CxControl_TransferSize(uint32_t n) { return (n & 0xFFF) << 0; } + __INLINE uint32_t CxControl_SBSize(uint32_t n) { return (n & 0x7) << 12; } + __INLINE uint32_t CxControl_DBSize(uint32_t n) { return (n & 0x7) << 15; } + __INLINE uint32_t CxControl_SWidth(uint32_t n) { return (n & 0x7) << 18; } + __INLINE uint32_t CxControl_DWidth(uint32_t n) { return (n & 0x7) << 21; } + __INLINE uint32_t CxControl_SI() { return (1UL << 26); } + __INLINE uint32_t CxControl_DI() { return (1UL << 27); } + __INLINE uint32_t CxControl_Prot1() { return (1UL << 28); } + __INLINE uint32_t CxControl_Prot2() { return (1UL << 29); } + __INLINE uint32_t CxControl_Prot3() { return (1UL << 30); } + __INLINE uint32_t CxControl_I() { return (1UL << 31); } + __INLINE uint32_t CxControl_E() { return (1UL << 0); } + __INLINE uint32_t CxConfig_SrcPeripheral(uint32_t n) { return (n & 0x1F) << 1; } + __INLINE uint32_t CxConfig_DestPeripheral(uint32_t n) { return (n & 0x1F) << 6; } + __INLINE uint32_t CxConfig_TransferType(uint32_t n) { return (n & 0x7) << 11; } + __INLINE uint32_t CxConfig_IE() { return (1UL << 14); } + __INLINE uint32_t CxConfig_ITC() { return (1UL << 15); } + __INLINE uint32_t CxConfig_L() { return (1UL << 16); } + __INLINE uint32_t CxConfig_A() { return (1UL << 17); } + __INLINE uint32_t CxConfig_H() { return (1UL << 18); } + + /** + * A store for up to 8 (8 channels) of configurations. + * @see MODDMA_Config + */ + MODDMA_Config *setups[8]; + + /** + * Get a pointer to the current configuration the ISR is servicing. + * + * @ingroup API + * @return MODDMA_Config * A pointer to the setup the ISR is currently servicing. + */ + MODDMA_Config *getConfig(void) { return setups[IrqProcessingChannel]; } + + /** + * Set which channel the ISR is currently servicing. + * + * *** USED INTERNALLY. DO NOT CALL FROM USER PROGRAMS *** + * + * Must be public so the extern "C" ISR can use it. + */ + void setIrqProcessingChannel(CHANNELS n) { IrqProcessingChannel = n; } + + /** + * Gets which channel the ISR is currently servicing. + * + * @ingroup API + * @return CHANNELS The current channel the ISR is servicing. + */ + CHANNELS irqProcessingChannel(void) { return IrqProcessingChannel; } + + /** + * Sets which type of IRQ the ISR is making a callback for. + * + * *** USED INTERNALLY. DO NOT CALL FROM USER PROGRAMS *** + * + * Must be public so the extern "C" ISR can use it. + */ + void setIrqType(IrqType_t n) { IrqType = n; } + + /** + * Get which type of IRQ the ISR is calling you about, + * terminal count or error. + */ + IrqType_t irqType(void) { return IrqType; } + + /** + * Clear the interrupt after handling. + * + * @param CHANNELS The channel the IQR occured on. + */ + void clearTcIrq(CHANNELS n) { LPC_GPDMA->DMACIntTCClear = (uint32_t)(1UL << n); } + + /** + * Clear the interrupt the ISR is currently handing.. + */ + void clearTcIrq(void) { clearTcIrq( IrqProcessingChannel ); } + + /** + * Clear the error interrupt after handling. + * + * @ingroup API + * @param CHANNELS The channel the IQR occured on. + */ + void clearErrIrq(CHANNELS n) { LPC_GPDMA->DMACIntTCClear = (uint32_t)(1UL << n); } + + /** + * Clear the error interrupt the ISR is currently handing. + * @ingroup API + */ + void clearErrIrq(void) { clearErrIrq( IrqProcessingChannel ); } + + /** + * Is the supplied channel currently active? + * + * @ingroup API + * @param CHANNELS The channel to inquire about. + * @return bool true if active, false otherwise. + */ + bool isActive(CHANNELS ChannelNumber); + + /** + * Halt the supplied channel. + * + * @ingroup API + * @param CHANNELS The channel to halt. + */ + void haltChannel(CHANNELS ChannelNumber); + + /** + * get a channels control register. + * + * @ingroup API + * @param CHANNELS The channel to get the control register for. + */ + uint32_t getControl(CHANNELS ChannelNumber); + + /** + * Wait for channel transfer to complete and then halt. + * + * @ingroup API + * @param CHANNELS The channel to wait for then halt. + */ + void haltAndWaitChannelComplete(CHANNELS n) { haltChannel(n); while (isActive(n)); } + + /** + * Attach a callback to the TC IRQ controller. + * + * @ingroup API + * @param fptr A function pointer to call + * @return this + */ + void attach_tc(void (*fptr)(void)) { + isrIntTCStat.attach(fptr); + } + + /** + * Attach a callback to the TC IRQ controller. + * + * @ingroup API + * @param tptr A template pointer to the calling object + * @param mptr A method pointer within the object to call. + * @return this + */ + template<typename T> + void attach_tc(T* tptr, void (T::*mptr)(void)) { + if((mptr != NULL) && (tptr != NULL)) { + isrIntTCStat.attach(tptr, mptr); + } + } + + /** + * The MODDMA controllers terminal count interrupt callback. + */ + FunctionPointer isrIntTCStat; + + /** + * Attach a callback to the ERR IRQ controller. + * + * @ingroup API + * @param fptr A function pointer to call + * @return this + */ + void attach_err(void (*fptr)(void)) { + isrIntErrStat.attach(fptr); + } + + /** + * Attach a callback to the ERR IRQ controller. + * + * @ingroup API + * @param tptr A template pointer to the calling object + * @param mptr A method pointer within the object to call. + * @return this + */ + template<typename T> + void attach_err(T* tptr, void (T::*mptr)(void)) { + if((mptr != NULL) && (tptr != NULL)) { + isrIntErrStat.attach(tptr, mptr); + } + } + + /** + * Get the Linked List index regsiter for the requested channel. + * + * @param channelNum The channel number. + * @return uint32_t The value of the DMACCLLI register + */ + uint32_t lli(CHANNELS ChannelNumber, MODDMA_LLI *set = 0) { + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber & 0x7 ); + if (set) pChannel->DMACCLLI = (uint32_t)set; + return pChannel->DMACCLLI; + } + + /** + * The MODDMA controllers error interrupt callback. + */ + FunctionPointer isrIntErrStat; + + uint32_t Channel_p(int channel); + +protected: + + // Data LUTs. + uint32_t LUTPerAddr(int n); + uint8_t LUTPerBurst(int n); + uint8_t LUTPerWid(int n); + //uint32_t Channel_p(int channel); + + CHANNELS IrqProcessingChannel; + + IrqType_t IrqType; +}; + +}; // namespace AjK ends. + +using namespace AjK; + +#endif
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/SETUP.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/SETUP.cpp Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,194 @@ +/* + Copyright (c) 2010 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ + +#include "MODDMA.h" + +namespace AjK { + +uint32_t +MODDMA::Setup(MODDMA_Config *config) +{ + LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( config->channelNum() ); + + setups[config->channelNum() & 0x7] = config; + + // Reset the Interrupt status + LPC_GPDMA->DMACIntTCClear = IntTCClear_Ch( config->channelNum() ); + LPC_GPDMA->DMACIntErrClr = IntErrClr_Ch ( config->channelNum() ); + + // Clear DMA configure + pChannel->DMACCControl = 0x00; + pChannel->DMACCConfig = 0x00; + + // Assign Linker List Item value + pChannel->DMACCLLI = config->dmaLLI(); + + // Set value to Channel Control Registers + switch (config->transferType()) { + + // Memory to memory + case m2m: + // Assign physical source and destination address + pChannel->DMACCSrcAddr = config->srcMemAddr(); + pChannel->DMACCDestAddr = config->dstMemAddr(); + pChannel->DMACCControl + = CxControl_TransferSize(config->transferSize()) + | CxControl_SBSize(_32) + | CxControl_DBSize(_32) + | CxControl_SWidth(config->transferWidth()) + | CxControl_DWidth(config->transferWidth()) + | CxControl_SI() + | CxControl_DI() + | CxControl_I(); + break; + + // Memory to peripheral + case m2p: + // Assign physical source + pChannel->DMACCSrcAddr = config->srcMemAddr(); + // Assign peripheral destination address + pChannel->DMACCDestAddr = (uint32_t)LUTPerAddr(config->dstConn()); + pChannel->DMACCControl + = CxControl_TransferSize((uint32_t)config->transferSize()) + | CxControl_SBSize((uint32_t)LUTPerBurst(config->dstConn())) + | CxControl_DBSize((uint32_t)LUTPerBurst(config->dstConn())) + | CxControl_SWidth((uint32_t)LUTPerWid(config->dstConn())) + | CxControl_DWidth((uint32_t)LUTPerWid(config->dstConn())) + | CxControl_SI() + | CxControl_I(); + break; + + // Peripheral to memory + case p2m: + // Assign peripheral source address + pChannel->DMACCSrcAddr = (uint32_t)LUTPerAddr(config->srcConn()); + // Assign memory destination address + pChannel->DMACCDestAddr = config->dstMemAddr(); + pChannel->DMACCControl + = CxControl_TransferSize((uint32_t)config->transferSize()) + | CxControl_SBSize((uint32_t)LUTPerBurst(config->srcConn())) + | CxControl_DBSize((uint32_t)LUTPerBurst(config->srcConn())) + | CxControl_SWidth((uint32_t)LUTPerWid(config->srcConn())) + | CxControl_DWidth((uint32_t)LUTPerWid(config->srcConn())) + | CxControl_DI() + | CxControl_I(); + break; + + // Peripheral to peripheral + case p2p: + // Assign peripheral source address + pChannel->DMACCSrcAddr = (uint32_t)LUTPerAddr(config->srcConn()); + // Assign peripheral destination address + pChannel->DMACCDestAddr = (uint32_t)LUTPerAddr(config->dstConn()); + pChannel->DMACCControl + = CxControl_TransferSize((uint32_t)config->transferSize()) + | CxControl_SBSize((uint32_t)LUTPerBurst(config->srcConn())) + | CxControl_DBSize((uint32_t)LUTPerBurst(config->dstConn())) + | CxControl_SWidth((uint32_t)LUTPerWid(config->srcConn())) + | CxControl_DWidth((uint32_t)LUTPerWid(config->dstConn())) + | CxControl_I(); + break; + + // GPIO to memory + case g2m: + // Assign GPIO source address + pChannel->DMACCSrcAddr = config->srcMemAddr(); + // Assign memory destination address + pChannel->DMACCDestAddr = config->dstMemAddr(); + pChannel->DMACCControl + = CxControl_TransferSize((uint32_t)config->transferSize()) + | CxControl_SBSize((uint32_t)LUTPerBurst(config->srcConn())) + | CxControl_DBSize((uint32_t)LUTPerBurst(config->srcConn())) + | CxControl_SWidth((uint32_t)LUTPerWid(config->srcConn())) + | CxControl_DWidth((uint32_t)LUTPerWid(config->srcConn())) + | CxControl_DI() + | CxControl_I(); + break; + + // Memory to GPIO + case m2g: + // Assign physical source + pChannel->DMACCSrcAddr = config->srcMemAddr(); + // Assign peripheral destination address + pChannel->DMACCDestAddr = config->dstMemAddr(); + pChannel->DMACCControl + = CxControl_TransferSize((uint32_t)config->transferSize()) + | CxControl_SBSize((uint32_t)LUTPerBurst(config->dstConn())) + | CxControl_DBSize((uint32_t)LUTPerBurst(config->dstConn())) + | CxControl_SWidth((uint32_t)LUTPerWid(config->dstConn())) + | CxControl_DWidth((uint32_t)LUTPerWid(config->dstConn())) + | CxControl_SI() + | CxControl_I(); + break; + + // Do not support any more transfer type, return ERROR + default: + return 0; + } +/* + // Re-Configure DMA Request Select for source peripheral + if (config->srcConn() > 15) { + LPC_SC->RESERVED9 |= (1 << (config->srcConn() - 16)); + } + else { + LPC_SC->RESERVED9 &= ~(1 << (config->srcConn() - 8)); + } + + // Re-Configure DMA Request Select for destination peripheral + if (config->dstConn() > 15) { + LPC_SC->RESERVED9 |= (1 << (config->dstConn() - 16)); + } + else { + LPC_SC->RESERVED9 &= ~(1 << (config->dstConn() - 8)); + } +*/ + // Enable DMA channels, little endian + LPC_GPDMA->DMACConfig = _E; + while (!(LPC_GPDMA->DMACConfig & _E)); + + // Calculate absolute value for Connection number + uint32_t tmp1 = config->srcConn(); tmp1 = ((tmp1 > 15) ? (tmp1 - 8) : tmp1); + uint32_t tmp2 = config->dstConn(); tmp2 = ((tmp2 > 15) ? (tmp2 - 8) : tmp2); + + if (config->dmacSync()) { + uint32_t tmp3 = config->dmacSync(); tmp3 = ((tmp3 > 15) ? (tmp3 - 8) : tmp3); + LPC_GPDMA->DMACSync |= Sync_Src( tmp3 ); + } + + uint32_t tfer_type = (uint32_t)config->transferType(); + if (tfer_type == g2m || tfer_type == m2g) { + tfer_type -= 2; // Adjust psuedo transferType to a real transferType. + } + + // Configure DMA Channel, enable Error Counter and Terminate counter + pChannel->DMACCConfig + = CxConfig_IE() + | CxConfig_ITC() + | CxConfig_TransferType(tfer_type) + | CxConfig_SrcPeripheral(tmp1) + | CxConfig_DestPeripheral(tmp2); + + return pChannel->DMACCControl; +} + +}; // namespace AjK ends +
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/example1.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/example1.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,89 @@ +#include "mbed.h" +#include "MODDMA.h" +#include "MODSERIAL.h" + +DigitalOut led1(LED1); +DigitalOut led2(LED2); +DigitalOut led3(LED3); +DigitalOut led4(LED4); +MODDMA dma; +MODSERIAL pc(USBTX, USBRX); + +// Function prototypes for IRQ callbacks. +// See definitions following main() below. +void dmaTCCallback(void); +void dmaERRCallback(void); +void TC0_callback(void); +void ERR0_callback(void); + +int main() { + char s[] = "**DMA** ABCDEFGHIJKLMNOPQRSTUVWXYZ **DMA**"; + + pc.baud(PC_BAUD); + + dma.attach_tc( &dmaTCCallback ); + dma.attach_err( &dmaERRCallback ); + + MODDMA_Config *config = new MODDMA_Config; + config + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( (uint32_t) &s ) + ->dstMemAddr ( 0 ) + ->transferSize ( sizeof(s) ) + ->transferType ( MODDMA::m2p ) + ->transferWidth ( 0 ) + ->srcConn ( 0 ) + ->dstConn ( MODDMA::UART0_Tx ) + ->dmaLLI ( 0 ) + ->attach_tc ( &TC0_callback ) + ->attach_err ( &ERR0_callback ) + ; // config end + + // Setup the configuration. + dma.Setup(config); + + //dma.Enable( MODDMA::Channel_0 ); + //dma.Enable( config->channelNum() ); + dma.Enable( config ); + + while (1) { + led1 = !led1; + wait(0.25); + } +} + +// Main controller TC IRQ callback +void dmaTCCallback(void) { + led2 = 1; +} + +// Main controller ERR IRQ callback +void dmaERRCallback(void) { + error("Oh no! My Mbed exploded! :( Only kidding, find the problem"); +} + +// Configuration callback on TC +void TC0_callback(void) { + MODDMA_Config *config = dma.getConfig(); + dma.haltAndWaitChannelComplete( (MODDMA::CHANNELS)config->channelNum()); + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Configurations have two IRQ callbacks for TC and Err so you + // know which you are processing. However, if you want to use + // a single callback function you can tell what type of IRQ + // is being processed thus:- + if (dma.irqType() == MODDMA::TcIrq) { + led3 = 1; + dma.clearTcIrq(); + } + if (dma.irqType() == MODDMA::ErrIrq) { + led4 = 1; + dma.clearErrIrq(); + } +} + +// Configuration cakllback on Error +void ERR0_callback(void) { + error("Oh no! My Mbed exploded! :( Only kidding, find the problem"); +} +
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/example2.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/example2.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,137 @@ +/* + * This example was provided to support Mbed forum thread:- + * http://mbed.org/forum/mbed/topic/1798 + */ + +#include "mbed.h" +#include "MODDMA.h" + +#define SAMPLE_BUFFER_LENGTH 32 + +DigitalOut led1(LED1); +DigitalOut led2(LED2); + +MODDMA dma; +Serial pc(USBTX, USBRX); + +// ISR set's this when transfer complete. +bool dmaTransferComplete = false; + +// Function prototypes for IRQ callbacks. +// See definitions following main() below. +void TC0_callback(void); +void ERR0_callback(void); + +int main() { + + // Create a buffer to hold the ADC samples and clear it. + // Note, we are going to sample two ADC inputs so they + // end up in this buffer "interleaved". So you will want + // a buffer twice this size to a real life given sample + // frequency. See the printf() output for details. + uint32_t adcInputBuffer[SAMPLE_BUFFER_LENGTH]; + memset(adcInputBuffer, 0, sizeof(adcInputBuffer)); + + // We use the ADC irq to trigger DMA and the manual says + // that in this case the NVIC for ADC must be disabled. + NVIC_DisableIRQ(ADC_IRQn); + + // Power up the ADC and set PCLK + LPC_SC->PCONP |= (1UL << 12); + LPC_SC->PCLKSEL0 &= ~(3UL << 24); // PCLK = CCLK/4 96M/4 = 24MHz + + // Enable the ADC, 12MHz, ADC0.0 & .1 + LPC_ADC->ADCR = (1UL << 21) | (1UL << 8) | (3UL << 0); + + // Set the pin functions to ADC + LPC_PINCON->PINSEL1 &= ~(3UL << 14); /* P0.23, Mbed p15. */ + LPC_PINCON->PINSEL1 |= (1UL << 14); + LPC_PINCON->PINSEL1 &= ~(3UL << 16); /* P0.24, Mbed p16. */ + LPC_PINCON->PINSEL1 |= (1UL << 16); + + // Setup the serial port to print out results. + pc.baud(115200); + pc.printf("ADC with DMA example\n"); + pc.printf("====================\n"); + + // Prepare an ADC configuration. + MODDMA_Config *conf = new MODDMA_Config; + conf + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( 0 ) + ->dstMemAddr ( (uint32_t)adcInputBuffer ) + ->transferSize ( SAMPLE_BUFFER_LENGTH ) + ->transferType ( MODDMA::p2m ) + ->transferWidth ( MODDMA::word ) + ->srcConn ( MODDMA::ADC ) + ->dstConn ( 0 ) + ->dmaLLI ( 0 ) + ->attach_tc ( &TC0_callback ) + ->attach_err ( &ERR0_callback ) + ; // end conf. + + // Prepare configuration. + dma.Setup( conf ); + + // Enable configuration. + dma.Enable( conf ); + + // Enable ADC irq flag (to DMA). + // Note, don't set the individual flags, + // just set the global flag. + LPC_ADC->ADINTEN = 0x100; + + // Enable burst mode on inputs 0 and 1. + LPC_ADC->ADCR |= (1UL << 16); + + while (1) { + // When transfer complete do this block. + if (dmaTransferComplete) { + delete conf; // No memory leaks, delete the configuration. + dmaTransferComplete = false; + for (int i = 0; i < SAMPLE_BUFFER_LENGTH; i++) { + int channel = (adcInputBuffer[i] >> 24) & 0x7; + int iVal = (adcInputBuffer[i] >> 4) & 0xFFF; + double fVal = 3.3 * (double)((double)iVal) / ((double)0x1000); // scale to 0v to 3.3v + pc.printf("Array index %02d : ADC input channel %d = 0x%03x %01.3f volts\n", i, channel, iVal, fVal); + } + } + + // Just flash LED1 for something to do. + led1 = !led1; + wait(0.25); + } +} + +// Configuration callback on TC +void TC0_callback(void) { + + MODDMA_Config *config = dma.getConfig(); + + // Disbale burst mode and switch off the IRQ flag. + LPC_ADC->ADCR &= ~(1UL << 16); + LPC_ADC->ADINTEN = 0; + + // Finish the DMA cycle by shutting down the channel. + dma.haltAndWaitChannelComplete( (MODDMA::CHANNELS)config->channelNum()); + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Tell main() while(1) loop to print the results. + dmaTransferComplete = true; + + // Switch on LED2 to show transfer complete. + led2 = 1; + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); + if (dma.irqType() == MODDMA::ErrIrq) dma.clearErrIrq(); +} + +// Configuration callback on Error +void ERR0_callback(void) { + // Switch off burst conversions. + LPC_ADC->ADCR |= ~(1UL << 16); + LPC_ADC->ADINTEN = 0; + error("Oh no! My Mbed EXPLODED! :( Only kidding, go find the problem"); +} +
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/example3.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/example3.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,131 @@ +/* + * Demonstrates capturing the GPIO P0.4 to P0.7 "nibble" to memory + * using GPDMA. The transfers from port pins to memory buffer are + * triggered using Timer1 MAT1.0 match compare. + * + * In this example all inputs have pullups. So with nothing connected + * the P0.4/7 reads as 0xF. Connecting a wire from one or more of the four + * inputs to ground will show up in the captured buffer sequence. + */ + +#include "mbed.h" +#include "MODDMA.h" +#include "iomacros.h" // within MODDMA library. + +// How long between grabbing GPIO FIO0PIN register. +// Value is in microseconds. (500000 is half a second). +#define SAMPLE_PERIOD 500000 + +#define NUM_OF_SAMPLES 5 + +Serial pc(USBTX, USBRX); + +DigitalOut led1(LED1); +DigitalOut led2(LED2); +DigitalOut led3(LED3); + +uint32_t buffer[NUM_OF_SAMPLES]; + +bool dmaTransferComplete; + +MODDMA dma; +MODDMA_Config *conf; + +void TC0_callback(void); +void ERR0_callback(void); + +int main() { + volatile int life_counter = 0; + + // Macros defined in iomacros.h, saves messing with DigitalIn + p30_AS_INPUT; p30_MODE( PIN_PULLUP ); // P0.4 + p29_AS_INPUT; p29_MODE( PIN_PULLUP ); // P0.5 + p8_AS_INPUT; p8_MODE( PIN_PULLUP ); // P0.6 + p7_AS_INPUT; p7_MODE( PIN_PULLUP ); // P0.7 + + // Clear the buffer. + memset(buffer, 0, sizeof(buffer)); + + // Setup the serial port to print out results. + pc.baud(115200); + pc.printf("Starting up...\n"); + + // Set-up timer1 as a periodic timer. + LPC_SC->PCONP |= (1UL << 2); // TIM1 On + LPC_SC->PCLKSEL0 |= (3UL << 4); // CCLK/8 = 12MHz + LPC_TIM1->PR = 11; // TC clocks at 1MHz. + LPC_TIM1->MCR = 2; // Reset TCR to zero on match. + LPC_TIM1->MR0 = SAMPLE_PERIOD; + + // Prepare the GPDMA system. + conf = new MODDMA_Config; + conf + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( (uint32_t)&LPC_GPIO0->FIOPIN ) + ->dstMemAddr ( (uint32_t)&buffer[0] ) + ->transferSize ( NUM_OF_SAMPLES ) + ->transferType ( MODDMA::g2m ) // pseudo transfer code MODDMA understands. + ->transferWidth ( MODDMA::word ) + ->srcConn ( MODDMA::MAT1_0 ) + ->dmacSync ( MODDMA::MAT1_0 ) + ->attach_tc ( TC0_callback ) + ->attach_err ( ERR0_callback ) + ; // end conf. + + // Prepare configuration. + if (!dma.Setup( conf )) { + error("Doh!"); + } + + // Enable GPDMA to be ready for the TIM1 "ticks". + dma.Enable( conf ); + + // Begin. + LPC_TIM1->TCR = 1; + + while (1) { + if (life_counter++ > 1000000) { + led1 = !led1; // Show some sort of life. + life_counter = 0; + } + + if (dmaTransferComplete) { + dmaTransferComplete = false; + for (int i = 0; i < NUM_OF_SAMPLES; i++) { + int val = (buffer[i] >> 4) & 0xF; + pc.printf("Buffer index %d = 0x%x\n", i, val); + } + pc.printf("Done.\n"); + + // Schedule another grab. + if (dma.Setup( conf )) { + dma.Enable( conf ); + } + } + } +} + +// Configuration callback on TC +void TC0_callback(void) { + + // Just show sample sequence grab complete. + led3 = !led3; + + // Get configuration pointer. + MODDMA_Config *config = dma.getConfig(); + + // Finish the DMA cycle by shutting down the channel. + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Tell main() while(1) loop to print the results. + dmaTransferComplete = true; + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); + if (dma.irqType() == MODDMA::ErrIrq) dma.clearErrIrq(); +} + +// Configuration callback on Error +void ERR0_callback(void) { + error("Oh no! My Mbed EXPLODED! :( Only kidding, go find the problem"); +}
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/example4.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/example4.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,156 @@ +/* + * Demonstrates sending a buffer repeatedly to the DAC using DMA. + * Connect an oscilloscope to Mbed pin 18. This example doesn't + * output anything else (nothing on any serial ports). + */ +#include "mbed.h" +#include "MODDMA.h" + +// Make the buffer size match the number of degrees +// in a circle since we are going to output a sinewave. +#define BUFFER_SIZE 360 + +// Set DAC output power mode. +#define DAC_POWER_MODE (1 << 16) + +DigitalOut led1(LED1); +DigitalOut led3(LED3); +DigitalOut led4(LED4); + +int buffer[2][BUFFER_SIZE]; + +AnalogOut signal(p18); + +MODDMA dma; +MODDMA_Config *conf0, *conf1; + +void TC0_callback(void); +void ERR0_callback(void); + +void TC1_callback(void); +void ERR1_callback(void); + +int main() { + volatile int life_counter = 0; + + // Create a sinewave buffer for testing. + for (int i = 0; i <= 90; i++) buffer[0][i] = (512 * sin(3.14159/180.0 * i)) + 512; + for (int i = 91; i <= 180; i++) buffer[0][i] = buffer[0][180 - i]; + for (int i = 181; i <= 270; i++) buffer[0][i] = 512 - (buffer[0][i - 180] - 512); + for (int i = 271; i < 360; i++) buffer[0][i] = 512 - (buffer[0][360 - i] - 512); + + // Adjust the sinewave buffer for use with DAC hardware. + for (int i = 0; i < 360; i++) { + buffer[0][i] = DAC_POWER_MODE | ((buffer[0][i] << 6) & 0xFFC0); + buffer[1][i] = buffer[0][i]; // Just create a copy of buffer0 to continue sinewave. + } + + // Prepare the GPDMA system for buffer0. + conf0 = new MODDMA_Config; + conf0 + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( (uint32_t) &buffer[0] ) + ->dstMemAddr ( MODDMA::DAC ) + ->transferSize ( 360 ) + ->transferType ( MODDMA::m2p ) + ->dstConn ( MODDMA::DAC ) + ->attach_tc ( &TC0_callback ) + ->attach_err ( &ERR0_callback ) + ; // config end + + + // Prepare the GPDMA system for buffer1. + conf1 = new MODDMA_Config; + conf1 + ->channelNum ( MODDMA::Channel_1 ) + ->srcMemAddr ( (uint32_t) &buffer[1] ) + ->dstMemAddr ( MODDMA::DAC ) + ->transferSize ( 360 ) + ->transferType ( MODDMA::m2p ) + ->dstConn ( MODDMA::DAC ) + ->attach_tc ( &TC1_callback ) + ->attach_err ( &ERR1_callback ) + ; // config end + + + // Calculating the transfer frequency: + // By default, the Mbed library sets the PCLK_DAC clock value + // to 24MHz. One complete sinewave cycle in each buffer is 360 + // points long. So, for a 1Hz wave we would need to transfer 360 + // values per second. That would be 24000000/360 which is approx + // 66,666. But that's no good! The count val is only 16bits in size + // so bare this in mind. If you need to go slower you will need to + // alter PCLK_DAC from CCLK/4 to CCLK/8. + // For our demo we are going to have the sinewave run at 1kHz. + // That's 24000000/360000 which is approx 66. Experimentation + // however showed 65 to get closer to 1kHz (on my Mbed and scope + // at least). + LPC_DAC->DACCNTVAL = 65; // 6500 for 10Hz + + // Prepare first configuration. + if (!dma.Prepare( conf0 )) { + error("Doh!"); + } + + // Begin (enable DMA and counter). Note, don't enable + // DBLBUF_ENA as we are using DMA double buffering. + LPC_DAC->DACCTRL |= (3UL << 2); + + while (1) { + // There's not a lot to do as DMA and interrupts are + // now handling the buffer transfers. So we'll just + // flash led1 to show the Mbed is alive and kicking. + if (life_counter++ > 1000000) { + led1 = !led1; // Show some sort of life. + life_counter = 0; + } + } +} + +// Configuration callback on TC +void TC0_callback(void) { + + // Just show sending buffer0 complete. + led3 = !led3; + + // Get configuration pointer. + MODDMA_Config *config = dma.getConfig(); + + // Finish the DMA cycle by shutting down the channel. + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Swap to buffer1 + dma.Prepare( conf1 ); + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); +} + +// Configuration callback on Error +void ERR0_callback(void) { + error("Oh no! My Mbed EXPLODED! :( Only kidding, go find the problem"); +} + +// Configuration callback on TC +void TC1_callback(void) { + + // Just show sending buffer1 complete. + led4 = !led4; + + // Get configuration pointer. + MODDMA_Config *config = dma.getConfig(); + + // Finish the DMA cycle by shutting down the channel. + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Swap to buffer0 + dma.Prepare( conf0 ); + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); +} + +// Configuration callback on Error +void ERR1_callback(void) { + error("Oh no! My Mbed EXPLODED! :( Only kidding, go find the problem"); +}
diff -r a7b1803dfa44 -r a3e0f7f37ac9 MODDMA/iomacros.h --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/MODDMA/iomacros.h Wed Dec 05 07:56:09 2012 +0000 @@ -0,0 +1,418 @@ +/* + Copyright (c) 2011 Andy Kirkham + + Permission is hereby granted, free of charge, to any person obtaining a copy + of this software and associated documentation files (the "Software"), to deal + in the Software without restriction, including without limitation the rights + to use, copy, modify, merge, publish, distribute, sublicense, and/or sell + copies of the Software, and to permit persons to whom the Software is + furnished to do so, subject to the following conditions: + + The above copyright notice and this permission notice shall be included in + all copies or substantial portions of the Software. + + THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR + IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, + FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE + AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER + LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, + OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN + THE SOFTWARE. +*/ + +#ifndef IOMACROS_H +#define IOMACROS_H + +#ifndef __LPC17xx_H__ +#include "LPC17xx.h" +#endif + +#define PIN_PULLUP 0UL +#define PIN_REPEAT 1UL +#define PIN_NONE 2UL +#define PIN_PULLDOWN 3UL + +/* p5 is P0.9 */ +#define p5_SEL_MASK ~(3UL << 18) +#define p5_SET_MASK (1UL << 9) +#define p5_CLR_MASK ~(p5_SET_MASK) +#define p5_AS_OUTPUT LPC_PINCON->PINSEL0&=p5_SEL_MASK;LPC_GPIO0->FIODIR|=p5_SET_MASK +#define p5_AS_INPUT LPC_GPIO0->FIOMASK &= p5_CLR_MASK; +#define p5_SET LPC_GPIO0->FIOSET = p5_SET_MASK +#define p5_CLR LPC_GPIO0->FIOCLR = p5_SET_MASK +#define p5_IS_SET (bool)(LPC_GPIO0->FIOPIN & p5_SET_MASK) +#define p5_IS_CLR !(p5_IS_SET) +#define p5_MODE(x) LPC_PINCON->PINMODE0&=p5_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<18) + +/* p6 is P0.8 */ +#define p6_SEL_MASK ~(3UL << 16) +#define p6_SET_MASK (1UL << 8) +#define p6_CLR_MASK ~(p6_SET_MASK) +#define p6_AS_OUTPUT LPC_PINCON->PINSEL0&=p6_SEL_MASK;LPC_GPIO0->FIODIR|=p6-SET_MASK +#define p6_AS_INPUT LPC_GPIO0->FIOMASK &= p6_CLR_MASK; +#define p6_SET LPC_GPIO0->FIOSET = p6_SET_MASK +#define p6_CLR LPC_GPIO0->FIOCLR = p6_SET_MASK +#define p6_IS_SET (bool)(LPC_GPIO0->FIOPIN & p6_SET_MASK) +#define p6_IS_CLR !(p6_IS_SET) +#define p6_MODE(x) LPC_PINCON->PINMODE0&=p6_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<16) + +/* p7 is P0.7 */ +#define p7_SEL_MASK ~(3UL << 14) +#define p7_SET_MASK (1UL << 7) +#define p7_CLR_MASK ~(p7_SET_MASK) +#define p7_AS_OUTPUT LPC_PINCON->PINSEL0&=p7_SEL_MASK;LPC_GPIO0->FIODIR|=p7_SET_MASK +#define p7_AS_INPUT LPC_GPIO0->FIOMASK &= p7_CLR_MASK; +#define p7_SET LPC_GPIO0->FIOSET = p7_SET_MASK +#define p7_CLR LPC_GPIO0->FIOCLR = p7_SET_MASK +#define p7_IS_SET (bool)(LPC_GPIO0->FIOPIN & p7_SET_MASK) +#define p7_IS_CLR !(p7_IS_SET) +#define p7_MODE(x) LPC_PINCON->PINMODE0&=p7_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<14) + +/* p8 is P0.6 */ +#define p8_SEL_MASK ~(3UL << 12) +#define p8_SET_MASK (1UL << 6) +#define p8_CLR_MASK ~(p8_SET_MASK) +#define p8_AS_OUTPUT LPC_PINCON->PINSEL0&=p8_SEL_MASK;LPC_GPIO0->FIODIR|=p8_SET_MASK +#define p8_AS_INPUT LPC_GPIO0->FIOMASK &= p8_CLR_MASK; +#define p8_SET LPC_GPIO0->FIOSET = p8_SET_MASK +#define p8_CLR LPC_GPIO0->FIOCLR = p8_SET_MASK +#define p8_IS_SET (bool)(LPC_GPIO0->FIOPIN & p8_SET_MASK) +#define p8_IS_CLR !(p8_IS_SET) +#define p8_MODE(x) LPC_PINCON->PINMODE0&=p8_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<12) + +/* p9 is P0.0 */ +#define p9_SEL_MASK ~(3UL << 0) +#define p9_SET_MASK (1UL << 0) +#define p9_CLR_MASK ~(p9_SET_MASK) +#define p9_AS_OUTPUT LPC_PINCON->PINSEL0&=p9_SEL_MASK;LPC_GPIO0->FIODIR|=p9_SET_MASK +#define p9_AS_INPUT LPC_GPIO0->FIOMASK &= p9_CLR_MASK; +#define p9_SET LPC_GPIO0->FIOSET = p9_SET_MASK +#define p9_CLR LPC_GPIO0->FIOCLR = p9_SET_MASK +#define p9_IS_SET (bool)(LPC_GPIO0->FIOPIN & p9_SET_MASK) +#define p9_IS_CLR !(p9_IS_SET) +#define p9_MODE(x) LPC_PINCON->PINMODE0&=p9_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<0) + +/* p10 is P0.1 */ +#define p10_SEL_MASK ~(3UL << 2) +#define p10_SET_MASK (1UL << 1) +#define p10_CLR_MASK ~(p10_SET_MASK) +#define p10_AS_OUTPUT LPC_PINCON->PINSEL0&=p10_SEL_MASK;LPC_GPIO0->FIODIR|=p10_SET_MASK +#define p10_AS_INPUT LPC_GPIO0->FIOMASK &= p10_CLR_MASK; +#define p10_SET LPC_GPIO0->FIOSET = p10_SET_MASK +#define p10_CLR LPC_GPIO0->FIOCLR = p10_SET_MASK +#define p10_IS_SET (bool)(LPC_GPIO0->FIOPIN & p10_SET_MASK) +#define p10_IS_CLR !(p10_IS_SET) +#define p10_MODE(x) LPC_PINCON->PINMODE0&=p10_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<2) + +/* p11 is P0.18 */ +#define p11_SEL_MASK ~(3UL << 4) +#define p11_SET_MASK (1UL << 18) +#define p11_CLR_MASK ~(p11_SET_MASK) +#define p11_AS_OUTPUT LPC_PINCON->PINSEL1&=p11_SEL_MASK;LPC_GPIO0->FIODIR|=p11_SET_MASK +#define p11_AS_INPUT LPC_GPIO0->FIOMASK &= p11_CLR_MASK; +#define p11_SET LPC_GPIO0->FIOSET = p11_SET_MASK +#define p11_CLR LPC_GPIO0->FIOCLR = p11_SET_MASK +#define p11_IS_SET (bool)(LPC_GPIO0->FIOPIN & p11_SET_MASK) +#define p11_IS_CLR !(p11_IS_SET) +#define p11_MODE(x) LPC_PINCON->PINMODE1&=p11_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<4) + +/* p12 is P0.17 */ +#define p12_SEL_MASK ~(3UL << 2) +#define p12_SET_MASK (1UL << 17) +#define p12_CLR_MASK ~(p12_SET_MASK) +#define p12_AS_OUTPUT LPC_PINCON->PINSEL1&=p12_SEL_MASK;LPC_GPIO0->FIODIR|=p12_SET_MASK +#define p12_AS_INPUT LPC_GPIO0->FIOMASK &= p12_CLR_MASK; +#define p12_SET LPC_GPIO0->FIOSET = p12_SET_MASK +#define p12_CLR LPC_GPIO0->FIOCLR = p12_SET_MASK +#define p12_IS_SET (bool)(LPC_GPIO0->FIOPIN & p12_SET_MASK) +#define p12_IS_CLR !(p12_IS_SET) +#define p12_MODE(x) LPC_PINCON->PINMODE1&=p12_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<2) + +/* p13 is P0.15 */ +#define p13_SEL_MASK ~(3UL << 30) +#define p13_SET_MASK (1UL << 15) +#define p13_CLR_MASK ~(p13_SET_MASK) +#define p13_AS_OUTPUT LPC_PINCON->PINSEL0&=p13_SEL_MASK;LPC_GPIO0->FIODIR|=p13_SET_MASK +#define p13_AS_INPUT LPC_GPIO0->FIOMASK &= p13_CLR_MASK; +#define p13_SET LPC_GPIO0->FIOSET = p13_SET_MASK +#define p13_CLR LPC_GPIO0->FIOCLR = p13_SET_MASK +#define p13_IS_SET (bool)(LPC_GPIO0->FIOPIN & p13_SET_MASK) +#define p13_IS_CLR !(p13_IS_SET) +#define p13_MODE(x) LPC_PINCON->PINMODE0&=p13_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<30) + +/* p14 is P0.16 */ +#define p14_SEL_MASK ~(3UL << 0) +#define p14_SET_MASK (1UL << 16) +#define p14_CLR_MASK ~(p14_SET_MASK) +#define p14_AS_OUTPUT LPC_PINCON->PINSEL1&=p14_SEL_MASK;LPC_GPIO0->FIODIR|=p14_SET_MASK +#define p14_AS_INPUT LPC_GPIO0->FIOMASK &= p14_CLR_MASK; +#define p14_SET LPC_GPIO0->FIOSET = p14_SET_MASK +#define p14_CLR LPC_GPIO0->FIOCLR = p14_SET_MASK +#define p14_IS_SET (bool)(LPC_GPIO0->FIOPIN & p14_SET_MASK) +#define p14_IS_CLR !(p14_IS_SET) +#define p14_MODE(x) LPC_PINCON->PINMODE1&=p14_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<0) + +/* p15 is P0.23 */ +#define p15_SEL_MASK ~(3UL << 14) +#define p15_SET_MASK (1UL << 23) +#define p15_CLR_MASK ~(p15_SET_MASK) +#define p15_AS_OUTPUT LPC_PINCON->PINSEL1&=p15_SEL_MASK;LPC_GPIO0->FIODIR|=p15_SET_MASK +#define p15_AS_INPUT LPC_GPIO0->FIOMASK &= p15_CLR_MASK; +#define p15_SET LPC_GPIO0->FIOSET = p15_SET_MASK +#define p15_CLR LPC_GPIO0->FIOCLR = p15_SET_MASK +#define p15_IS_SET (bool)(LPC_GPIO0->FIOPIN & p15_SET_MASK) +#define p15_IS_CLR !(p15_IS_SET) +#define p15_MODE(x) LPC_PINCON->PINMODE1&=p15_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<14) + +/* p16 is P0.24 */ +#define p16_SEL_MASK ~(3UL << 16) +#define p16_SET_MASK (1UL << 24) +#define p16_CLR_MASK ~(p16_SET_MASK) +#define p16_AS_OUTPUT LPC_PINCON->PINSEL1&=p16_SEL_MASK;LPC_GPIO0->FIODIR|=p16_SET_MASK +#define p16_AS_INPUT LPC_GPIO0->FIOMASK &= p16_CLR_MASK; +#define p16_SET LPC_GPIO0->FIOSET = p16_SET_MASK +#define p16_CLR LPC_GPIO0->FIOCLR = p16_SET_MASK +#define p16_IS_SET (bool)(LPC_GPIO0->FIOPIN & p16_SET_MASK) +#define p16_IS_CLR !(p16_IS_SET) +#define p16_MODE(x) LPC_PINCON->PINMODE1&=p16_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<16) + +/* p17 is P0.25 */ +#define p17_SEL_MASK ~(3UL << 18) +#define p17_SET_MASK (1UL << 25) +#define p17_CLR_MASK ~(p17_SET_MASK) +#define p17_AS_OUTPUT LPC_PINCON->PINSEL1&=p17_SEL_MASK;LPC_GPIO0->FIODIR|=p17_SET_MASK +#define p17_AS_INPUT LPC_GPIO0->FIOMASK &= p17_CLR_MASK; +#define p17_SET LPC_GPIO0->FIOSET = p17_SET_MASK +#define p17_CLR LPC_GPIO0->FIOCLR = p17_SET_MASK +#define p17_IS_SET (bool)(LPC_GPIO0->FIOPIN & p17_SET_MASK) +#define p17_IS_CLR !(p17_IS_SET) +#define p17_MODE(x) LPC_PINCON->PINMODE1&=p17_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<18) + +/* p18 is P0.26 */ +#define p18_SEL_MASK ~(3UL << 20) +#define p18_SET_MASK (1UL << 26) +#define p18_CLR_MASK ~(p18_SET_MASK) +#define p18_AS_OUTPUT LPC_PINCON->PINSEL1&=p18_SEL_MASK;LPC_GPIO0->FIODIR|=p18_SET_MASK +#define p18_AS_INPUT LPC_GPIO0->FIOMASK &= p18_CLR_MASK; +#define p18_SET LPC_GPIO0->FIOSET = p18_SET_MASK +#define p18_CLR LPC_GPIO0->FIOCLR = p18_SET_MASK +#define p18_IS_SET (bool)(LPC_GPIO0->FIOPIN & p18_SET_MASK) +#define p18_IS_CLR !(p18_IS_SET) +#define p18_MODE(x) LPC_PINCON->PINMODE1&=p18_SEL_MASK;LPC_PINCON->PINMODE1|=((x&0x3)<<20) + +/* p19 is P1.30 */ +#define p19_SEL_MASK ~(3UL << 28) +#define p19_SET_MASK (1UL << 30) +#define p19_AS_OUTPUT LPC_PINCON->PINSEL3&=p19_SEL_MASK;LPC_GPIO1->FIODIR|=p19_SET_MASK +#define p19_AS_INPUT LPC_GPIO1->FIOMASK &= p19_CLR_MASK; +#define p19_SET LPC_GPIO1->FIOSET = p19_SET_MASK +#define p19_CLR LPC_GPIO1->FIOCLR = p19_SET_MASK +#define p19_IS_SET (bool)(LPC_GPIO1->FIOPIN & p19_SET_MASK) +#define p19_IS_CLR !(p19_IS_SET) +#define p19_MODE(x) LPC_PINCON->PINMODE3&=p19_SEL_MASK;LPC_PINCON->PINMODE3|=((x&0x3)<<28) + +/* p20 is P1.31 */ +#define p20_SEL_MASK ~(3UL << 30) +#define p20_SET_MASK (1UL << 31) +#define p20_CLR_MASK ~(p20_SET_MASK) +#define p20_AS_OUTPUT LPC_PINCON->PINSEL3&=p20_SEL_MASK;LPC_GPIO1->FIODIR|=p20_SET_MASK +#define p20_AS_INPUT LPC_GPIO1->FIOMASK &= p20_CLR_MASK; +#define p20_SET LPC_GPIO1->FIOSET = p20_SET_MASK +#define p20_CLR LPC_GPIO1->FIOCLR = p20_SET_MASK +#define p20_IS_SET (bool)(LPC_GPIO1->FIOPIN & p20_SET_MASK) +#define p20_IS_CLR !(p20_IS_SET) +#define p20_MODE(x) LPC_PINCON->PINMODE3&=p20_SEL_MASK;LPC_PINCON->PINMODE3|=((x&0x3)<<30) + +/* p21 is P2.5 */ +#define p21_SEL_MASK ~(3UL << 10) +#define p21_SET_MASK (1UL << 5) +#define p21_CLR_MASK ~(p21_SET_MASK) +#define p21_AS_OUTPUT LPC_PINCON->PINSEL4&=p21_SEL_MASK;LPC_GPIO2->FIODIR|=p21_SET_MASK +#define p21_AS_INPUT LPC_GPIO2->FIOMASK &= p21_CLR_MASK; +#define p21_SET LPC_GPIO2->FIOSET = p21_SET_MASK +#define p21_CLR LPC_GPIO2->FIOCLR = p21_SET_MASK +#define p21_IS_SET (bool)(LPC_GPIO2->FIOPIN & p21_SET_MASK) +#define p21_IS_CLR !(p21_IS_SET) +#define p21_TOGGLE p21_IS_SET?p21_CLR:p21_SET +#define p21_MODE(x) LPC_PINCON->PINMODE4&=p21_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<10) + +/* p22 is P2.4 */ +#define p22_SEL_MASK ~(3UL << 8) +#define p22_SET_MASK (1UL << 4) +#define p22_CLR_MASK ~(p22_SET_MASK) +#define p22_AS_OUTPUT LPC_PINCON->PINSEL4&=p22_SEL_MASK;LPC_GPIO2->FIODIR|=p22_SET_MASK +#define p22_AS_INPUT LPC_GPIO2->FIOMASK &= p22_CLR_MASK; +#define p22_SET LPC_GPIO2->FIOSET = p22_SET_MASK +#define p22_CLR LPC_GPIO2->FIOCLR = p22_SET_MASK +#define p22_IS_SET (bool)(LPC_GPIO2->FIOPIN & p22_SET_MASK) +#define p22_IS_CLR !(p22_IS_SET) +#define p22_TOGGLE p22_IS_SET?p22_CLR:p22_SET +#define p22_MODE(x) LPC_PINCON->PINMODE4&=p22_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<8) + +/* p23 is P2.3 */ +#define p23_SEL_MASK ~(3UL << 6) +#define p23_SET_MASK (1UL << 3) +#define p23_CLR_MASK ~(p23_SET_MASK) +#define p23_AS_OUTPUT LPC_PINCON->PINSEL4&=p23_SEL_MASK;LPC_GPIO2->FIODIR|=p23_SET_MASK +#define p23_AS_INPUT LPC_GPIO2->FIOMASK &= p23_CLR_MASK; +#define p23_SET LPC_GPIO2->FIOSET = p23_SET_MASK +#define p23_CLR LPC_GPIO2->FIOCLR = p23_SET_MASK +#define p23_IS_SET (bool)(LPC_GPIO2->FIOPIN & p23_SET_MASK) +#define p23_IS_CLR !(p23_IS_SET) +#define p23_TOGGLE p23_IS_SET?p23_CLR:p23_SET +#define p23_MODE(x) LPC_PINCON->PINMODE4&=p23_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<6) + +/* p24 is P2.2 */ +#define p24_SEL_MASK ~(3UL << 4) +#define p24_SET_MASK (1UL << 2) +#define p24_CLR_MASK ~(p24_SET_MASK) +#define p24_AS_OUTPUT LPC_PINCON->PINSEL4&=p24_SEL_MASK;LPC_GPIO2->FIODIR|=p24_SET_MASK +#define p24_AS_INPUT LPC_GPIO2->FIOMASK &= p24_CLR_MASK; +#define p24_SET LPC_GPIO2->FIOSET = p24_SET_MASK +#define p24_CLR LPC_GPIO2->FIOCLR = p24_SET_MASK +#define p24_IS_SET (bool)(LPC_GPIO2->FIOPIN & p24_SET_MASK) +#define p24_IS_CLR !(p24_IS_SET) +#define p24_TOGGLE p24_IS_SET?p24_CLR:p24_SET +#define p24_MODE(x) LPC_PINCON->PINMODE4&=p24_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<4) + +/* p25 is P2.1 */ +#define p25_SEL_MASK ~(3UL << 2) +#define p25_SET_MASK (1UL << 1) +#define p25_CLR_MASK ~(p25_SET_MASK) +#define p25_AS_OUTPUT LPC_PINCON->PINSEL4&=p25_SEL_MASK;LPC_GPIO2->FIODIR|=p25_SET_MASK +#define p25_AS_INPUT LPC_GPIO2->FIOMASK &= p25_CLR_MASK; +#define p25_SET LPC_GPIO2->FIOSET = p25_SET_MASK +#define p25_CLR LPC_GPIO2->FIOCLR = p25_SET_MASK +#define p25_IS_SET (bool)(LPC_GPIO2->FIOPIN & p25_SET_MASK) +#define p25_IS_CLR !(p25_IS_SET) +#define p25_MODE(x) LPC_PINCON->PINMODE4&=p25_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<2) + +/* p26 is P2.0 */ +#define p26_SEL_MASK ~(3UL << 0) +#define p26_SET_MASK (1UL << 0) +#define p26_CLR_MASK ~(p26_SET_MASK) +#define p26_AS_OUTPUT LPC_PINCON->PINSEL4&=p26_SEL_MASK;LPC_GPIO2->FIODIR|=p26_SET_MASK +#define p26_AS_INPUT LPC_GPIO2->FIOMASK &= p26_CLR_MASK; +#define p26_SET LPC_GPIO2->FIOSET = p26_SET_MASK +#define p26_CLR LPC_GPIO2->FIOCLR = p26_SET_MASK +#define p26_IS_SET (bool)(LPC_GPIO2->FIOPIN & p26_SET_MASK) +#define p26_IS_CLR !(p26_IS_SET) +#define p26_MODE(x) LPC_PINCON->PINMODE4&=p26_SEL_MASK;LPC_PINCON->PINMODE4|=((x&0x3)<<0) + +/* p27 is P0.11 */ +#define p27_SEL_MASK ~(3UL << 22) +#define p27_SET_MASK (1UL << 11) +#define p27_CLR_MASK ~(p27_SET_MASK) +#define p27_AS_OUTPUT LPC_PINCON->PINSEL0&=p27_SEL_MASK;LPC_GPIO0->FIODIR|=p27_SET_MASK +#define p27_AS_INPUT LPC_GPIO0->FIOMASK &= p27_CLR_MASK; +#define p27_SET LPC_GPIO0->FIOSET = p27_SET_MASK +#define p27_CLR LPC_GPIO0->FIOCLR = p27_SET_MASK +#define p27_IS_SET (bool)(LPC_GPIO0->FIOPIN & p27_SET_MASK) +#define p27_IS_CLR !(p27_IS_SET) +#define p27_MODE(x) LPC_PINCON->PINMODE0&=p27_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<22) + +/* p28 is P0.10 */ +#define p28_SEL_MASK ~(3UL << 20) +#define p28_SET_MASK (1UL << 10) +#define p28_CLR_MASK ~(p28_SET_MASK) +#define p28_AS_OUTPUT LPC_PINCON->PINSEL0&=p28_SEL_MASK;LPC_GPIO0->FIODIR|=p28_SET_MASK +#define p28_AS_INPUT LPC_GPIO0->FIOMASK &= p28_CLR_MASK; +#define p28_SET LPC_GPIO0->FIOSET = p28_SET_MASK +#define p28_CLR LPC_GPIO0->FIOCLR = p28_SET_MASK +#define p28_IS_SET (bool)(LPC_GPIO0->FIOPIN & p28_SET_MASK) +#define p28_IS_CLR !(p28_IS_SET) +#define p28_MODE(x) LPC_PINCON->PINMODE0&=p28_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<20) + +/* p29 is P0.5 */ +#define p29_SEL_MASK ~(3UL << 10) +#define p29_SET_MASK (1UL << 5) +#define p29_CLR_MASK ~(p29_SET_MASK) +#define p29_AS_OUTPUT LPC_PINCON->PINSEL0&=p29_SEL_MASK;LPC_GPIO0->FIODIR|=p29_SET_MASK +#define p29_AS_INPUT LPC_GPIO0->FIOMASK &= p29_CLR_MASK; +#define p29_SET LPC_GPIO0->FIOSET = p29_SET_MASK +#define p29_CLR LPC_GPIO0->FIOCLR = p29_SET_MASK +#define p29_IS_SET (bool)(LPC_GPIO0->FIOPIN & p29_SET_MASK) +#define p29_IS_CLR !(p29_IS_SET) +#define p29_TOGGLE p29_IS_SET?p29_CLR:p29_SET +#define p29_MODE(x) LPC_PINCON->PINMODE0&=p29_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<10) + +/* p30 is P0.4 */ +#define p30_SEL_MASK ~(3UL << 8) +#define p30_SET_MASK (1UL << 4) +#define p30_CLR_MASK ~(p30_SET_MASK) +#define p30_AS_OUTPUT LPC_PINCON->PINSEL0&=p30_SEL_MASK;LPC_GPIO0->FIODIR|=p30_SET_MASK +#define p30_AS_INPUT LPC_GPIO0->FIOMASK &= p30_CLR_MASK; +#define p30_SET LPC_GPIO0->FIOSET = p30_SET_MASK +#define p30_CLR LPC_GPIO0->FIOCLR = p30_SET_MASK +#define p30_IS_SET (bool)(LPC_GPIO0->FIOPIN & p30_SET_MASK) +#define p30_IS_CLR !(p30_IS_SET) +#define p30_MODE(x) LPC_PINCON->PINMODE0&=p30_SEL_MASK;LPC_PINCON->PINMODE0|=((x&0x3)<<8) + +/* The following definitions are for the four Mbed LEDs. + LED1 = P1.18 + LED2 = P1.20 + LED3 = P1.21 + LED4 = P1.23 */ + +#define P1_18_SEL_MASK ~(3UL << 4) +#define P1_18_SET_MASK (1UL << 18) +#define P1_18_CLR_MASK ~(P1_18_SET_MASK) +#define P1_18_AS_OUTPUT LPC_PINCON->PINSEL3&=P1_18_SEL_MASK;LPC_GPIO1->FIODIR|=P1_18_SET_MASK +#define P1_18_AS_INPUT LPC_GPIO1->FIOMASK &= P1_18_CLR_MASK; +#define P1_18_SET LPC_GPIO1->FIOSET = P1_18_SET_MASK +#define P1_18_CLR LPC_GPIO1->FIOCLR = P1_18_SET_MASK +#define P1_18_IS_SET (bool)(LPC_GPIO1->FIOPIN & P1_18_SET_MASK) +#define P1_18_IS_CLR !(P1_18_IS_SET) +#define LED1_USE P1_18_AS_OUTPUT;P1_18_AS_INPUT +#define LED1_ON P1_18_SET +#define LED1_OFF P1_18_CLR +#define LED1_IS_ON P1_18_IS_SET +#define LED1_TOGGLE P1_18_IS_SET?LED1_OFF:LED1_ON + +#define P1_20_SEL_MASK ~(3UL << 8) +#define P1_20_SET_MASK (1UL << 20) +#define P1_20_CLR_MASK ~(P1_20_SET_MASK) +#define P1_20_AS_OUTPUT LPC_PINCON->PINSEL3&=P1_20_SEL_MASK;LPC_GPIO1->FIODIR|=P1_20_SET_MASK +#define P1_20_AS_INPUT LPC_GPIO1->FIOMASK &= P1_20_CLR_MASK; +#define P1_20_SET LPC_GPIO1->FIOSET = P1_20_SET_MASK +#define P1_20_CLR LPC_GPIO1->FIOCLR = P1_20_SET_MASK +#define P1_20_IS_SET (bool)(LPC_GPIO1->FIOPIN & P1_20_SET_MASK) +#define P1_20_IS_CLR !(P1_20_IS_SET) +#define LED2_USE P1_20_AS_OUTPUT;P1_20_AS_INPUT +#define LED2_ON P1_20_SET +#define LED2_OFF P1_20_CLR +#define LED2_IS_ON P1_20_IS_SET +#define LED2_TOGGLE P1_20_IS_SET?LED2_OFF:LED2_ON + +#define P1_21_SEL_MASK ~(3UL << 10) +#define P1_21_SET_MASK (1UL << 21) +#define P1_21_CLR_MASK ~(P1_21_SET_MASK) +#define P1_21_AS_OUTPUT LPC_PINCON->PINSEL3&=P1_21_SEL_MASK;LPC_GPIO1->FIODIR|=P1_21_SET_MASK +#define P1_21_AS_INPUT LPC_GPIO1->FIOMASK &= P1_21_CLR_MASK; +#define P1_21_SET LPC_GPIO1->FIOSET = P1_21_SET_MASK +#define P1_21_CLR LPC_GPIO1->FIOCLR = P1_21_SET_MASK +#define P1_21_IS_SET (bool)(LPC_GPIO1->FIOPIN & P1_21_SET_MASK) +#define P1_21_IS_CLR !(P1_21_IS_SET) +#define LED3_USE P1_21_AS_OUTPUT;P1_21_AS_INPUT +#define LED3_ON P1_21_SET +#define LED3_OFF P1_21_CLR +#define LED3_IS_ON P1_21_IS_SET +#define LED3_TOGGLE P1_21_IS_SET?LED3_OFF:LED3_ON + +#define P1_23_SEL_MASK ~(3UL << 14) +#define P1_23_SET_MASK (1UL << 23) +#define P1_23_CLR_MASK ~(P1_23_SET_MASK) +#define P1_23_AS_OUTPUT LPC_PINCON->PINSEL3&=P1_23_SEL_MASK;LPC_GPIO1->FIODIR|=P1_23_SET_MASK +#define P1_23_AS_INPUT LPC_GPIO1->FIOMASK &= P1_23_CLR_MASK; +#define P1_23_SET LPC_GPIO1->FIOSET = P1_23_SET_MASK +#define P1_23_CLR LPC_GPIO1->FIOCLR = P1_23_SET_MASK +#define P1_23_IS_SET (bool)(LPC_GPIO1->FIOPIN & P1_23_SET_MASK) +#define P1_23_IS_CLR !(P1_23_IS_SET) +#define LED4_USE P1_23_AS_OUTPUT;P1_23_AS_INPUT +#define LED4_ON P1_23_SET +#define LED4_OFF P1_23_CLR +#define LED4_IS_ON P1_23_IS_SET +#define LED4_TOGGLE P1_23_IS_SET?LED4_OFF:LED4_ON + +#endif +
diff -r a7b1803dfa44 -r a3e0f7f37ac9 main.cpp --- a/main.cpp Fri Nov 09 06:23:54 2012 +0000 +++ b/main.cpp Wed Dec 05 07:56:09 2012 +0000 @@ -1,8 +1,12 @@ /* * SPI RAM 23LC1024 (Microchip) * 1Mbit + * with DMA ( http://mbed.org/users/AjK/code/MODDMA/ ) */ #include "mbed.h" +#include "MODDMA.h" + +#define ENABLE_DMA #define CMD_READ 0x03 #define CMD_WRITE 0x02 @@ -13,20 +17,96 @@ Serial pc(USBTX, USBRX); SPI spi(p11, p12, p13); // mosi, miso, sclk -DigitalOut cs(p17), hold(p18); +DigitalOut cs(p14); + +MODDMA dma; +MODDMA_Config *dmacfg0 = NULL, *dmacfg1 = NULL; +DigitalOut led2(LED2), led3(LED3), led4(LED4); +volatile int dmaexit; + +extern "C" void HardFault_Handler() { + register unsigned int _msp __asm("msp"); + printf("Hard Fault! address: %08x\r\n", *((unsigned int *)(_msp + 24))); + exit(-1); +} + +void tc0_callback () { + led2 = 1; + + MODDMA_Config *config = dma.getConfig(); + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); + if (dma.irqType() == MODDMA::ErrIrq) dma.clearErrIrq(); +} + +void tc1_callback () { + dmaexit = 1; + led3 = 1; + + MODDMA_Config *config = dma.getConfig(); + dma.Disable( (MODDMA::CHANNELS)config->channelNum() ); + + // Clear DMA IRQ flags. + if (dma.irqType() == MODDMA::TcIrq) dma.clearTcIrq(); + if (dma.irqType() == MODDMA::ErrIrq) dma.clearErrIrq(); +} + +void err_callback () { + dmaexit = 1; + led4 = 1; + printf("err\r\n"); +} int ram_write (int addr, char *buf, int len) { int i; + char dummy[len]; cs = 0; spi.write(CMD_WRITE); spi.write((addr >> 16) & 0xff); spi.write((addr >> 8) & 0xff); spi.write(addr & 0xff); + +#ifdef ENABLE_DMA + dmacfg0 + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( (uint32_t)buf ) + ->dstMemAddr ( MODDMA::SSP0_Tx ) + ->transferSize ( len ) + ->transferType ( MODDMA::m2p ) + ->dstConn ( MODDMA::SSP0_Tx ) + ->attach_tc ( &tc0_callback ) + ->attach_err ( &err_callback ) + ; // config end + dmacfg1 + ->channelNum ( MODDMA::Channel_1 ) + ->srcMemAddr ( MODDMA::SSP0_Rx ) + ->dstMemAddr ( (uint32_t)dummy ) + ->transferSize ( len ) + ->transferType ( MODDMA::p2m ) + ->srcConn ( MODDMA::SSP0_Rx ) + ->attach_tc ( &tc1_callback ) + ->attach_err ( &err_callback ) + ; // config end + + if (dma.Setup( dmacfg0 ) && dma.Setup( dmacfg1 )) { + dmaexit = 0; + LPC_SSP0->DMACR = (1<<1)|(1<<0); // TX,RXDMAE + dma.Enable( dmacfg0 ); + dma.Enable( dmacfg1 ); + while (! dmaexit); + } else { + printf("error\r\n"); + } + LPC_SSP0->DMACR = 0; +#else for (i = 0; i < len; i ++) { spi.write(buf[i]); } +#endif cs = 1; return i; } @@ -40,9 +120,44 @@ spi.write((addr >> 8) & 0xff); spi.write(addr & 0xff); +#ifdef ENABLE_DMA + dmacfg0 + ->channelNum ( MODDMA::Channel_0 ) + ->srcMemAddr ( (uint32_t)buf ) + ->dstMemAddr ( MODDMA::SSP0_Tx ) + ->transferSize ( len ) + ->transferType ( MODDMA::m2p ) + ->dstConn ( MODDMA::SSP0_Tx ) + ->attach_tc ( &tc0_callback ) + ->attach_err ( &err_callback ) + ; // config end + + dmacfg1 + ->channelNum ( MODDMA::Channel_1 ) + ->srcMemAddr ( MODDMA::SSP0_Rx ) + ->dstMemAddr ( (uint32_t)buf ) + ->transferSize ( len ) + ->transferType ( MODDMA::p2m ) + ->srcConn ( MODDMA::SSP0_Rx ) + ->attach_tc ( &tc1_callback ) + ->attach_err ( &err_callback ) + ; // config end + + if (dma.Setup( dmacfg0 ) && dma.Setup( dmacfg1 )) { + dmaexit = 0; + LPC_SSP0->DMACR = (1<<1)|(1<<0); // TX,RXDMAE + dma.Enable( dmacfg0 ); + dma.Enable( dmacfg1 ); + while (! dmaexit); + } else { + printf("error\r\n"); + } + LPC_SSP0->DMACR = 0; +#else for (i = 0; i < len; i ++) { buf[i] = spi.write(0); } +#endif cs = 1; return i; } @@ -53,11 +168,14 @@ Timer t; cs = 1; - hold = 1; +#ifdef ENABLE_DMA + dmacfg0 = new MODDMA_Config; + dmacfg1 = new MODDMA_Config; +#endif pc.baud(115200); spi.frequency(16000000); wait_ms(500); - + cs = 0; spi.write(CMD_RDMR); printf("RAM mode: %02x\r\n", spi.write(0)); @@ -72,7 +190,7 @@ for (i = 0; i < 256; i ++) { buf[i] = i; } - ram_write(6, buf, 256); + ram_write(8, buf, 200); wait(1); memset(buf, 0, 256);