利用ZYNQ SOC快速打开算法验证通路(3)——PS端DMA缓存数据到PS端DDR
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2022-10-23 13:53:17
上篇该系列博文中讲述W5500接收到上位机传输的数据,此后需要将数据缓存起来。当数据量较大或者其他数据带宽较高的情况下,片上缓存(OCM)已无法满足需求,这时需要将大量数据保存在外挂的DDR SDRAM中。 最简单的方式是使用Xilinx的读写地址库函数Xil_In32()和Xil_Out32(), ......
上篇该系列博文中讲述W5500接收到上位机传输的数据,此后需要将数据缓存起来。当数据量较大或者其他数据带宽较高的情况下,片上缓存(OCM)已无法满足需求,这时需要将大量数据保存在外挂的DDR SDRAM中。
最简单的方式是使用Xilinx的读写地址库函数Xil_In32()和Xil_Out32(),当然不仅支持32bit位宽,还包括8 16和64bit。但这种方式每次读写都要占用CPU,无法在读写的同时接收后续数据或者对之前的数据进一步处理,也就无法形成类似FPGA逻辑设计中的“流水线结构”,此时前段数据缓存过程中,后段数据会被丢弃。所以,需要利用PS端CPU子系统内的专用硬件DMA完成高速的批量数据搬移工作。
在Xilinx SDK的system.mss页面下直接导入ps_dma示例工程。
1 #include <stdio.h>
2 #include <stdlib.h>
3 #include "sleep.h"
4 #include "xparameters.h"
5 #include "xil_types.h"
6 #include "xil_assert.h"
7 #include "xil_io.h"
8 #include "xil_exception.h"
9 #include "xil_cache.h"
10 #include "xil_printf.h"
11 #include "xscugic.h"
12 #include "xdmaps.h"
13
14 /************************** Constant Definitions *****************************/
15 /*
16 * The following constants map to the XPAR parameters created in the
17 * xparameters.h file. They are defined here such that a user can easily
18 * change all the needed parameters in one place.
19 */
20 #define DMA_DEVICE_ID XPAR_XDMAPS_1_DEVICE_ID
21 #define INTC_DEVICE_ID XPAR_SCUGIC_SINGLE_DEVICE_ID
22
23 #define DMA_DONE_INTR_0 XPAR_XDMAPS_0_DONE_INTR_0
24 #define DMA_DONE_INTR_1 XPAR_XDMAPS_0_DONE_INTR_1
25 #define DMA_DONE_INTR_2 XPAR_XDMAPS_0_DONE_INTR_2
26 #define DMA_DONE_INTR_3 XPAR_XDMAPS_0_DONE_INTR_3
27 #define DMA_DONE_INTR_4 XPAR_XDMAPS_0_DONE_INTR_4
28 #define DMA_DONE_INTR_5 XPAR_XDMAPS_0_DONE_INTR_5
29 #define DMA_DONE_INTR_6 XPAR_XDMAPS_0_DONE_INTR_6
30 #define DMA_DONE_INTR_7 XPAR_XDMAPS_0_DONE_INTR_7
31 #define DMA_FAULT_INTR XPAR_XDMAPS_0_FAULT_INTR
32
33
34
35 #define TEST_ROUNDS 1 /* Number of loops that the Dma transfers run.*/
36 #define DMA_LENGTH 1024 /* Length of the Dma Transfers */
37 #define TIMEOUT_LIMIT 0x2000 /* Loop count for timeout */
38
39 /**************************** Type Definitions *******************************/
40
41
42 /***************** Macros (Inline Functions) Definitions *********************/
43
44
45 /************************** Function Prototypes ******************************/
46
47 int XDmaPs_Example_W_Intr(XScuGic *GicPtr, u16 DeviceId);
48 int SetupInterruptSystem(XScuGic *GicPtr, XDmaPs *DmaPtr);
49 void DmaDoneHandler(unsigned int Channel, XDmaPs_Cmd *DmaCmd,
50 void *CallbackRef);
51
52 /************************** Macro Definitions *****************************/
53
54
55 /************************** Variable Definitions *****************************/
56 #ifdef __ICCARM__
57 #pragma data_alignment=32
58 static int Src[DMA_LENGTH];
59 static int Dst[DMA_LENGTH];
60 #pragma data_alignment=4
61 #else
62 static int Src[DMA_LENGTH] __attribute__ ((aligned (32)));
63 static int Dst[DMA_LENGTH] __attribute__ ((aligned (32)));
64 #endif
65
66 XDmaPs DmaInstance;
67 #ifndef TESTAPP_GEN
68 XScuGic GicInstance;
69 #endif
70
71 /****************************************************************************/
72 /**
73 *
74 * This is the main function for the DmaPs interrupt example.
75 *
76 * @param None.
77 *
78 * @return XST_SUCCESS to indicate success, otherwise XST_FAILURE.
79 *
80 * @note None.
81 *
82 ****************************************************************************/
83 #ifndef TESTAPP_GEN
84 int main(void)
85 {
86 int Status;
87
88 Status = XDmaPs_Example_W_Intr(&GicInstance,DMA_DEVICE_ID);
89 if (Status != XST_SUCCESS) {
90 xil_printf("Error: XDMaPs_Example_W_Intr failed\r\n");
91 return XST_FAILURE;
92 }
93
94 xil_printf("XDMaPs_Example_W_Intr passed\r\n");
95 return XST_SUCCESS;
96
97 }
98 #endif
99
100
101 /*****************************************************************************/
102 /**
103 *
104 * Interrupt Example to test the DMA.
105 *
106 * @param DeviceId is the Device ID of the DMA controller.
107 *
108 * @return XST_SUCCESS to indicate success, otherwise XST_FAILURE.
109 *
110 * @note None.
111 *
112 ****************************************************************************/
113 int XDmaPs_Example_W_Intr(XScuGic *GicPtr, u16 DeviceId)
114 {
115 int Index;
116 unsigned int Channel = 0;
117 int Status;
118 int TestStatus;
119 int TestRound;
120 int TimeOutCnt;
121 volatile int Checked[XDMAPS_CHANNELS_PER_DEV];
122 XDmaPs_Config *DmaCfg;
123 XDmaPs *DmaInst = &DmaInstance;
124 XDmaPs_Cmd DmaCmd;
125
126 memset(&DmaCmd, 0, sizeof(XDmaPs_Cmd));
127
128 DmaCmd.ChanCtrl.SrcBurstSize = 4;
129 DmaCmd.ChanCtrl.SrcBurstLen = 4;
130 DmaCmd.ChanCtrl.SrcInc = 1;
131 DmaCmd.ChanCtrl.DstBurstSize = 4;
132 DmaCmd.ChanCtrl.DstBurstLen = 4;
133 DmaCmd.ChanCtrl.DstInc = 1;
134 DmaCmd.BD.SrcAddr = (u32) Src;
135 DmaCmd.BD.DstAddr = (u32) Dst;
136 DmaCmd.BD.Length = DMA_LENGTH * sizeof(int);
137
138
139 /*
140 * Initialize the DMA Driver
141 */
142 DmaCfg = XDmaPs_LookupConfig(DeviceId);
143 if (DmaCfg == NULL) {
144 return XST_FAILURE;
145 }
146
147 Status = XDmaPs_CfgInitialize(DmaInst,
148 DmaCfg,
149 DmaCfg->BaseAddress);
150 if (Status != XST_SUCCESS) {
151 return XST_FAILURE;
152 }
153
154
155 /*
156 * Setup the interrupt system.
157 */
158 Status = SetupInterruptSystem(GicPtr, DmaInst);
159 if (Status != XST_SUCCESS) {
160 return XST_FAILURE;
161 }
162
163
164 TestStatus = XST_SUCCESS;
165
166 for (TestRound = 0; TestRound < TEST_ROUNDS; TestRound++) {
167 xil_printf("Test round %d\r\n", TestRound);
168 for (Channel = 0;
169 Channel < XDMAPS_CHANNELS_PER_DEV;
170 Channel++) {
171
172
173 /* Initialize source */
174 for (Index = 0; Index < DMA_LENGTH; Index++)
175 Src[Index] = DMA_LENGTH - Index;
176
177 /* Clear destination */
178 for (Index = 0; Index < DMA_LENGTH; Index++)
179 Dst[Index] = 0;
180
181 Checked[Channel] = 0;
182
183 /* Set the Done interrupt handler */
184 XDmaPs_SetDoneHandler(DmaInst,
185 Channel,
186 DmaDoneHandler,
187 (void *)Checked);
188
189
190 Status = XDmaPs_Start(DmaInst, Channel, &DmaCmd, 0);
191 if (Status != XST_SUCCESS) {
192 return XST_FAILURE;
193 }
194
195 TimeOutCnt = 0;
196
197 /* Now the DMA is done */
198 while (!Checked[Channel]
199 && TimeOutCnt < TIMEOUT_LIMIT) {
200 TimeOutCnt++;
201 }
202
203 if (TimeOutCnt >= TIMEOUT_LIMIT) {
204 TestStatus = XST_FAILURE;
205 }
206
207 if (Checked[Channel] < 0) {
208 /* DMA controller failed */
209 TestStatus = XST_FAILURE;
210 }
211 }
212 }
213
214 return TestStatus;
215
216 }
217
218
219 /******************************************************************************/
220 /**
221 *
222 * This function connects the interrupt handler of the interrupt controller to
223 * the processor. This function is seperate to allow it to be customized for
224 * each application. Each processor or RTOS may require unique processing to
225 * connect the interrupt handler.
226 *
227 * @param GicPtr is the GIC instance pointer.
228 * @param DmaPtr is the DMA instance pointer.
229 *
230 * @return None.
231 *
232 * @note None.
233 *
234 ****************************************************************************/
235 int SetupInterruptSystem(XScuGic *GicPtr, XDmaPs *DmaPtr)
236 {
237 int Status;
238 #ifndef TESTAPP_GEN
239 XScuGic_Config *GicConfig;
240
241
242 Xil_ExceptionInit();
243
244 /*
245 * Initialize the interrupt controller driver so that it is ready to
246 * use.
247 */
248 GicConfig = XScuGic_LookupConfig(INTC_DEVICE_ID);
249 if (NULL == GicConfig) {
250 return XST_FAILURE;
251 }
252
253 Status = XScuGic_CfgInitialize(GicPtr, GicConfig,
254 GicConfig->CpuBaseAddress);
255 if (Status != XST_SUCCESS) {
256 return XST_FAILURE;
257 }
258
259 /*
260 * Connect the interrupt controller interrupt handler to the hardware
261 * interrupt handling logic in the processor.
262 */
263 Xil_ExceptionRegisterHandler(XIL_EXCEPTION_ID_IRQ_INT,
264 (Xil_ExceptionHandler)XScuGic_InterruptHandler,
265 GicPtr);
266 #endif
267 /*
268 * Connect the device driver handlers that will be called when an interrupt
269 * for the device occurs, the device driver handler performs the specific
270 * interrupt processing for the device
271 */
272
273 /*
274 * Connect the Fault ISR
275 */
276 Status = XScuGic_Connect(GicPtr,
277 DMA_FAULT_INTR,
278 (Xil_InterruptHandler)XDmaPs_FaultISR,
279 (void *)DmaPtr);
280 if (Status != XST_SUCCESS) {
281 return XST_FAILURE;
282 }
283
284 /*
285 * Connect the Done ISR for all 8 channels of DMA 0
286 */
287 Status = XScuGic_Connect(GicPtr,
288 DMA_DONE_INTR_0,
289 (Xil_InterruptHandler)XDmaPs_DoneISR_0,
290 (void *)DmaPtr);
291 Status |= XScuGic_Connect(GicPtr,
292 DMA_DONE_INTR_1,
293 (Xil_InterruptHandler)XDmaPs_DoneISR_1,
294 (void *)DmaPtr);
295 Status |= XScuGic_Connect(GicPtr,
296 DMA_DONE_INTR_2,
297 (Xil_InterruptHandler)XDmaPs_DoneISR_2,
298 (void *)DmaPtr);
299 Status |= XScuGic_Connect(GicPtr,
300 DMA_DONE_INTR_3,
301 (Xil_InterruptHandler)XDmaPs_DoneISR_3,
302 (void *)DmaPtr);
303 Status |= XScuGic_Connect(GicPtr,
304 DMA_DONE_INTR_4,
305 (Xil_InterruptHandler)XDmaPs_DoneISR_4,
306 (void *)DmaPtr);
307 Status |= XScuGic_Connect(GicPtr,
308 DMA_DONE_INTR_5,
309 (Xil_InterruptHandler)XDmaPs_DoneISR_5,
310 (void *)DmaPtr);
311 Status |= XScuGic_Connect(GicPtr,
312 DMA_DONE_INTR_6,
313 (Xil_InterruptHandler)XDmaPs_DoneISR_6,
314 (void *)DmaPtr);
315 Status |= XScuGic_Connect(GicPtr,
316 DMA_DONE_INTR_7,
317 (Xil_InterruptHandler)XDmaPs_DoneISR_7,
318 (void *)DmaPtr);
319
320 if (Status != XST_SUCCESS)
321 return XST_FAILURE;
322
323 /*
324 * Enable the interrupts for the device
325 */
326 XScuGic_Enable(GicPtr, DMA_DONE_INTR_0);
327 XScuGic_Enable(GicPtr, DMA_DONE_INTR_1);
328 XScuGic_Enable(GicPtr, DMA_DONE_INTR_2);
329 XScuGic_Enable(GicPtr, DMA_DONE_INTR_3);
330 XScuGic_Enable(GicPtr, DMA_DONE_INTR_4);
331 XScuGic_Enable(GicPtr, DMA_DONE_INTR_5);
332 XScuGic_Enable(GicPtr, DMA_DONE_INTR_6);
333 XScuGic_Enable(GicPtr, DMA_DONE_INTR_7);
334 XScuGic_Enable(GicPtr, DMA_FAULT_INTR);
335
336 Xil_ExceptionEnable();
337
338 return XST_SUCCESS;
339
340 }
341
342
343 /*****************************************************************************/
344 /**
345 *
346 * DmaDoneHandler.
347 *
348 * @param Channel is the Channel number.
349 * @param DmaCmd is the Dma Command.
350 * @param CallbackRef is the callback reference data.
351 *
352 * @return None.
353 *
354 * @note None.
355 *
356 ******************************************************************************/
357 void DmaDoneHandler(unsigned int Channel, XDmaPs_Cmd *DmaCmd, void *CallbackRef)
358 {
359
360 /* done handler */
361 volatile int *Checked = (volatile int *)CallbackRef;
362 int Index;
363 int Status = 1;
364 int *Src;
365 int *Dst;
366
367 Src = (int *)DmaCmd->BD.SrcAddr;
368 Dst = (int *)DmaCmd->BD.DstAddr;
369
370 /* DMA successful */
371 /* compare the src and dst buffer */
372 for (Index = 0; Index < DMA_LENGTH; Index++) {
373 if ((Src[Index] != Dst[Index]) ||
374 (Dst[Index] != DMA_LENGTH - Index)) {
375 Status = -XST_FAILURE;
376 }
377 }
378
379
380 Checked[Channel] = Status;
381 }
其实demo中做的操作非常简单,仅仅是定义了两个数组Src和Dst,之后利用PS_DMA将Src中数据搬移到Dst中,搬移完成后进入中断函数比较两部分地址数据是否一致。Xilinx的SDK软件代码有固定的套路,“上有政策,下有对策”,我们可以将其封装成固定格式的一个个子函数,方便今后调用。这里把整个工程分为:系统中断,PS_DMA专有中断以及主函数三个部分。
1 #include "xscugic.h"
2 #include "sys_intr.h"
3
4 int sys_IntrInit(XScuGic *GicPtr)
5 {
6 XScuGic_Config *GicConfig;
7 /*
8 * Initialize the interrupt controller driver so that it is ready to
9 * use.
10 */
11 int Status;
12 GicConfig = XScuGic_LookupConfig(INTC_DEVICE_ID);
13 if (NULL == GicConfig) {
14 return XST_FAILURE;
15 }
16
17 Status = XScuGic_CfgInitialize(GicPtr, GicConfig,
18 GicConfig->CpuBaseAddress);
19 if (Status != XST_SUCCESS) {
20 return XST_FAILURE;
21 }
22 return XST_SUCCESS;
23 }
24
25 void setupIntrException(XScuGic *GicPtr)
26 {
27 Xil_ExceptionInit();
28 /*
29 * Connect the interrupt controller interrupt handler to the hardware
30 * interrupt handling logic in the processor.
31 */
32 Xil_ExceptionRegisterHandler(XIL_EXCEPTION_ID_IRQ_INT,
33 (Xil_ExceptionHandler)XScuGic_InterruptHandler,
34 GicPtr);
35 Xil_ExceptionEnable();
36 }
1 #ifndef SRC_SYS_INTR_H_ 2 #define SRC_SYS_INTR_H_ 3 4 #define INTC_DEVICE_ID XPAR_SCUGIC_SINGLE_DEVICE_ID 5 6 int sys_IntrInit(XScuGic *GicPtr); 7 void setupIntrException(XScuGic *GicPtr); 8 9 #endif /* SRC_SYS_INTR_H_ */
1 #include "xil_types.h"
2 #include "xdmaps.h"
3 #include "xscugic.h"
4 #include "psdma_intr.h"
5
6 int PS_DMA_IntrInit(XDmaPs *DmaInst,u16 DeviceId)
7 {
8 /*
9 * Initialize the DMA Driver
10 */
11 int Status;
12 XDmaPs_Config *DmaCfg = NULL;
13 DmaCfg = XDmaPs_LookupConfig(DeviceId);
14 if (DmaCfg == NULL) {
15 return XST_FAILURE;
16 }
17
18 Status = XDmaPs_CfgInitialize(DmaInst,
19 DmaCfg,
20 DmaCfg->BaseAddress);
21 if (Status != XST_SUCCESS) {
22 return XST_FAILURE;
23 }
24 return XST_SUCCESS;
25 }
26
27 int PS_DMA_SetupIntr(XScuGic *GicPtr,XDmaPs *DmaPtr,unsigned Channel)
28 {
29 int Status;
30 /*
31 * Connect the device driver handlers that will be called when an interrupt
32 * for the device occurs, the device driver handler performs the specific
33 * interrupt processing for the device
34 */
35
36 /*
37 * Connect the Fault ISR
38 */
39 Status = XScuGic_Connect(GicPtr,
40 DMA_FAULT_INTR,
41 (Xil_InterruptHandler)XDmaPs_FaultISR,
42 (void *)DmaPtr);
43 if (Status != XST_SUCCESS) {
44 return XST_FAILURE;
45 }
46
47 /*
48 * Connect the Done ISR for all 8 channels of DMA 0
49 */
50 Status = XScuGic_Connect(GicPtr,
51 DMA_DONE_INTR_0,
52 (Xil_InterruptHandler)XDmaPs_DoneISR_0,
53 (void *)DmaPtr);
54 /*Status |= XScuGic_Connect(GicPtr,
55 DMA_DONE_INTR_1,
56 (Xil_InterruptHandler)XDmaPs_DoneISR_1,
57 (void *)DmaPtr);
58 Status |= XScuGic_Connect(GicPtr,
59 DMA_DONE_INTR_2,
60 (Xil_InterruptHandler)XDmaPs_DoneISR_2,
61 (void *)DmaPtr);
62 Status |= XScuGic_Connect(GicPtr,
63 DMA_DONE_INTR_3,
64 (Xil_InterruptHandler)XDmaPs_DoneISR_3,
65 (void *)DmaPtr);
66 Status |= XScuGic_Connect(GicPtr,
67 DMA_DONE_INTR_4,
68 (Xil_InterruptHandler)XDmaPs_DoneISR_4,
69 (void *)DmaPtr);
70 Status |= XScuGic_Connect(GicPtr,
71 DMA_DONE_INTR_5,
72 (Xil_InterruptHandler)XDmaPs_DoneISR_5,
73 (void *)DmaPtr);
74 Status |= XScuGic_Connect(GicPtr,
75 DMA_DONE_INTR_6,
76 (Xil_InterruptHandler)XDmaPs_DoneISR_6,
77 (void *)DmaPtr);
78 Status |= XScuGic_Connect(GicPtr,
79 DMA_DONE_INTR_7,
80 (Xil_InterruptHandler)XDmaPs_DoneISR_7,
81 (void *)DmaPtr);*/
82
83 if (Status != XST_SUCCESS)
84 return XST_FAILURE;
85
86 /* Set the Done interrupt handler */
87 XDmaPs_SetDoneHandler(DmaPtr,
88 Channel,//Channel
89 DmaDoneHandler,//真正的中断函数
90 (void *)Checked);
91
92 /*
93 * Enable the interrupts for the device
94 */
95 XScuGic_Enable(GicPtr, DMA_DONE_INTR_0);
96 /*
97 XScuGic_Enable(GicPtr, DMA_DONE_INTR_1);
98 XScuGic_Enable(GicPtr, DMA_DONE_INTR_2);
99 XScuGic_Enable(GicPtr, DMA_DONE_INTR_3);
100 XScuGic_Enable(GicPtr, DMA_DONE_INTR_4);
101 XScuGic_Enable(GicPtr, DMA_DONE_INTR_5);
102 XScuGic_Enable(GicPtr, DMA_DONE_INTR_6);
103 XScuGic_Enable(GicPtr, DMA_DONE_INTR_7);*/
104 XScuGic_Enable(GicPtr, DMA_FAULT_INTR);
105
106 return XST_SUCCESS;
107 }
108
109 void DmaDoneHandler(unsigned int Channel, XDmaPs_Cmd *DmaCmd, void *CallbackRef)
110 {
111
112 /* done handler */
113 volatile int *Checked = (volatile int *)CallbackRef;
114 //int Index;
115 int Status = 1;
116
117 xil_printf("Enter into the interrupt\n");
118 Checked[Channel] = Status;
119 }
120
121 void PS_DMA_InitPara(XDmaPs_Cmd* DmaCmd)
122 {
123
124 memset(DmaCmd, 0, sizeof(XDmaPs_Cmd));
125
126 DmaCmd->ChanCtrl.SrcBurstSize = 4;
127 DmaCmd->ChanCtrl.SrcBurstLen = 4;
128 DmaCmd->ChanCtrl.SrcInc = 1;
129 DmaCmd->ChanCtrl.DstBurstSize = 4;
130 DmaCmd->ChanCtrl.DstBurstLen = 4;
131 DmaCmd->ChanCtrl.DstInc = 1;
132 DmaCmd->BD.SrcAddr = (u32) Src;
133 DmaCmd->BD.DstAddr = (u32) DDR_BASEADDR;//Dst
134 DmaCmd->BD.Length = DMA_LENGTH * sizeof(int);
135 }
1 #ifndef SRC_PSDMA_INTR_H_ 2 #define SRC_PSDMA_INTR_H_ 3 4 #define DMA_DONE_INTR_0 XPAR_XDMAPS_0_DONE_INTR_0 5 #define DMA_DONE_INTR_1 XPAR_XDMAPS_0_DONE_INTR_1 6 #define DMA_DONE_INTR_2 XPAR_XDMAPS_0_DONE_INTR_2 7 #define DMA_DONE_INTR_3 XPAR_XDMAPS_0_DONE_INTR_3 8 #define DMA_DONE_INTR_4 XPAR_XDMAPS_0_DONE_INTR_4 9 #define DMA_DONE_INTR_5 XPAR_XDMAPS_0_DONE_INTR_5 10 #define DMA_DONE_INTR_6 XPAR_XDMAPS_0_DONE_INTR_6 11 #define DMA_DONE_INTR_7 XPAR_XDMAPS_0_DONE_INTR_7 12 #define DMA_FAULT_INTR XPAR_XDMAPS_0_FAULT_INTR 13 14 #define DDR_BASEADDR 0x00600000//XPAR_PS7_DDR_0_S_AXI_BASEADDR 0x00100000 15 #define DMA_LENGTH 1024 /* Length of the Dma Transfers */ 16 17 int Src[DMA_LENGTH] __attribute__ ((aligned (32))); 18 volatile int Checked[XDMAPS_CHANNELS_PER_DEV]; 19 20 int PS_DMA_IntrInit(XDmaPs *DmaInst,u16 DeviceId); 21 int PS_DMA_SetupIntr(XScuGic *GicPtr,XDmaPs *DmaPtr,unsigned Channel); 22 void DmaDoneHandler(unsigned int Channel, XDmaPs_Cmd *DmaCmd, void *CallbackRef); 23 void PS_DMA_InitPara(XDmaPs_Cmd* DmaCmd); 24 25 #endif /* SRC_PSDMA_INTR_H_ */
1 #include <stdio.h>
2 #include <stdlib.h>
3 #include "sleep.h"
4 #include "xparameters.h"
5 #include "xil_types.h"
6 #include "xil_assert.h"
7 #include "xil_io.h"
8 #include "xil_exception.h"
9 #include "xil_cache.h"
10 #include "xil_printf.h"
11 #include "xscugic.h"
12 #include "xdmaps.h"
13
14 #include "sys_intr.h"
15 #include "psdma_intr.h"
16
17
18 #define DMA_DEVICE_ID XPAR_XDMAPS_1_DEVICE_ID
19 #define INTC_DEVICE_ID XPAR_SCUGIC_SINGLE_DEVICE_ID
20
21
22 #define TEST_ROUNDS 1 /* Number of loops that the Dma transfers run.*/
23 #define TIMEOUT_LIMIT 0x2000 /* Loop count for timeout */
24
25
26 static XScuGic GicInstance;
27 static XDmaPs DmaInstance;
28 static XDmaPs_Cmd DmaCmd;
29 unsigned int Channel = 0;
30
31 /************************** Function Prototypes ******************************/
32
33 int PS_DMA_WriteTest();
34 int SetupInterruptSystem(XScuGic *GicPtr, XDmaPs *DmaPtr);
35 void DmaDoneHandler(unsigned int Channel, XDmaPs_Cmd *DmaCmd,
36 void *CallbackRef);
37 int dataCheck(u32 baseAddr,u32 len);
38 int systemInit(XScuGic *GicPtr,u16 DeviceId);
39
40
41 int main(void)
42 {
43 int Status;
44 Status = systemInit(&GicInstance,DMA_DEVICE_ID);
45 if (Status != XST_SUCCESS) {
46 xil_printf("System initialization is failed\r\n");
47 return XST_FAILURE;
48 }
49
50 Status = PS_DMA_WriteTest();
51 if (Status != XST_SUCCESS) {
52 xil_printf("Error: XDMaPs_Example_W_Intr failed\r\n");
53 return XST_FAILURE;
54 }
55 xil_printf("Checking data...\n");
56 Status = dataCheck(DDR_BASEADDR,DMA_LENGTH);
57 if(Status != XST_SUCCESS)
58 {
59 xil_printf("Error:check failed\n");
60 return XST_FAILURE;
61 }
62
63 xil_printf("Writing data to DDR using DMA test passed!\r\n");
64 return XST_SUCCESS;
65
66 }
67
68 int dataCheck(u32 baseAddr,u32 len)
69 {
70 u32 DDR_ReadData[1024];
71 int i;
72 for(i=0;i<len;i++)
73 {
74 DDR_ReadData[i] = Xil_In32(baseAddr+i*4);
75 if(DDR_ReadData[i]!=Src[i])
76 return XST_FAILURE;
77 //else //将写入DDR数据读回 并打印
78 // xil_printf("data at %x is %d\n",baseAddr+i*4,DDR_ReadData[i]);
79 }
80 return XST_SUCCESS;
81 }
82
83
84 /*****************************************************************************/
85 /**
86 *
87 * Interrupt Example to test the DMA.
88 *
89 * @param DeviceId is the Device ID of the DMA controller.
90 *
91 * @return XST_SUCCESS to indicate success, otherwise XST_FAILURE.
92 *
93 * @note None.
94 *
95 ****************************************************************************/
96 int PS_DMA_WriteTest()
97 {
98 int Index;
99 int Status;
100 int TestStatus;
101 int TestRound;
102 int TimeOutCnt;
103
104 TestStatus = XST_SUCCESS;
105
106 for (TestRound = 0; TestRound < TEST_ROUNDS; TestRound++) {
107 xil_printf("Test round %d\r\n", TestRound);
108 for (Channel = 0;Channel < 1;Channel++)
109 {
110 /* Initialize source */
111 for (Index = 0; Index < DMA_LENGTH; Index++)
112 Src[Index] = DMA_LENGTH - Index;
113
114 Checked[Channel] = 0;
115
116 Status = XDmaPs_Start(&DmaInstance, Channel, &DmaCmd, 0);
117 if (Status != XST_SUCCESS) {
118 xil_printf("Starting the DMA is failed.\n");
119 return XST_FAILURE;
120 }
121 xil_printf("Starting the DMA is successful.\n");
122 TimeOutCnt = 0;
123
124 while (!Checked[Channel]
125 && TimeOutCnt < TIMEOUT_LIMIT) {
126 TimeOutCnt++;
127 }
128 /* Now the DMA is done */
129 xil_printf("Jump out of the interrupt\n");
130 if (TimeOutCnt >= TIMEOUT_LIMIT) {
131 xil_printf("Overtime!\n");
132 TestStatus = XST_FAILURE;
133 }
134
135 if (Checked[Channel] < 0) {
136 /* DMA controller failed */
137 xil_printf("Checking failure!\n");
138 TestStatus = XST_FAILURE;
139 }
140 }
141 }
142
143 return TestStatus;
144
145 }
146
147 int systemInit(XScuGic *GicPtr,u16 DeviceId)
148 {
149 xil_printf("Start to initialize interrupt system.\n");
150
151 PS_DMA_InitPara(&DmaCmd);//主要设置DMA的源目的地址
152 //xil_printf("Configuring DMA parameters is successful.\n");
153
154 int Status;
155
156 Status = PS_DMA_IntrInit(&DmaInstance,DeviceId);
157 if (Status != XST_SUCCESS) {
158 xil_printf("DMA initialization is failed.\n");
159 return XST_FAILURE;
160 }
161 //xil_printf("DMA initialization is successful.\n");
162
163 Status = sys_IntrInit(GicPtr);
164 if (Status != XST_SUCCESS) {
165 xil_printf("Initialization of the interrupt system is failed.\n");
166 return XST_FAILURE;
167 }
168 //xil_printf("Initialization of the interrupt system is successful.\n");
169
170 setupIntrException(GicPtr);
171
172 Status = PS_DMA_SetupIntr(GicPtr,&DmaInstance,Channel);//////////////////////////DMA中断入口///////////////////////
173 if (Status != XST_SUCCESS) {
174 xil_printf("Setting up DMA interrupt is failed.\n");
175 return XST_FAILURE;
176 }
177 //xil_printf("Setting up DMA interrupt is successful.\n");
178
179 xil_printf("System initialization is finished.\n");
180 xil_printf("------------------------------------------\n");
181 return XST_SUCCESS;
182 }
上述代码的封装方式参考了米联客教程中的思想。先说明系统中断部分:sys_IntrInit()函数中进行查找表配置和中断控制器初始化操作,setupIntrException()函数负责使能中断异常处理。再来说说PS_DMA中断部分:PS_DMA_IntrInit()函数与系统中断中sys_IntrInit()从操作到格式几乎完成相同,亦是查找表配置和DMA的初始化。PS_DMA_SetupIntr()函数完成了中断源和中断控制器的连接和设置中断处理器,以及中断使能,也就是所有PS_DMA的专用中断操作。
PS_DMA_SetupIntr()内最重要的部分是XDmaPs_SetDoneHandler(),其相当于一个调用中断函数的通用处理框架,它的第三个参数DoneHandler才是真正的中断处理函数。这里涉及到C语言的高级话题:函数通过函数指针调用另一个函数,被函数指针调用的函数就是通常讲的“回调函数”了。指针调用函数的方式兼顾了程序的通用架构和灵活性,具体参考文章:不懂C语言回调函数,那就看这篇文章吧! - 简书 在该程序中,中断回调函数为DmaDoneHandler()。
PS_DMA_InitPara()是自行添加的PS_DMA参数初始化函数,内部的参数更是重中之重了,我们来查看Xilinx官方文档ug585的DMA Controller章节。
简要来说,DMA以burst形式传输数据,意思是分批次搬移。手册说明原或目的burst_size位宽不能超过64bit,这也是其挂载AXI总线的数据位宽。PS_DMA_InitPara()里的SrcBurstSize为源突发传输位宽字节数,最大为8.SrcBurstLen是手册中所说的“burst length”,即突发传输数据个数。SrcInc表示burst types为地址自增(1)还是地址固定(0)模式。目的控制字同理。剩下的三个参数最重要:SrcAddr DstAddr Length分别代表源首地址 目的首地址和一共需要搬移的数据字节数。需要注意的是,一定要满足srcburstsize*srcburstlen == dstburstsize*dstburstlen,否则发生错误。这一点也比较好理解,相当于FPGA逻辑设计中的异步FIFO两侧数据带宽要匹配。
那么要想完成OCM到DDR的数据搬移,改动下地址就可以嘛。由于读写DDR要访问绝对地址,所以要格外注意读写操作的地址不能和DDR内存储程序代码和中间数据的地址段重叠。避免程序崩溃很简单的做法就是在XPAR_PS7_DDR_0_S_AXI_BASEADDR 的基础上加一段偏移量,具体加多少的问题本人也不是很明确,希望看到的朋友能在评论中指点一二。
对于ZYNQ这一SOC架构来说,PS端连接如以太网,USB等高带宽外设计接口更加方便,所以PS_DMA的灵活运用还好是十分必要的,更灵活高效的利用这一硬件资源还要后期继续探索。PS端和PL端高速数据交互就需要用到另一个DMA成员AXI_DMA,可以说它利用片内总线打破了CPU+FPGA架构的性能瓶颈,该部分内容将在后续说明。
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