SPI RAM 23LC1024 (Microchip) with DMA

Dependencies:   mbed

Fork of SPIRAM_23LC1024 by Suga koubou

Committer:
okini3939
Date:
Wed Dec 05 07:56:09 2012 +0000
Revision:
2:a3e0f7f37ac9
DMX

Who changed what in which revision?

UserRevisionLine numberNew contents of line
okini3939 2:a3e0f7f37ac9 1 /*
okini3939 2:a3e0f7f37ac9 2 Copyright (c) 2010 Andy Kirkham
okini3939 2:a3e0f7f37ac9 3
okini3939 2:a3e0f7f37ac9 4 Permission is hereby granted, free of charge, to any person obtaining a copy
okini3939 2:a3e0f7f37ac9 5 of this software and associated documentation files (the "Software"), to deal
okini3939 2:a3e0f7f37ac9 6 in the Software without restriction, including without limitation the rights
okini3939 2:a3e0f7f37ac9 7 to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
okini3939 2:a3e0f7f37ac9 8 copies of the Software, and to permit persons to whom the Software is
okini3939 2:a3e0f7f37ac9 9 furnished to do so, subject to the following conditions:
okini3939 2:a3e0f7f37ac9 10
okini3939 2:a3e0f7f37ac9 11 The above copyright notice and this permission notice shall be included in
okini3939 2:a3e0f7f37ac9 12 all copies or substantial portions of the Software.
okini3939 2:a3e0f7f37ac9 13
okini3939 2:a3e0f7f37ac9 14 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
okini3939 2:a3e0f7f37ac9 15 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
okini3939 2:a3e0f7f37ac9 16 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
okini3939 2:a3e0f7f37ac9 17 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
okini3939 2:a3e0f7f37ac9 18 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
okini3939 2:a3e0f7f37ac9 19 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
okini3939 2:a3e0f7f37ac9 20 THE SOFTWARE.
okini3939 2:a3e0f7f37ac9 21
okini3939 2:a3e0f7f37ac9 22 @file MODDMA.h
okini3939 2:a3e0f7f37ac9 23 @purpose Adds DMA controller and multiple transfer configurations
okini3939 2:a3e0f7f37ac9 24 @version see ChangeLog.c
okini3939 2:a3e0f7f37ac9 25 @date Nov 2010
okini3939 2:a3e0f7f37ac9 26 @author Andy Kirkham
okini3939 2:a3e0f7f37ac9 27 */
okini3939 2:a3e0f7f37ac9 28
okini3939 2:a3e0f7f37ac9 29 #ifndef MODDMA_H
okini3939 2:a3e0f7f37ac9 30 #define MODDMA_H
okini3939 2:a3e0f7f37ac9 31
okini3939 2:a3e0f7f37ac9 32 /** @defgroup API The MODDMA API */
okini3939 2:a3e0f7f37ac9 33 /** @defgroup MISC Misc MODSERIAL functions */
okini3939 2:a3e0f7f37ac9 34 /** @defgroup INTERNALS MODSERIAL Internals */
okini3939 2:a3e0f7f37ac9 35
okini3939 2:a3e0f7f37ac9 36 #include "mbed.h"
okini3939 2:a3e0f7f37ac9 37 #include "iomacros.h"
okini3939 2:a3e0f7f37ac9 38
okini3939 2:a3e0f7f37ac9 39 namespace AjK {
okini3939 2:a3e0f7f37ac9 40
okini3939 2:a3e0f7f37ac9 41 /**
okini3939 2:a3e0f7f37ac9 42 * @brief The MODDMA configuration system
okini3939 2:a3e0f7f37ac9 43 * @author Andy Kirkham
okini3939 2:a3e0f7f37ac9 44 * @see http://mbed.org/cookbook/MODDMA_Config
okini3939 2:a3e0f7f37ac9 45 * @see MODDMA
okini3939 2:a3e0f7f37ac9 46 * @see API
okini3939 2:a3e0f7f37ac9 47 *
okini3939 2:a3e0f7f37ac9 48 * <b>MODDMA_Config</b> defines a configuration that can be passed to the MODDMA controller
okini3939 2:a3e0f7f37ac9 49 * instance to perform a GPDMA data transfer.
okini3939 2:a3e0f7f37ac9 50 */
okini3939 2:a3e0f7f37ac9 51 class MODDMA_Config {
okini3939 2:a3e0f7f37ac9 52 protected:
okini3939 2:a3e0f7f37ac9 53
okini3939 2:a3e0f7f37ac9 54 // *****************************************
okini3939 2:a3e0f7f37ac9 55 // From GPDMA by NXP MCU SW Application Team
okini3939 2:a3e0f7f37ac9 56 // *****************************************
okini3939 2:a3e0f7f37ac9 57
okini3939 2:a3e0f7f37ac9 58 uint32_t ChannelNum; //!< DMA channel number, should be in range from 0 to 7.
okini3939 2:a3e0f7f37ac9 59 uint32_t TransferSize; //!< Length/Size of transfer
okini3939 2:a3e0f7f37ac9 60 uint32_t TransferWidth; //!< Transfer width - used for TransferType is GPDMA_TRANSFERTYPE_m2m only
okini3939 2:a3e0f7f37ac9 61 uint32_t SrcMemAddr; //!< Physical Src Addr, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::m2p
okini3939 2:a3e0f7f37ac9 62 uint32_t DstMemAddr; //!< Physical Destination Address, used in case TransferType is chosen as MODDMA::GPDMA_TRANSFERTYPE::m2m or MODDMA::GPDMA_TRANSFERTYPE::p2m
okini3939 2:a3e0f7f37ac9 63 uint32_t TransferType; //!< Transfer Type
okini3939 2:a3e0f7f37ac9 64 uint32_t SrcConn; //!< Peripheral Source Connection type, used in case TransferType is chosen as
okini3939 2:a3e0f7f37ac9 65 uint32_t DstConn; //!< Peripheral Destination Connection type, used in case TransferType is chosen as
okini3939 2:a3e0f7f37ac9 66 uint32_t DMALLI; //!< Linker List Item structure data address if there's no Linker List, set as '0'
okini3939 2:a3e0f7f37ac9 67 uint32_t DMACSync; //!< DMACSync if required.
okini3939 2:a3e0f7f37ac9 68
okini3939 2:a3e0f7f37ac9 69 // Mbed specifics.
okini3939 2:a3e0f7f37ac9 70
okini3939 2:a3e0f7f37ac9 71 public:
okini3939 2:a3e0f7f37ac9 72
okini3939 2:a3e0f7f37ac9 73 MODDMA_Config() {
okini3939 2:a3e0f7f37ac9 74 isrIntTCStat = new FunctionPointer;
okini3939 2:a3e0f7f37ac9 75 isrIntErrStat = new FunctionPointer;
okini3939 2:a3e0f7f37ac9 76 ChannelNum = 0xFFFF;
okini3939 2:a3e0f7f37ac9 77 TransferSize = 0;
okini3939 2:a3e0f7f37ac9 78 TransferWidth = 0;
okini3939 2:a3e0f7f37ac9 79 SrcMemAddr = 0;
okini3939 2:a3e0f7f37ac9 80 DstMemAddr = 0;
okini3939 2:a3e0f7f37ac9 81 TransferType = 0;
okini3939 2:a3e0f7f37ac9 82 SrcConn = 0;
okini3939 2:a3e0f7f37ac9 83 DstConn = 0;
okini3939 2:a3e0f7f37ac9 84 DMALLI = 0;
okini3939 2:a3e0f7f37ac9 85 DMACSync = 0;
okini3939 2:a3e0f7f37ac9 86 }
okini3939 2:a3e0f7f37ac9 87
okini3939 2:a3e0f7f37ac9 88 ~MODDMA_Config() {
okini3939 2:a3e0f7f37ac9 89 delete(isrIntTCStat);
okini3939 2:a3e0f7f37ac9 90 delete(isrIntErrStat);
okini3939 2:a3e0f7f37ac9 91 }
okini3939 2:a3e0f7f37ac9 92
okini3939 2:a3e0f7f37ac9 93 class MODDMA_Config * channelNum(uint32_t n) { ChannelNum = n & 0x7; return this; }
okini3939 2:a3e0f7f37ac9 94 class MODDMA_Config * transferSize(uint32_t n) { TransferSize = n; return this; }
okini3939 2:a3e0f7f37ac9 95 class MODDMA_Config * transferWidth(uint32_t n) { TransferWidth = n; return this; }
okini3939 2:a3e0f7f37ac9 96 class MODDMA_Config * srcMemAddr(uint32_t n) { SrcMemAddr = n; return this; }
okini3939 2:a3e0f7f37ac9 97 class MODDMA_Config * dstMemAddr(uint32_t n) { DstMemAddr = n; return this; }
okini3939 2:a3e0f7f37ac9 98 class MODDMA_Config * transferType(uint32_t n) { TransferType = n; return this; }
okini3939 2:a3e0f7f37ac9 99 class MODDMA_Config * srcConn(uint32_t n) { SrcConn = n; return this; }
okini3939 2:a3e0f7f37ac9 100 class MODDMA_Config * dstConn(uint32_t n) { DstConn = n; return this; }
okini3939 2:a3e0f7f37ac9 101 class MODDMA_Config * dmaLLI(uint32_t n) { DMALLI = n; return this; }
okini3939 2:a3e0f7f37ac9 102 class MODDMA_Config * dmacSync(uint32_t n) { DMACSync = n; return this; }
okini3939 2:a3e0f7f37ac9 103
okini3939 2:a3e0f7f37ac9 104 uint32_t channelNum(void) { return ChannelNum; }
okini3939 2:a3e0f7f37ac9 105 uint32_t transferSize(void) { return TransferSize; }
okini3939 2:a3e0f7f37ac9 106 uint32_t transferWidth(void) { return TransferWidth; }
okini3939 2:a3e0f7f37ac9 107 uint32_t srcMemAddr(void) { return SrcMemAddr; }
okini3939 2:a3e0f7f37ac9 108 uint32_t dstMemAddr(void) { return DstMemAddr; }
okini3939 2:a3e0f7f37ac9 109 uint32_t transferType(void) { return TransferType; }
okini3939 2:a3e0f7f37ac9 110 uint32_t srcConn(void) { return SrcConn; }
okini3939 2:a3e0f7f37ac9 111 uint32_t dstConn(void) { return DstConn; }
okini3939 2:a3e0f7f37ac9 112 uint32_t dmaLLI(void) { return DMALLI; }
okini3939 2:a3e0f7f37ac9 113 uint32_t dmacSync(void) { return DMACSync; }
okini3939 2:a3e0f7f37ac9 114
okini3939 2:a3e0f7f37ac9 115 /**
okini3939 2:a3e0f7f37ac9 116 * Attach a callback to the TC IRQ configuration.
okini3939 2:a3e0f7f37ac9 117 *
okini3939 2:a3e0f7f37ac9 118 * @param fptr A function pointer to call
okini3939 2:a3e0f7f37ac9 119 * @return this
okini3939 2:a3e0f7f37ac9 120 */
okini3939 2:a3e0f7f37ac9 121 class MODDMA_Config * attach_tc(void (*fptr)(void)) {
okini3939 2:a3e0f7f37ac9 122 isrIntTCStat->attach(fptr);
okini3939 2:a3e0f7f37ac9 123 return this;
okini3939 2:a3e0f7f37ac9 124 }
okini3939 2:a3e0f7f37ac9 125
okini3939 2:a3e0f7f37ac9 126 /**
okini3939 2:a3e0f7f37ac9 127 * Attach a callback to the ERR IRQ configuration.
okini3939 2:a3e0f7f37ac9 128 *
okini3939 2:a3e0f7f37ac9 129 * @param fptr A function pointer to call
okini3939 2:a3e0f7f37ac9 130 * @return this
okini3939 2:a3e0f7f37ac9 131 */
okini3939 2:a3e0f7f37ac9 132 class MODDMA_Config * attach_err(void (*fptr)(void)) {
okini3939 2:a3e0f7f37ac9 133 isrIntErrStat->attach(fptr);
okini3939 2:a3e0f7f37ac9 134 return this;
okini3939 2:a3e0f7f37ac9 135 }
okini3939 2:a3e0f7f37ac9 136
okini3939 2:a3e0f7f37ac9 137 /**
okini3939 2:a3e0f7f37ac9 138 * Attach a callback to the TC IRQ configuration.
okini3939 2:a3e0f7f37ac9 139 *
okini3939 2:a3e0f7f37ac9 140 * @param tptr A template pointer to the calling object
okini3939 2:a3e0f7f37ac9 141 * @param mptr A method pointer within the object to call.
okini3939 2:a3e0f7f37ac9 142 * @return this
okini3939 2:a3e0f7f37ac9 143 */
okini3939 2:a3e0f7f37ac9 144 template<typename T>
okini3939 2:a3e0f7f37ac9 145 class MODDMA_Config * attach_tc(T* tptr, void (T::*mptr)(void)) {
okini3939 2:a3e0f7f37ac9 146 if((mptr != NULL) && (tptr != NULL)) {
okini3939 2:a3e0f7f37ac9 147 isrIntTCStat->attach(tptr, mptr);
okini3939 2:a3e0f7f37ac9 148 }
okini3939 2:a3e0f7f37ac9 149 return this;
okini3939 2:a3e0f7f37ac9 150 }
okini3939 2:a3e0f7f37ac9 151
okini3939 2:a3e0f7f37ac9 152 /**
okini3939 2:a3e0f7f37ac9 153 * Attach a callback to the ERR IRQ configuration.
okini3939 2:a3e0f7f37ac9 154 *
okini3939 2:a3e0f7f37ac9 155 * @param tptr A template pointer to the calling object
okini3939 2:a3e0f7f37ac9 156 * @param mptr A method pointer within the object to call.
okini3939 2:a3e0f7f37ac9 157 * @return this
okini3939 2:a3e0f7f37ac9 158 */
okini3939 2:a3e0f7f37ac9 159 template<typename T>
okini3939 2:a3e0f7f37ac9 160 class MODDMA_Config * attach_err(T* tptr, void (T::*mptr)(void)) {
okini3939 2:a3e0f7f37ac9 161 if((mptr != NULL) && (tptr != NULL)) {
okini3939 2:a3e0f7f37ac9 162 isrIntErrStat->attach(tptr, mptr);
okini3939 2:a3e0f7f37ac9 163 }
okini3939 2:a3e0f7f37ac9 164 return this;
okini3939 2:a3e0f7f37ac9 165 }
okini3939 2:a3e0f7f37ac9 166 FunctionPointer *isrIntTCStat;
okini3939 2:a3e0f7f37ac9 167 FunctionPointer *isrIntErrStat;
okini3939 2:a3e0f7f37ac9 168 };
okini3939 2:a3e0f7f37ac9 169
okini3939 2:a3e0f7f37ac9 170 /**
okini3939 2:a3e0f7f37ac9 171 * @brief The MODDMA configuration system (linked list items)
okini3939 2:a3e0f7f37ac9 172 * @author Andy Kirkham
okini3939 2:a3e0f7f37ac9 173 * @see http://mbed.org/cookbook/MODDMA_Config
okini3939 2:a3e0f7f37ac9 174 * @see MODDMA
okini3939 2:a3e0f7f37ac9 175 * @see MODDMA_Config
okini3939 2:a3e0f7f37ac9 176 * @see API
okini3939 2:a3e0f7f37ac9 177 */
okini3939 2:a3e0f7f37ac9 178 class MODDMA_LLI {
okini3939 2:a3e0f7f37ac9 179 public:
okini3939 2:a3e0f7f37ac9 180 class MODDMA_LLI *srcAddr(uint32_t n) { SrcAddr = n; return this; }
okini3939 2:a3e0f7f37ac9 181 class MODDMA_LLI *dstAddr(uint32_t n) { DstAddr = n; return this; }
okini3939 2:a3e0f7f37ac9 182 class MODDMA_LLI *nextLLI(uint32_t n) { NextLLI = n; return this; }
okini3939 2:a3e0f7f37ac9 183 class MODDMA_LLI *control(uint32_t n) { Control = n; return this; }
okini3939 2:a3e0f7f37ac9 184 uint32_t srcAddr(void) { return SrcAddr; }
okini3939 2:a3e0f7f37ac9 185 uint32_t dstAddr(void) { return DstAddr; }
okini3939 2:a3e0f7f37ac9 186 uint32_t nextLLI(void) { return NextLLI; }
okini3939 2:a3e0f7f37ac9 187 uint32_t control(void) { return Control; }
okini3939 2:a3e0f7f37ac9 188
okini3939 2:a3e0f7f37ac9 189 uint32_t SrcAddr; //!< Source Address
okini3939 2:a3e0f7f37ac9 190 uint32_t DstAddr; //!< Destination address
okini3939 2:a3e0f7f37ac9 191 uint32_t NextLLI; //!< Next LLI address, otherwise set to '0'
okini3939 2:a3e0f7f37ac9 192 uint32_t Control; //!< GPDMA Control of this LLI
okini3939 2:a3e0f7f37ac9 193 };
okini3939 2:a3e0f7f37ac9 194
okini3939 2:a3e0f7f37ac9 195
okini3939 2:a3e0f7f37ac9 196
okini3939 2:a3e0f7f37ac9 197 /**
okini3939 2:a3e0f7f37ac9 198 * @brief MODDMA GPDMA Controller
okini3939 2:a3e0f7f37ac9 199 * @author Andy Kirkham
okini3939 2:a3e0f7f37ac9 200 * @see http://mbed.org/cookbook/MODDMA
okini3939 2:a3e0f7f37ac9 201 * @see example1.cpp
okini3939 2:a3e0f7f37ac9 202 * @see API
okini3939 2:a3e0f7f37ac9 203 *
okini3939 2:a3e0f7f37ac9 204 * <b>MODDMA</b> defines a GPDMA controller and multiple DMA configurations that allow for DMA
okini3939 2:a3e0f7f37ac9 205 * transfers from memory to memory, memory to peripheral or peripheral to memory.
okini3939 2:a3e0f7f37ac9 206 *
okini3939 2:a3e0f7f37ac9 207 * At the heart of the library is the MODDMA class that defines a single instance controller that
okini3939 2:a3e0f7f37ac9 208 * manages all the GPDMA hardware registers and interrupts. The controller can accept multiple
okini3939 2:a3e0f7f37ac9 209 * configurations that define the channel transfers. Each configuration specifies the source and
okini3939 2:a3e0f7f37ac9 210 * destination information and other associated parts to maintain the transfer process.
okini3939 2:a3e0f7f37ac9 211 *
okini3939 2:a3e0f7f37ac9 212 * Standard example:
okini3939 2:a3e0f7f37ac9 213 * @code
okini3939 2:a3e0f7f37ac9 214 * #include "mbed.h"
okini3939 2:a3e0f7f37ac9 215 * #include "MODDMA.h"
okini3939 2:a3e0f7f37ac9 216 *
okini3939 2:a3e0f7f37ac9 217 * DigitalOut led1(LED1);
okini3939 2:a3e0f7f37ac9 218 * Serial pc(USBTX, USBRX); // tx, rx
okini3939 2:a3e0f7f37ac9 219 * MODDMA dma;
okini3939 2:a3e0f7f37ac9 220 *
okini3939 2:a3e0f7f37ac9 221 * int main() {
okini3939 2:a3e0f7f37ac9 222 *
okini3939 2:a3e0f7f37ac9 223 * // Create a string buffer to send directly to a Uart/Serial
okini3939 2:a3e0f7f37ac9 224 * char s[] = "***DMA*** ABCDEFGHIJKLMNOPQRSTUVWXYZ ***DMA***";
okini3939 2:a3e0f7f37ac9 225 *
okini3939 2:a3e0f7f37ac9 226 * // Create a transfer configuarion
okini3939 2:a3e0f7f37ac9 227 * MODDMA_Config *config = new MODDMA_Config;
okini3939 2:a3e0f7f37ac9 228 *
okini3939 2:a3e0f7f37ac9 229 * // Provide a "minimal" setup for demo purposes.
okini3939 2:a3e0f7f37ac9 230 * config
okini3939 2:a3e0f7f37ac9 231 * ->channelNum ( MODDMA::Channel_0 ) // The DMA channel to use.
okini3939 2:a3e0f7f37ac9 232 * ->srcMemAddr ( (uint32_t) &s ) // A pointer to the buffer to send.
okini3939 2:a3e0f7f37ac9 233 * ->transferSize ( sizeof(s) ) // The size of that buffer.
okini3939 2:a3e0f7f37ac9 234 * ->transferType ( MODDMA::m2p ) // Source is memory, destination is peripheral
okini3939 2:a3e0f7f37ac9 235 * ->dstConn ( MODDMA::UART0_Tx ) // Specifically, peripheral is Uart0 TX (USBTX, USBRX)
okini3939 2:a3e0f7f37ac9 236 * ; // config end.
okini3939 2:a3e0f7f37ac9 237 *
okini3939 2:a3e0f7f37ac9 238 * // Pass the configuration to the MODDMA controller.
okini3939 2:a3e0f7f37ac9 239 * dma.Setup( config );
okini3939 2:a3e0f7f37ac9 240 *
okini3939 2:a3e0f7f37ac9 241 * // Enable the channel and begin transfer.
okini3939 2:a3e0f7f37ac9 242 * dma.Enable( config->channelNum() );
okini3939 2:a3e0f7f37ac9 243 *
okini3939 2:a3e0f7f37ac9 244 * while(1) {
okini3939 2:a3e0f7f37ac9 245 * led1 = !led1;
okini3939 2:a3e0f7f37ac9 246 * wait(0.25);
okini3939 2:a3e0f7f37ac9 247 * }
okini3939 2:a3e0f7f37ac9 248 * }
okini3939 2:a3e0f7f37ac9 249 * @endcode
okini3939 2:a3e0f7f37ac9 250 */
okini3939 2:a3e0f7f37ac9 251 class MODDMA
okini3939 2:a3e0f7f37ac9 252 {
okini3939 2:a3e0f7f37ac9 253 public:
okini3939 2:a3e0f7f37ac9 254
okini3939 2:a3e0f7f37ac9 255 //! Channel definitions.
okini3939 2:a3e0f7f37ac9 256 enum CHANNELS {
okini3939 2:a3e0f7f37ac9 257 Channel_0 = 0 /*!< Channel 0 */
okini3939 2:a3e0f7f37ac9 258 , Channel_1 /*!< Channel 1 */
okini3939 2:a3e0f7f37ac9 259 , Channel_2 /*!< Channel 2 */
okini3939 2:a3e0f7f37ac9 260 , Channel_3 /*!< Channel 3 */
okini3939 2:a3e0f7f37ac9 261 , Channel_4 /*!< Channel 4 */
okini3939 2:a3e0f7f37ac9 262 , Channel_5 /*!< Channel 5 */
okini3939 2:a3e0f7f37ac9 263 , Channel_6 /*!< Channel 6 */
okini3939 2:a3e0f7f37ac9 264 , Channel_7 /*!< Channel 7 */
okini3939 2:a3e0f7f37ac9 265 };
okini3939 2:a3e0f7f37ac9 266
okini3939 2:a3e0f7f37ac9 267 //! Interrupt callback types.
okini3939 2:a3e0f7f37ac9 268 enum IrqType_t {
okini3939 2:a3e0f7f37ac9 269 TcIrq = 0 /*!< Terminal Count interrupt */
okini3939 2:a3e0f7f37ac9 270 , ErrIrq /*!< Error interrupt */
okini3939 2:a3e0f7f37ac9 271 };
okini3939 2:a3e0f7f37ac9 272
okini3939 2:a3e0f7f37ac9 273 //! Return status codes.
okini3939 2:a3e0f7f37ac9 274 enum Status {
okini3939 2:a3e0f7f37ac9 275 Ok = 0 /*!< Ok, suceeded */
okini3939 2:a3e0f7f37ac9 276 , Error = -1 /*!< General error */
okini3939 2:a3e0f7f37ac9 277 , ErrChInUse = -2 /*!< Specific error, channel in use */
okini3939 2:a3e0f7f37ac9 278 };
okini3939 2:a3e0f7f37ac9 279
okini3939 2:a3e0f7f37ac9 280 //! DMA Connection number definitions
okini3939 2:a3e0f7f37ac9 281 enum GPDMA_CONNECTION {
okini3939 2:a3e0f7f37ac9 282 SSP0_Tx = 0UL /*!< SSP0 Tx */
okini3939 2:a3e0f7f37ac9 283 , SSP0_Rx = 1UL /*!< SSP0 Rx */
okini3939 2:a3e0f7f37ac9 284 , SSP1_Tx = 2UL /*!< SSP1 Tx */
okini3939 2:a3e0f7f37ac9 285 , SSP1_Rx = 3UL /*!< SSP1 Rx */
okini3939 2:a3e0f7f37ac9 286 , ADC = 4UL /*!< ADC */
okini3939 2:a3e0f7f37ac9 287 , I2S_Channel_0 = 5UL /*!< I2S channel 0 */
okini3939 2:a3e0f7f37ac9 288 , I2S_Channel_1 = 6UL /*!< I2S channel 1 */
okini3939 2:a3e0f7f37ac9 289 , DAC = 7UL /*!< DAC */
okini3939 2:a3e0f7f37ac9 290 , UART0_Tx = 8UL /*!< UART0 Tx */
okini3939 2:a3e0f7f37ac9 291 , UART0_Rx = 9UL /*!< UART0 Rx */
okini3939 2:a3e0f7f37ac9 292 , UART1_Tx = 10UL /*!< UART1 Tx */
okini3939 2:a3e0f7f37ac9 293 , UART1_Rx = 11UL /*!< UART1 Rx */
okini3939 2:a3e0f7f37ac9 294 , UART2_Tx = 12UL /*!< UART2 Tx */
okini3939 2:a3e0f7f37ac9 295 , UART2_Rx = 13UL /*!< UART2 Rx */
okini3939 2:a3e0f7f37ac9 296 , UART3_Tx = 14UL /*!< UART3 Tx */
okini3939 2:a3e0f7f37ac9 297 , UART3_Rx = 15UL /*!< UART3 Rx */
okini3939 2:a3e0f7f37ac9 298 , MAT0_0 = 16UL /*!< MAT0.0 */
okini3939 2:a3e0f7f37ac9 299 , MAT0_1 = 17UL /*!< MAT0.1 */
okini3939 2:a3e0f7f37ac9 300 , MAT1_0 = 18UL /*!< MAT1.0 */
okini3939 2:a3e0f7f37ac9 301 , MAT1_1 = 19UL /*!< MAT1.1 */
okini3939 2:a3e0f7f37ac9 302 , MAT2_0 = 20UL /**< MAT2.0 */
okini3939 2:a3e0f7f37ac9 303 , MAT2_1 = 21UL /*!< MAT2.1 */
okini3939 2:a3e0f7f37ac9 304 , MAT3_0 = 22UL /*!< MAT3.0 */
okini3939 2:a3e0f7f37ac9 305 , MAT3_1 = 23UL /*!< MAT3.1 */
okini3939 2:a3e0f7f37ac9 306 };
okini3939 2:a3e0f7f37ac9 307
okini3939 2:a3e0f7f37ac9 308 //! GPDMA Transfer type definitions
okini3939 2:a3e0f7f37ac9 309 enum GPDMA_TRANSFERTYPE {
okini3939 2:a3e0f7f37ac9 310 m2m = 0UL /*!< Memory to memory - DMA control */
okini3939 2:a3e0f7f37ac9 311 , m2p = 1UL /*!< Memory to peripheral - DMA control */
okini3939 2:a3e0f7f37ac9 312 , p2m = 2UL /*!< Peripheral to memory - DMA control */
okini3939 2:a3e0f7f37ac9 313 , p2p = 3UL /*!< Src peripheral to dest peripheral - DMA control */
okini3939 2:a3e0f7f37ac9 314 , g2m = 4UL /*!< Psuedo special case for reading "peripheral GPIO" that's memory mapped. */
okini3939 2:a3e0f7f37ac9 315 , m2g = 5UL /*!< Psuedo Special case for writing "peripheral GPIO" that's memory mapped. */
okini3939 2:a3e0f7f37ac9 316 };
okini3939 2:a3e0f7f37ac9 317
okini3939 2:a3e0f7f37ac9 318 //! Burst size in Source and Destination definitions */
okini3939 2:a3e0f7f37ac9 319 enum GPDMA_BSIZE {
okini3939 2:a3e0f7f37ac9 320 _1 = 0UL /*!< Burst size = 1 */
okini3939 2:a3e0f7f37ac9 321 , _4 = 1UL /*!< Burst size = 4 */
okini3939 2:a3e0f7f37ac9 322 , _8 = 2UL /*!< Burst size = 8 */
okini3939 2:a3e0f7f37ac9 323 , _16 = 3UL /*!< Burst size = 16 */
okini3939 2:a3e0f7f37ac9 324 , _32 = 4UL /*!< Burst size = 32 */
okini3939 2:a3e0f7f37ac9 325 , _64 = 5UL /*!< Burst size = 64 */
okini3939 2:a3e0f7f37ac9 326 , _128 = 6UL /*!< Burst size = 128 */
okini3939 2:a3e0f7f37ac9 327 , _256 = 7UL /*!< Burst size = 256 */
okini3939 2:a3e0f7f37ac9 328 };
okini3939 2:a3e0f7f37ac9 329
okini3939 2:a3e0f7f37ac9 330 //! Width in Src transfer width and Dest transfer width definitions */
okini3939 2:a3e0f7f37ac9 331 enum GPDMA_WIDTH {
okini3939 2:a3e0f7f37ac9 332 byte = 0UL /*!< Width = 1 byte */
okini3939 2:a3e0f7f37ac9 333 , halfword = 1UL /*!< Width = 2 bytes */
okini3939 2:a3e0f7f37ac9 334 , word = 2UL /*!< Width = 4 bytes */
okini3939 2:a3e0f7f37ac9 335 };
okini3939 2:a3e0f7f37ac9 336
okini3939 2:a3e0f7f37ac9 337 //! DMA Request Select Mode definitions. */
okini3939 2:a3e0f7f37ac9 338 enum GPDMA_REQSEL {
okini3939 2:a3e0f7f37ac9 339 uart = 0UL /*!< UART TX/RX is selected */
okini3939 2:a3e0f7f37ac9 340 , timer = 1UL /*!< Timer match is selected */
okini3939 2:a3e0f7f37ac9 341 };
okini3939 2:a3e0f7f37ac9 342
okini3939 2:a3e0f7f37ac9 343 //! GPDMA Control register bits.
okini3939 2:a3e0f7f37ac9 344 enum Config {
okini3939 2:a3e0f7f37ac9 345 _E = 1 /*!< DMA Controller enable */
okini3939 2:a3e0f7f37ac9 346 , _M = 2 /*!< AHB Master endianness configuration */
okini3939 2:a3e0f7f37ac9 347 };
okini3939 2:a3e0f7f37ac9 348
okini3939 2:a3e0f7f37ac9 349 //! GPDMA Channel config register bits.
okini3939 2:a3e0f7f37ac9 350 enum CConfig {
okini3939 2:a3e0f7f37ac9 351 _CE = (1UL << 0) /*!< Channel enable */
okini3939 2:a3e0f7f37ac9 352 , _IE = (1UL << 14) /*!< Interrupt error mask */
okini3939 2:a3e0f7f37ac9 353 , _ITC = (1UL << 15) /*!< Terminal count interrupt mask */
okini3939 2:a3e0f7f37ac9 354 , _L = (1UL << 16) /*!< Lock */
okini3939 2:a3e0f7f37ac9 355 , _A = (1UL << 17) /*!< Active */
okini3939 2:a3e0f7f37ac9 356 , _H = (1UL << 18) /*!< Halt */
okini3939 2:a3e0f7f37ac9 357 };
okini3939 2:a3e0f7f37ac9 358
okini3939 2:a3e0f7f37ac9 359 /**
okini3939 2:a3e0f7f37ac9 360 * The MODDMA constructor is used to initialise the DMA controller object.
okini3939 2:a3e0f7f37ac9 361 */
okini3939 2:a3e0f7f37ac9 362 MODDMA() { init(true); }
okini3939 2:a3e0f7f37ac9 363
okini3939 2:a3e0f7f37ac9 364 /**
okini3939 2:a3e0f7f37ac9 365 * The MODDMA destructor.
okini3939 2:a3e0f7f37ac9 366 */
okini3939 2:a3e0f7f37ac9 367 ~MODDMA() {}
okini3939 2:a3e0f7f37ac9 368
okini3939 2:a3e0f7f37ac9 369 /**
okini3939 2:a3e0f7f37ac9 370 * Used to setup the DMA controller to prepare for a data transfer.
okini3939 2:a3e0f7f37ac9 371 *
okini3939 2:a3e0f7f37ac9 372 * @ingroup API
okini3939 2:a3e0f7f37ac9 373 * @param isConstructorCalling Set true when called from teh constructor
okini3939 2:a3e0f7f37ac9 374 * @param
okini3939 2:a3e0f7f37ac9 375 */
okini3939 2:a3e0f7f37ac9 376 void init(bool isConstructorCalling, int Channels = 0xFF, int Tc = 0xFF, int Err = 0xFF);
okini3939 2:a3e0f7f37ac9 377
okini3939 2:a3e0f7f37ac9 378 /**
okini3939 2:a3e0f7f37ac9 379 * Used to setup and enable the DMA controller.
okini3939 2:a3e0f7f37ac9 380 *
okini3939 2:a3e0f7f37ac9 381 * @see Setup
okini3939 2:a3e0f7f37ac9 382 * @see Enable
okini3939 2:a3e0f7f37ac9 383 * @ingroup API
okini3939 2:a3e0f7f37ac9 384 * @param c A pointer to an instance of MODDMA_Config to setup.
okini3939 2:a3e0f7f37ac9 385 */
okini3939 2:a3e0f7f37ac9 386 uint32_t Prepare(MODDMA_Config *c) {
okini3939 2:a3e0f7f37ac9 387 uint32_t u = Setup(c);
okini3939 2:a3e0f7f37ac9 388 if (u) Enable(c);
okini3939 2:a3e0f7f37ac9 389 return u;
okini3939 2:a3e0f7f37ac9 390 }
okini3939 2:a3e0f7f37ac9 391
okini3939 2:a3e0f7f37ac9 392 /**
okini3939 2:a3e0f7f37ac9 393 * Used to setup the DMA controller to prepare for a data transfer.
okini3939 2:a3e0f7f37ac9 394 *
okini3939 2:a3e0f7f37ac9 395 * @ingroup API
okini3939 2:a3e0f7f37ac9 396 * @param c A pointer to an instance of MODDMA_Config to setup.
okini3939 2:a3e0f7f37ac9 397 */
okini3939 2:a3e0f7f37ac9 398 uint32_t Setup(MODDMA_Config *c);
okini3939 2:a3e0f7f37ac9 399
okini3939 2:a3e0f7f37ac9 400 /**
okini3939 2:a3e0f7f37ac9 401 * Enable and begin data transfer.
okini3939 2:a3e0f7f37ac9 402 *
okini3939 2:a3e0f7f37ac9 403 * @ingroup API
okini3939 2:a3e0f7f37ac9 404 * @param ChannelNumber Type CHANNELS, the channel number to enable
okini3939 2:a3e0f7f37ac9 405 */
okini3939 2:a3e0f7f37ac9 406 void Enable(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 407
okini3939 2:a3e0f7f37ac9 408 /**
okini3939 2:a3e0f7f37ac9 409 * Enable and begin data transfer (overloaded function)
okini3939 2:a3e0f7f37ac9 410 *
okini3939 2:a3e0f7f37ac9 411 * @ingroup API
okini3939 2:a3e0f7f37ac9 412 * @param ChannelNumber Type uin32_t, the channel number to enable
okini3939 2:a3e0f7f37ac9 413 */
okini3939 2:a3e0f7f37ac9 414 void Enable(uint32_t ChannelNumber) { Enable((CHANNELS)(ChannelNumber & 0x7)); }
okini3939 2:a3e0f7f37ac9 415
okini3939 2:a3e0f7f37ac9 416 /**
okini3939 2:a3e0f7f37ac9 417 * Enable and begin data transfer (overloaded function)
okini3939 2:a3e0f7f37ac9 418 *
okini3939 2:a3e0f7f37ac9 419 * @ingroup API
okini3939 2:a3e0f7f37ac9 420 * @param config A pointer to teh configuration
okini3939 2:a3e0f7f37ac9 421 */
okini3939 2:a3e0f7f37ac9 422 void Enable(MODDMA_Config *config) { Enable( config->channelNum() ); }
okini3939 2:a3e0f7f37ac9 423
okini3939 2:a3e0f7f37ac9 424
okini3939 2:a3e0f7f37ac9 425 /**
okini3939 2:a3e0f7f37ac9 426 * Disable a channel and end data transfer.
okini3939 2:a3e0f7f37ac9 427 *
okini3939 2:a3e0f7f37ac9 428 * @ingroup API
okini3939 2:a3e0f7f37ac9 429 * @param ChannelNumber Type CHANNELS, the channel number to enable
okini3939 2:a3e0f7f37ac9 430 */
okini3939 2:a3e0f7f37ac9 431 void Disable(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 432
okini3939 2:a3e0f7f37ac9 433 /**
okini3939 2:a3e0f7f37ac9 434 * Disable a channel and end data transfer (overloaded function)
okini3939 2:a3e0f7f37ac9 435 *
okini3939 2:a3e0f7f37ac9 436 * @ingroup API
okini3939 2:a3e0f7f37ac9 437 * @param ChannelNumber Type uin32_t, the channel number to disable
okini3939 2:a3e0f7f37ac9 438 */
okini3939 2:a3e0f7f37ac9 439 void Disable(uint32_t ChannelNumber) { Disable((CHANNELS)(ChannelNumber & 0x7)); }
okini3939 2:a3e0f7f37ac9 440
okini3939 2:a3e0f7f37ac9 441 /**
okini3939 2:a3e0f7f37ac9 442 * Is the specified channel enabled?
okini3939 2:a3e0f7f37ac9 443 *
okini3939 2:a3e0f7f37ac9 444 * @ingroup API
okini3939 2:a3e0f7f37ac9 445 * @param ChannelNumber Type CHANNELS, the channel number to test
okini3939 2:a3e0f7f37ac9 446 * @return bool true if enabled, false otherwise.
okini3939 2:a3e0f7f37ac9 447 */
okini3939 2:a3e0f7f37ac9 448 bool Enabled(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 449
okini3939 2:a3e0f7f37ac9 450 /**
okini3939 2:a3e0f7f37ac9 451 * Is the specified channel enabled? (overloaded function)
okini3939 2:a3e0f7f37ac9 452 *
okini3939 2:a3e0f7f37ac9 453 * @ingroup API
okini3939 2:a3e0f7f37ac9 454 * @param ChannelNumber Type uin32_t, the channel number to test
okini3939 2:a3e0f7f37ac9 455 * @return bool true if enabled, false otherwise.
okini3939 2:a3e0f7f37ac9 456 */
okini3939 2:a3e0f7f37ac9 457 bool Enabled(uint32_t ChannelNumber) { return Enabled((CHANNELS)(ChannelNumber & 0x7)); }
okini3939 2:a3e0f7f37ac9 458
okini3939 2:a3e0f7f37ac9 459 __INLINE uint32_t IntStat(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 460 __INLINE uint32_t IntTCStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 461 __INLINE uint32_t IntTCClear_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 462 __INLINE uint32_t IntErrStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 463 __INLINE uint32_t IntErrClr_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 464 __INLINE uint32_t RawIntErrStat_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 465 __INLINE uint32_t EnbldChns_Ch(uint32_t n) { return (1UL << n) & 0xFF; }
okini3939 2:a3e0f7f37ac9 466 __INLINE uint32_t SoftBReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; }
okini3939 2:a3e0f7f37ac9 467 __INLINE uint32_t SoftSReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; }
okini3939 2:a3e0f7f37ac9 468 __INLINE uint32_t SoftLBReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; }
okini3939 2:a3e0f7f37ac9 469 __INLINE uint32_t SoftLSReq_Src(uint32_t n) { return (1UL << n) & 0xFFFF; }
okini3939 2:a3e0f7f37ac9 470 __INLINE uint32_t Sync_Src(uint32_t n) { return (1UL << n) & 0xFFFF; }
okini3939 2:a3e0f7f37ac9 471 __INLINE uint32_t ReqSel_Input(uint32_t n) { return (1UL << (n - 8)) & 0xFF; }
okini3939 2:a3e0f7f37ac9 472
okini3939 2:a3e0f7f37ac9 473
okini3939 2:a3e0f7f37ac9 474 __INLINE uint32_t CxControl_TransferSize(uint32_t n) { return (n & 0xFFF) << 0; }
okini3939 2:a3e0f7f37ac9 475 __INLINE uint32_t CxControl_SBSize(uint32_t n) { return (n & 0x7) << 12; }
okini3939 2:a3e0f7f37ac9 476 __INLINE uint32_t CxControl_DBSize(uint32_t n) { return (n & 0x7) << 15; }
okini3939 2:a3e0f7f37ac9 477 __INLINE uint32_t CxControl_SWidth(uint32_t n) { return (n & 0x7) << 18; }
okini3939 2:a3e0f7f37ac9 478 __INLINE uint32_t CxControl_DWidth(uint32_t n) { return (n & 0x7) << 21; }
okini3939 2:a3e0f7f37ac9 479 __INLINE uint32_t CxControl_SI() { return (1UL << 26); }
okini3939 2:a3e0f7f37ac9 480 __INLINE uint32_t CxControl_DI() { return (1UL << 27); }
okini3939 2:a3e0f7f37ac9 481 __INLINE uint32_t CxControl_Prot1() { return (1UL << 28); }
okini3939 2:a3e0f7f37ac9 482 __INLINE uint32_t CxControl_Prot2() { return (1UL << 29); }
okini3939 2:a3e0f7f37ac9 483 __INLINE uint32_t CxControl_Prot3() { return (1UL << 30); }
okini3939 2:a3e0f7f37ac9 484 __INLINE uint32_t CxControl_I() { return (1UL << 31); }
okini3939 2:a3e0f7f37ac9 485 __INLINE uint32_t CxControl_E() { return (1UL << 0); }
okini3939 2:a3e0f7f37ac9 486 __INLINE uint32_t CxConfig_SrcPeripheral(uint32_t n) { return (n & 0x1F) << 1; }
okini3939 2:a3e0f7f37ac9 487 __INLINE uint32_t CxConfig_DestPeripheral(uint32_t n) { return (n & 0x1F) << 6; }
okini3939 2:a3e0f7f37ac9 488 __INLINE uint32_t CxConfig_TransferType(uint32_t n) { return (n & 0x7) << 11; }
okini3939 2:a3e0f7f37ac9 489 __INLINE uint32_t CxConfig_IE() { return (1UL << 14); }
okini3939 2:a3e0f7f37ac9 490 __INLINE uint32_t CxConfig_ITC() { return (1UL << 15); }
okini3939 2:a3e0f7f37ac9 491 __INLINE uint32_t CxConfig_L() { return (1UL << 16); }
okini3939 2:a3e0f7f37ac9 492 __INLINE uint32_t CxConfig_A() { return (1UL << 17); }
okini3939 2:a3e0f7f37ac9 493 __INLINE uint32_t CxConfig_H() { return (1UL << 18); }
okini3939 2:a3e0f7f37ac9 494
okini3939 2:a3e0f7f37ac9 495 /**
okini3939 2:a3e0f7f37ac9 496 * A store for up to 8 (8 channels) of configurations.
okini3939 2:a3e0f7f37ac9 497 * @see MODDMA_Config
okini3939 2:a3e0f7f37ac9 498 */
okini3939 2:a3e0f7f37ac9 499 MODDMA_Config *setups[8];
okini3939 2:a3e0f7f37ac9 500
okini3939 2:a3e0f7f37ac9 501 /**
okini3939 2:a3e0f7f37ac9 502 * Get a pointer to the current configuration the ISR is servicing.
okini3939 2:a3e0f7f37ac9 503 *
okini3939 2:a3e0f7f37ac9 504 * @ingroup API
okini3939 2:a3e0f7f37ac9 505 * @return MODDMA_Config * A pointer to the setup the ISR is currently servicing.
okini3939 2:a3e0f7f37ac9 506 */
okini3939 2:a3e0f7f37ac9 507 MODDMA_Config *getConfig(void) { return setups[IrqProcessingChannel]; }
okini3939 2:a3e0f7f37ac9 508
okini3939 2:a3e0f7f37ac9 509 /**
okini3939 2:a3e0f7f37ac9 510 * Set which channel the ISR is currently servicing.
okini3939 2:a3e0f7f37ac9 511 *
okini3939 2:a3e0f7f37ac9 512 * *** USED INTERNALLY. DO NOT CALL FROM USER PROGRAMS ***
okini3939 2:a3e0f7f37ac9 513 *
okini3939 2:a3e0f7f37ac9 514 * Must be public so the extern "C" ISR can use it.
okini3939 2:a3e0f7f37ac9 515 */
okini3939 2:a3e0f7f37ac9 516 void setIrqProcessingChannel(CHANNELS n) { IrqProcessingChannel = n; }
okini3939 2:a3e0f7f37ac9 517
okini3939 2:a3e0f7f37ac9 518 /**
okini3939 2:a3e0f7f37ac9 519 * Gets which channel the ISR is currently servicing.
okini3939 2:a3e0f7f37ac9 520 *
okini3939 2:a3e0f7f37ac9 521 * @ingroup API
okini3939 2:a3e0f7f37ac9 522 * @return CHANNELS The current channel the ISR is servicing.
okini3939 2:a3e0f7f37ac9 523 */
okini3939 2:a3e0f7f37ac9 524 CHANNELS irqProcessingChannel(void) { return IrqProcessingChannel; }
okini3939 2:a3e0f7f37ac9 525
okini3939 2:a3e0f7f37ac9 526 /**
okini3939 2:a3e0f7f37ac9 527 * Sets which type of IRQ the ISR is making a callback for.
okini3939 2:a3e0f7f37ac9 528 *
okini3939 2:a3e0f7f37ac9 529 * *** USED INTERNALLY. DO NOT CALL FROM USER PROGRAMS ***
okini3939 2:a3e0f7f37ac9 530 *
okini3939 2:a3e0f7f37ac9 531 * Must be public so the extern "C" ISR can use it.
okini3939 2:a3e0f7f37ac9 532 */
okini3939 2:a3e0f7f37ac9 533 void setIrqType(IrqType_t n) { IrqType = n; }
okini3939 2:a3e0f7f37ac9 534
okini3939 2:a3e0f7f37ac9 535 /**
okini3939 2:a3e0f7f37ac9 536 * Get which type of IRQ the ISR is calling you about,
okini3939 2:a3e0f7f37ac9 537 * terminal count or error.
okini3939 2:a3e0f7f37ac9 538 */
okini3939 2:a3e0f7f37ac9 539 IrqType_t irqType(void) { return IrqType; }
okini3939 2:a3e0f7f37ac9 540
okini3939 2:a3e0f7f37ac9 541 /**
okini3939 2:a3e0f7f37ac9 542 * Clear the interrupt after handling.
okini3939 2:a3e0f7f37ac9 543 *
okini3939 2:a3e0f7f37ac9 544 * @param CHANNELS The channel the IQR occured on.
okini3939 2:a3e0f7f37ac9 545 */
okini3939 2:a3e0f7f37ac9 546 void clearTcIrq(CHANNELS n) { LPC_GPDMA->DMACIntTCClear = (uint32_t)(1UL << n); }
okini3939 2:a3e0f7f37ac9 547
okini3939 2:a3e0f7f37ac9 548 /**
okini3939 2:a3e0f7f37ac9 549 * Clear the interrupt the ISR is currently handing..
okini3939 2:a3e0f7f37ac9 550 */
okini3939 2:a3e0f7f37ac9 551 void clearTcIrq(void) { clearTcIrq( IrqProcessingChannel ); }
okini3939 2:a3e0f7f37ac9 552
okini3939 2:a3e0f7f37ac9 553 /**
okini3939 2:a3e0f7f37ac9 554 * Clear the error interrupt after handling.
okini3939 2:a3e0f7f37ac9 555 *
okini3939 2:a3e0f7f37ac9 556 * @ingroup API
okini3939 2:a3e0f7f37ac9 557 * @param CHANNELS The channel the IQR occured on.
okini3939 2:a3e0f7f37ac9 558 */
okini3939 2:a3e0f7f37ac9 559 void clearErrIrq(CHANNELS n) { LPC_GPDMA->DMACIntTCClear = (uint32_t)(1UL << n); }
okini3939 2:a3e0f7f37ac9 560
okini3939 2:a3e0f7f37ac9 561 /**
okini3939 2:a3e0f7f37ac9 562 * Clear the error interrupt the ISR is currently handing.
okini3939 2:a3e0f7f37ac9 563 * @ingroup API
okini3939 2:a3e0f7f37ac9 564 */
okini3939 2:a3e0f7f37ac9 565 void clearErrIrq(void) { clearErrIrq( IrqProcessingChannel ); }
okini3939 2:a3e0f7f37ac9 566
okini3939 2:a3e0f7f37ac9 567 /**
okini3939 2:a3e0f7f37ac9 568 * Is the supplied channel currently active?
okini3939 2:a3e0f7f37ac9 569 *
okini3939 2:a3e0f7f37ac9 570 * @ingroup API
okini3939 2:a3e0f7f37ac9 571 * @param CHANNELS The channel to inquire about.
okini3939 2:a3e0f7f37ac9 572 * @return bool true if active, false otherwise.
okini3939 2:a3e0f7f37ac9 573 */
okini3939 2:a3e0f7f37ac9 574 bool isActive(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 575
okini3939 2:a3e0f7f37ac9 576 /**
okini3939 2:a3e0f7f37ac9 577 * Halt the supplied channel.
okini3939 2:a3e0f7f37ac9 578 *
okini3939 2:a3e0f7f37ac9 579 * @ingroup API
okini3939 2:a3e0f7f37ac9 580 * @param CHANNELS The channel to halt.
okini3939 2:a3e0f7f37ac9 581 */
okini3939 2:a3e0f7f37ac9 582 void haltChannel(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 583
okini3939 2:a3e0f7f37ac9 584 /**
okini3939 2:a3e0f7f37ac9 585 * get a channels control register.
okini3939 2:a3e0f7f37ac9 586 *
okini3939 2:a3e0f7f37ac9 587 * @ingroup API
okini3939 2:a3e0f7f37ac9 588 * @param CHANNELS The channel to get the control register for.
okini3939 2:a3e0f7f37ac9 589 */
okini3939 2:a3e0f7f37ac9 590 uint32_t getControl(CHANNELS ChannelNumber);
okini3939 2:a3e0f7f37ac9 591
okini3939 2:a3e0f7f37ac9 592 /**
okini3939 2:a3e0f7f37ac9 593 * Wait for channel transfer to complete and then halt.
okini3939 2:a3e0f7f37ac9 594 *
okini3939 2:a3e0f7f37ac9 595 * @ingroup API
okini3939 2:a3e0f7f37ac9 596 * @param CHANNELS The channel to wait for then halt.
okini3939 2:a3e0f7f37ac9 597 */
okini3939 2:a3e0f7f37ac9 598 void haltAndWaitChannelComplete(CHANNELS n) { haltChannel(n); while (isActive(n)); }
okini3939 2:a3e0f7f37ac9 599
okini3939 2:a3e0f7f37ac9 600 /**
okini3939 2:a3e0f7f37ac9 601 * Attach a callback to the TC IRQ controller.
okini3939 2:a3e0f7f37ac9 602 *
okini3939 2:a3e0f7f37ac9 603 * @ingroup API
okini3939 2:a3e0f7f37ac9 604 * @param fptr A function pointer to call
okini3939 2:a3e0f7f37ac9 605 * @return this
okini3939 2:a3e0f7f37ac9 606 */
okini3939 2:a3e0f7f37ac9 607 void attach_tc(void (*fptr)(void)) {
okini3939 2:a3e0f7f37ac9 608 isrIntTCStat.attach(fptr);
okini3939 2:a3e0f7f37ac9 609 }
okini3939 2:a3e0f7f37ac9 610
okini3939 2:a3e0f7f37ac9 611 /**
okini3939 2:a3e0f7f37ac9 612 * Attach a callback to the TC IRQ controller.
okini3939 2:a3e0f7f37ac9 613 *
okini3939 2:a3e0f7f37ac9 614 * @ingroup API
okini3939 2:a3e0f7f37ac9 615 * @param tptr A template pointer to the calling object
okini3939 2:a3e0f7f37ac9 616 * @param mptr A method pointer within the object to call.
okini3939 2:a3e0f7f37ac9 617 * @return this
okini3939 2:a3e0f7f37ac9 618 */
okini3939 2:a3e0f7f37ac9 619 template<typename T>
okini3939 2:a3e0f7f37ac9 620 void attach_tc(T* tptr, void (T::*mptr)(void)) {
okini3939 2:a3e0f7f37ac9 621 if((mptr != NULL) && (tptr != NULL)) {
okini3939 2:a3e0f7f37ac9 622 isrIntTCStat.attach(tptr, mptr);
okini3939 2:a3e0f7f37ac9 623 }
okini3939 2:a3e0f7f37ac9 624 }
okini3939 2:a3e0f7f37ac9 625
okini3939 2:a3e0f7f37ac9 626 /**
okini3939 2:a3e0f7f37ac9 627 * The MODDMA controllers terminal count interrupt callback.
okini3939 2:a3e0f7f37ac9 628 */
okini3939 2:a3e0f7f37ac9 629 FunctionPointer isrIntTCStat;
okini3939 2:a3e0f7f37ac9 630
okini3939 2:a3e0f7f37ac9 631 /**
okini3939 2:a3e0f7f37ac9 632 * Attach a callback to the ERR IRQ controller.
okini3939 2:a3e0f7f37ac9 633 *
okini3939 2:a3e0f7f37ac9 634 * @ingroup API
okini3939 2:a3e0f7f37ac9 635 * @param fptr A function pointer to call
okini3939 2:a3e0f7f37ac9 636 * @return this
okini3939 2:a3e0f7f37ac9 637 */
okini3939 2:a3e0f7f37ac9 638 void attach_err(void (*fptr)(void)) {
okini3939 2:a3e0f7f37ac9 639 isrIntErrStat.attach(fptr);
okini3939 2:a3e0f7f37ac9 640 }
okini3939 2:a3e0f7f37ac9 641
okini3939 2:a3e0f7f37ac9 642 /**
okini3939 2:a3e0f7f37ac9 643 * Attach a callback to the ERR IRQ controller.
okini3939 2:a3e0f7f37ac9 644 *
okini3939 2:a3e0f7f37ac9 645 * @ingroup API
okini3939 2:a3e0f7f37ac9 646 * @param tptr A template pointer to the calling object
okini3939 2:a3e0f7f37ac9 647 * @param mptr A method pointer within the object to call.
okini3939 2:a3e0f7f37ac9 648 * @return this
okini3939 2:a3e0f7f37ac9 649 */
okini3939 2:a3e0f7f37ac9 650 template<typename T>
okini3939 2:a3e0f7f37ac9 651 void attach_err(T* tptr, void (T::*mptr)(void)) {
okini3939 2:a3e0f7f37ac9 652 if((mptr != NULL) && (tptr != NULL)) {
okini3939 2:a3e0f7f37ac9 653 isrIntErrStat.attach(tptr, mptr);
okini3939 2:a3e0f7f37ac9 654 }
okini3939 2:a3e0f7f37ac9 655 }
okini3939 2:a3e0f7f37ac9 656
okini3939 2:a3e0f7f37ac9 657 /**
okini3939 2:a3e0f7f37ac9 658 * Get the Linked List index regsiter for the requested channel.
okini3939 2:a3e0f7f37ac9 659 *
okini3939 2:a3e0f7f37ac9 660 * @param channelNum The channel number.
okini3939 2:a3e0f7f37ac9 661 * @return uint32_t The value of the DMACCLLI register
okini3939 2:a3e0f7f37ac9 662 */
okini3939 2:a3e0f7f37ac9 663 uint32_t lli(CHANNELS ChannelNumber, MODDMA_LLI *set = 0) {
okini3939 2:a3e0f7f37ac9 664 LPC_GPDMACH_TypeDef *pChannel = (LPC_GPDMACH_TypeDef *)Channel_p( ChannelNumber & 0x7 );
okini3939 2:a3e0f7f37ac9 665 if (set) pChannel->DMACCLLI = (uint32_t)set;
okini3939 2:a3e0f7f37ac9 666 return pChannel->DMACCLLI;
okini3939 2:a3e0f7f37ac9 667 }
okini3939 2:a3e0f7f37ac9 668
okini3939 2:a3e0f7f37ac9 669 /**
okini3939 2:a3e0f7f37ac9 670 * The MODDMA controllers error interrupt callback.
okini3939 2:a3e0f7f37ac9 671 */
okini3939 2:a3e0f7f37ac9 672 FunctionPointer isrIntErrStat;
okini3939 2:a3e0f7f37ac9 673
okini3939 2:a3e0f7f37ac9 674 uint32_t Channel_p(int channel);
okini3939 2:a3e0f7f37ac9 675
okini3939 2:a3e0f7f37ac9 676 protected:
okini3939 2:a3e0f7f37ac9 677
okini3939 2:a3e0f7f37ac9 678 // Data LUTs.
okini3939 2:a3e0f7f37ac9 679 uint32_t LUTPerAddr(int n);
okini3939 2:a3e0f7f37ac9 680 uint8_t LUTPerBurst(int n);
okini3939 2:a3e0f7f37ac9 681 uint8_t LUTPerWid(int n);
okini3939 2:a3e0f7f37ac9 682 //uint32_t Channel_p(int channel);
okini3939 2:a3e0f7f37ac9 683
okini3939 2:a3e0f7f37ac9 684 CHANNELS IrqProcessingChannel;
okini3939 2:a3e0f7f37ac9 685
okini3939 2:a3e0f7f37ac9 686 IrqType_t IrqType;
okini3939 2:a3e0f7f37ac9 687 };
okini3939 2:a3e0f7f37ac9 688
okini3939 2:a3e0f7f37ac9 689 }; // namespace AjK ends.
okini3939 2:a3e0f7f37ac9 690
okini3939 2:a3e0f7f37ac9 691 using namespace AjK;
okini3939 2:a3e0f7f37ac9 692
okini3939 2:a3e0f7f37ac9 693 #endif