Changeset 244 for trunk/softs
- Timestamp:
- Aug 3, 2012, 12:30:44 PM (12 years ago)
- Location:
- trunk/softs/soft_transpose_giet
- Files:
-
- 3 edited
Legend:
- Unmodified
- Added
- Removed
-
trunk/softs/soft_transpose_giet/Makefile
r163 r244 1 LD =mipsel-unknown-elf-ld2 CC =mipsel-unknown-elf-gcc3 AS =mipsel-unknown-elf-as4 DU =mipsel-unknown-elf-objdump1 LD = mipsel-unknown-elf-ld 2 CC = mipsel-unknown-elf-gcc 3 AS = mipsel-unknown-elf-as 4 DU = mipsel-unknown-elf-objdump 5 5 6 OBJS = reset.o \6 OBJS = reset.o \ 7 7 giet.o \ 8 8 isr.o \ … … 11 11 main.o 12 12 13 CFLAGS = -Wall -mno-gpopt -ffreestanding -fomit-frame-pointer -mips32 -ggdb13 CFLAGS = -Wall -mno-gpopt -ffreestanding -fomit-frame-pointer -mips32 -ggdb 14 14 15 GIET = ../giet_tsar15 GIET = ../giet_tsar 16 16 17 17 bin.soft: $(OBJS) ldscript -
trunk/softs/soft_transpose_giet/ldscript
r158 r244 32 32 33 33 seg_icu_base = 0x00F00000; /* controleur ICU */ 34 seg_tty_base = 0x 00F10000; /* controleur TTY */35 seg_dma_base = 0x00F 20000; /* controleur DMA */34 seg_tty_base = 0xBFF20000; /* controleur TTY */ 35 seg_dma_base = 0x00F30000; /* controleur DMA */ 36 36 37 37 seg_reset_base = 0xBFC00000; /* le code de boot */ 38 38 seg_fb_base = 0xBFD00000; /* controleur FRAME BUFFER */ 39 seg_ioc_base = 0xBFF 30000; /* controleur I/O */39 seg_ioc_base = 0xBFF10000; /* controleur I/O */ 40 40 41 seg_timer_base = 0x BFF40000; /* controleur TIMER */41 seg_timer_base = 0x00F00000; /* controleur TIMER */ 42 42 seg_gcd_base = 0xBFF50000; /* controleur GCD */ 43 43 -
trunk/softs/soft_transpose_giet/main.c
r171 r244 1 1 2 #include "stdio.h" 2 3 #define NL 512 4 #define NP 512 5 #define NB_IMAGES 1 6 #define BLOCK_SIZE 512 7 8 #define PRINTF if(local_id == 0) tty_printf 3 #include "limits.h" 4 #include "../giet_tsar/block_device.h" 5 6 #define NL 512 7 #define NP 512 8 #define NB_IMAGES 1 9 #define NB_CLUSTER_MAX 256 10 11 #define PRINTF(...) ({ if (local_id == 0) { tty_printf(__VA_ARGS__); } }) 9 12 10 13 /////////////////////////////////////////// … … 14 17 struct plaf; 15 18 19 extern struct plouf seg_ioc_base; 16 20 extern struct plaf seg_heap_base; 17 21 extern struct plaf NB_PROCS; … … 19 23 20 24 ///////////// 21 void main() 22 { 23 unsigned int image = 0; 24 unsigned int date = 0; 25 26 unsigned int c; // cluster index for loops 27 unsigned int l; // line index for loops 28 unsigned int p; // pixel index for loops 29 30 unsigned int proc_id = procid(); // processor id 31 unsigned int nprocs = (unsigned int)&NB_PROCS; // number of processors per cluster 32 unsigned int nclusters = (unsigned int)&NB_CLUSTERS; // number of clusters 33 unsigned int local_id = proc_id%nprocs; // local processor id 34 unsigned int cluster_id = proc_id/nprocs; // cluster id 35 unsigned int base = (unsigned int)&seg_heap_base; // base address for shared buffers 36 unsigned int increment = (0x80000000 / nclusters) * 2; // cluster increment 37 unsigned int ntasks = nclusters * nprocs; // number of tasks 38 unsigned int nblocks = (NP*NL) / BLOCK_SIZE; // number of blocks per image 39 40 PRINTF("\n *** Entering main at cycle %d ***\n\n", proctime()); 41 42 // parameters checking 43 if( (nprocs != 1) && (nprocs != 2) && (nprocs != 4) ) 44 { 45 PRINTF("NB_PROCS must be 1, 2 or 4\n"); 46 } 47 if( (nclusters != 1) && (nclusters != 2) && (nclusters != 4) && (nclusters != 8) && 48 (nclusters != 16) && (nclusters != 32) && (nclusters != 64) && (nclusters !=128) && 49 (nclusters != 256) ) 50 { 51 PRINTF("NB_CLUSTERS must be a power of 1 between 1 and 256\n"); 52 } 53 if( ntasks > 1024 ) 54 { 55 PRINTF("NB_PROCS * NB_CLUSTERS cannot be larger than 1024\n"); 56 } 57 if( proc_id >= ntasks ) 58 { 59 PRINTF("processor id %d larger than NB_CLUSTERS*NB_PROCS\n", proc_id); 60 } 61 62 // Arrays of pointers on the shared, distributed buffers containing the images 63 // These arrays are indexed by the cluster index (sized for the worst case : 256 clusters) 64 unsigned char* A[256]; 65 unsigned char* B[256]; 66 67 // Arrays of pointers on the instrumentation arrays 68 // These arrays are indexed by the cluster index (sized for the worst case : 256 clusters) 69 // each pointer points on the base adress of an array of NPROCS unsigned int 70 unsigned int* LOAD_START[256]; 71 unsigned int* LOAD_ENDED[256]; 72 unsigned int* TRSP_START[256]; 73 unsigned int* TRSP_ENDED[256]; 74 unsigned int* DISP_START[256]; 75 unsigned int* DISP_ENDED[256]; 76 77 // shared buffers address definition 78 // from the seg_heap_base and increment depending on the cluster index 79 // These arrays of pointers are identical and replicated in the stack of each task 80 for( c=0 ; c<nclusters ; c++) 81 { 82 A[c] = (unsigned char*)(base + increment*c); 83 B[c] = (unsigned char*)(base + NL*NP + increment*c); 84 LOAD_START[c] = (unsigned int*) (base + 2*NL*NP + increment*c); 85 LOAD_ENDED[c] = (unsigned int*) (base + 3*NL*NP + increment*c); 86 TRSP_START[c] = (unsigned int*) (base + 4*NL*NP + increment*c); 87 TRSP_ENDED[c] = (unsigned int*) (base + 5*NL*NP + increment*c); 88 DISP_START[c] = (unsigned int*) (base + 6*NL*NP + increment*c); 89 DISP_ENDED[c] = (unsigned int*) (base + 7*NL*NP + increment*c); 90 } 91 92 PRINTF("NB_CLUSTERS = %d\n", nclusters); 93 PRINTF("NB_PROCS = %d\n\n", nprocs); 94 95 PRINTF("*** starting barrier init at cycle %d ***\n", proctime()); 96 97 // barriers initialization 98 barrier_init(0, ntasks); 99 barrier_init(1, ntasks); 100 barrier_init(2, ntasks); 101 102 PRINTF("*** completing barrier init at cycle %d ***\n", proctime()); 103 104 // Main loop (on images) 105 while(image < NB_IMAGES) 106 { 107 // pseudo parallel load from disk to A[c] buffer : nblocks/nclusters blocks 108 // only task running on processor with (local_id == 0) does it 109 110 if ( local_id == 0 ) 111 { 112 int p; 113 114 date = proctime(); 115 PRINTF("\n*** Starting load for image %d at cycle %d\n", image, date); 116 for ( p=0 ; p<nprocs ; p++ ) LOAD_START[cluster_id][p] = date; 117 118 if( ioc_read(image*nblocks + nblocks*cluster_id/nclusters , A[cluster_id], nblocks/nclusters) ) 119 { 120 tty_printf("echec ioc_read\n"); 121 exit(); 25 void main(){ 26 unsigned int frame = 0; 27 unsigned int date = 0; 28 29 unsigned int c; // cluster index for loops 30 unsigned int l; // line index for loops 31 unsigned int p; // pixel index for loops 32 33 unsigned int proc_id = procid(); // processor id 34 unsigned int nlocal_procs = (unsigned int) &NB_PROCS; // number of processors per cluster 35 unsigned int nclusters = (unsigned int) &NB_CLUSTERS; // number of clusters 36 unsigned int local_id = proc_id % nlocal_procs; // local processor id 37 unsigned int cluster_id = proc_id / nlocal_procs; // cluster id 38 unsigned int base = (unsigned int) &seg_heap_base; // base address for shared buffers 39 unsigned int increment = 0x80000000 / nclusters * 2; // cluster increment 40 unsigned int nglobal_procs = nclusters * nlocal_procs; // number of tasks 41 unsigned int npixels = NP * NL; // number of pixel per frame 42 43 unsigned int * ioc_address = (unsigned int *) &seg_ioc_base; 44 unsigned int block_size = ioc_address[BLOCK_DEVICE_BLOCK_SIZE]; 45 unsigned int nblocks = npixels / block_size; // number of blocks per frame 46 47 PRINTF("\n *** Entering main at cycle %d ***\n\n", proctime()); 48 49 // parameters checking 50 if ((nlocal_procs != 1) && (nlocal_procs != 2) && (nlocal_procs != 4)){ 51 PRINTF("NB_PROCS must be 1, 2 or 4\n"); 52 exit(1); 53 } 54 if ((nclusters != 1) && (nclusters != 2) && (nclusters != 4) && (nclusters != 8) && 55 (nclusters != 16) && (nclusters != 32) && (nclusters != 64) && (nclusters != 128) && 56 (nclusters != 256)){ 57 PRINTF("NB_CLUSTERS must be a power of 1 between 1 and 256\n"); 58 exit(1); 59 } 60 if (nglobal_procs > 1024){ 61 PRINTF("NB_PROCS * NB_CLUSTERS cannot be larger than 1024\n"); 62 exit(1); 63 } 64 if (proc_id >= nglobal_procs){ 65 PRINTF("processor id %d larger than NB_CLUSTERS*NB_PROCS\n", proc_id); 66 exit(1); 67 } 68 69 // Arrays of pointers on the shared, distributed buffers containing the frames 70 // These arrays are indexed by the cluster index (sized for the worst case : 256 clusters) 71 unsigned char * A[NB_CLUSTER_MAX]; 72 unsigned char * B[NB_CLUSTER_MAX]; 73 74 // Arrays of pointers on the instrumentation arrays 75 // These arrays are indexed by the cluster index (sized for the worst case : 256 clusters) 76 // each pointer points on the base adress of an array of NPROCS unsigned int 77 unsigned int * LOAD_START[NB_CLUSTER_MAX]; 78 unsigned int * LOAD_END[NB_CLUSTER_MAX]; 79 unsigned int * TRSP_START[NB_CLUSTER_MAX]; 80 unsigned int * TRSP_END[NB_CLUSTER_MAX]; 81 unsigned int * DISP_START[NB_CLUSTER_MAX]; 82 unsigned int * DISP_END[NB_CLUSTER_MAX]; 83 84 // shared buffers address definition 85 // from the seg_heap_base and increment depending on the cluster index 86 // These arrays of pointers are identical and replicated in the stack of each task 87 for (c = 0; c < nclusters; c++){ 88 A[c] = (unsigned char *) (base + increment * c); 89 B[c] = (unsigned char *) (base + npixels + increment * c); 90 LOAD_START[c] = (unsigned int *) (base + 2 * npixels + increment * c); 91 LOAD_END[c] = (unsigned int *) (base + 2 * npixels + nlocal_procs + increment * c); 92 TRSP_START[c] = (unsigned int *) (base + 2 * npixels + 2 * nlocal_procs + increment * c); 93 TRSP_END[c] = (unsigned int *) (base + 2 * npixels + 3 * nlocal_procs + increment * c); 94 DISP_START[c] = (unsigned int *) (base + 2 * npixels + 4 * nlocal_procs + increment * c); 95 DISP_END[c] = (unsigned int *) (base + 2 * npixels + 5 * nlocal_procs + increment * c); 96 } 97 98 PRINTF("NB_CLUSTERS = %d\n", nclusters); 99 PRINTF("NB_LOCAL_PROCS = %d\n", nlocal_procs); 100 PRINTF("NB_GLOBAL_PROCS = %d\n", nglobal_procs); 101 PRINTF("NB_PIXELS = %d\n", npixels); 102 PRINTF("BLOCK_SIZE = %d\n", block_size); 103 PRINTF("NB_BLOCKS = %d\n\n", nblocks); 104 105 106 PRINTF("*** starting barrier init at cycle %d ***\n", proctime()); 107 108 // barriers initialization 109 barrier_init(0, nglobal_procs); 110 barrier_init(1, nglobal_procs); 111 barrier_init(2, nglobal_procs); 112 113 PRINTF("*** completing barrier init at cycle %d ***\n", proctime()); 114 115 // Main loop (on frames) 116 while (frame < NB_IMAGES){ 117 // pseudo parallel load from disk to A[c] buffer : nblocks/nclusters blocks 118 // only task running on processor with (local_id == 0) does it 119 120 if (local_id == 0){ 121 int p; 122 123 date = proctime(); 124 PRINTF("\n*** Starting load for frame %d at cycle %d\n", frame, date); 125 126 for (p = 0; p < nlocal_procs; p++){ 127 LOAD_START[cluster_id][p] = date; 128 } 129 tty_printf(" block_device offset : %d\n", nblocks * cluster_id / nclusters); 130 if (ioc_read(frame * nblocks + nblocks * cluster_id / nclusters, A[cluster_id], nblocks / nclusters)){ 131 tty_printf("echec ioc_read\n"); 132 exit(); 133 } 134 if (ioc_completed()){ 135 tty_printf("echec ioc_completed\n"); 136 exit(); 137 } 138 139 date = proctime(); 140 PRINTF("*** Completing load for frame %d at cycle %d\n", frame, date); 141 for (p = 0; p < nlocal_procs; p++){ 142 LOAD_END[cluster_id][p] = date; 143 } 144 } 145 146 barrier_wait(0); 147 148 // parallel transpose from A to B buffers 149 // each processor makes the transposition for (NL/nglobal_procs) lines 150 // (p,l) are the (x,y) pixel coordinates in the source frame 151 152 date = proctime(); 153 PRINTF("\n*** Starting transpose for frame %d at cycle %d\n", frame, date); 154 TRSP_START[cluster_id][local_id] = date; 155 156 unsigned int nlt = NL / nglobal_procs; // Nombre de ligne à traiter par processeur 157 unsigned int first = proc_id * nlt; // Index de la premiÚre ligne à traiter pour le proc courant (celui qui exécute le code) 158 unsigned int last = first + nlt; // Index de la derniÚre ligne 159 unsigned int nlines_clusters = NL / nclusters; // Nombre de lignes à traiter par cluster 160 unsigned int npix_clusters = NP / nclusters; // Nombre de pixels par ligne à traiter par cluster 161 162 for (l = first; l < last; l++){ 163 PRINTF(" - processing line %d\n", l); 164 for (p = 0; p < NP; p++){ 165 unsigned int source_index = (l % nlines_clusters) * NP + p; 166 unsigned int dest_cluster = p / npix_clusters; 167 unsigned int dest_index = (p % npix_clusters) * NL + l; 168 B[dest_cluster][dest_index] = A[cluster_id][source_index]; 169 } 170 } 171 172 date = proctime(); 173 PRINTF("*** Completing transpose for frame %d at cycle %d\n", frame, date); 174 TRSP_END[cluster_id][local_id] = date; 175 176 barrier_wait(1); 177 178 // parallel display from B[c] to frame buffer 179 // each processor uses its private dma to display NL*NP/nglobal_procs pixels 180 181 date = proctime(); 182 PRINTF("\n*** Starting display for frame %d at cycle %d\n", frame, date); 183 DISP_START[cluster_id][local_id] = date; 184 185 unsigned int npxt = npixels / nglobal_procs; // number of pixels per proc 186 if (npixels - npxt * nglobal_procs != 0){ 187 tty_printf("*** Error line %d\n", __LINE__); 188 exit(); 189 } 190 tty_printf(" npxt : %d\n", npxt); 191 192 if (fb_write(npxt * proc_id, B[cluster_id] + npxt * local_id, npxt)){ 193 tty_printf("[%d]: echec fb_sync_write\n", proc_id); 194 exit(); 195 } 196 197 PRINTF(" After fb_write and before fb_completed\n"); 198 199 if (fb_completed()){ 200 tty_printf("[%d]: echec fb_completed\n", proc_id); 201 exit(); 202 } 203 204 date = proctime(); 205 PRINTF("*** Completing display for frame %d at cycle %d\n", frame, date); 206 DISP_END[cluster_id][local_id] = date; 207 208 barrier_wait(2); 209 210 // Instrumentation (done by processor 0 in cluster 0) 211 if (local_id == 0){ 212 date = proctime(); 213 PRINTF("\n*** Starting Instrumentation for frame %d at cycle %d\n\n", frame, date); 214 215 int cc, pp; 216 unsigned int min_load_start = INT_MAX; 217 unsigned int max_load_start = 0; 218 unsigned int min_load_ended = INT_MAX; 219 unsigned int max_load_ended = 0; 220 unsigned int min_trsp_start = INT_MAX; 221 unsigned int max_trsp_start = 0; 222 unsigned int min_trsp_ended = INT_MAX; 223 unsigned int max_trsp_ended = 0; 224 unsigned int min_disp_start = INT_MAX; 225 unsigned int max_disp_start = 0; 226 unsigned int min_disp_ended = INT_MAX; 227 unsigned int max_disp_ended = 0; 228 229 for (cc = 0; cc < nclusters; cc++){ 230 for (pp = 0; pp < nlocal_procs; pp++){ 231 if (LOAD_START[cc][pp] < min_load_start){ 232 min_load_start = LOAD_START[cc][pp]; 233 } 234 if (LOAD_START[cc][pp] > max_load_start){ 235 max_load_start = LOAD_START[cc][pp]; 236 } 237 if (LOAD_END[cc][pp] < min_load_ended){ 238 min_load_ended = LOAD_END[cc][pp]; 239 } 240 if (LOAD_END[cc][pp] > max_load_ended){ 241 max_load_ended = LOAD_END[cc][pp]; 242 } 243 244 if (TRSP_START[cc][pp] < min_trsp_start){ 245 min_trsp_start = TRSP_START[cc][pp]; 246 } 247 if (TRSP_START[cc][pp] > max_trsp_start){ 248 max_trsp_start = TRSP_START[cc][pp]; 249 } 250 if (TRSP_END[cc][pp] < min_trsp_ended){ 251 min_trsp_ended = TRSP_END[cc][pp]; 252 } 253 if (TRSP_END[cc][pp] > max_trsp_ended){ 254 max_trsp_ended = TRSP_END[cc][pp]; 255 } 256 257 if (DISP_START[cc][pp] < min_disp_start){ 258 min_disp_start = DISP_START[cc][pp]; 259 } 260 if (DISP_START[cc][pp] > max_disp_start){ 261 max_disp_start = DISP_START[cc][pp]; 262 } 263 if (DISP_END[cc][pp] < min_disp_ended){ 264 min_disp_ended = DISP_END[cc][pp]; 265 } 266 if (DISP_END[cc][pp] > max_disp_ended){ 267 max_disp_ended = DISP_END[cc][pp]; 268 } 122 269 } 123 if ( ioc_completed() ) 124 { 125 tty_printf("echec ioc_completed\n"); 126 exit(); 127 } 128 129 date = proctime(); 130 PRINTF("*** Completing load for image %d at cycle %d\n", image, date); 131 for ( p=0 ; p<nprocs ; p++ ) LOAD_ENDED[cluster_id][p] = date; 132 } 133 134 barrier_wait(0); 135 136 // parallel transpose from A to B buffers 137 // each processor makes the transposition for (NL/ntasks) lines 138 // (p,l) are the (x,y) pixel coordinates in the source image 139 140 141 date = proctime(); 142 PRINTF("\n*** Starting transpose for image %d at cycle %d\n", image, date); 143 TRSP_START[cluster_id][local_id] = date; 144 145 unsigned int nlt = NL/ntasks; 146 unsigned int first = (cluster_id*nprocs + local_id)*nlt; 147 unsigned int last = first + nlt; 148 149 for ( l=first ; l<last ; l++) 150 { 151 PRINTF( " - processing line %d\n", l); 152 for ( p=0 ; p<NP ; p++) 153 { 154 unsigned int source_cluster = l/(NL/nclusters); 155 unsigned int source_index = (l%(NL/nclusters))*NP + p; 156 unsigned int dest_cluster = p / (NP/nclusters); 157 unsigned int dest_index = (p%(NP/nclusters))*NL + l; 158 B[dest_cluster][dest_index] = A[source_cluster][source_index]; 159 } 160 161 } 162 date = proctime(); 163 PRINTF("*** Completing transpose for image %d at cycle %d\n", image, date); 164 TRSP_ENDED[cluster_id][local_id] = date; 165 166 barrier_wait(1); 167 168 // parallel display from B[c] to frame buffer 169 // each processor uses its private dma to display NL*NP/ntasks pixels 170 171 date = proctime(); 172 PRINTF("\n*** Starting display for image %d at cycle %d\n", image, date); 173 DISP_START[cluster_id][local_id] = date; 174 175 unsigned int npxt = NL*NP/ntasks; // number of pixels per task 176 177 if ( fb_write(npxt*proc_id, B[cluster_id] + npxt*local_id, npxt) ) 178 { 179 PRINTF("echec fb_sync_write\n"); 180 exit(); 181 } 182 if ( fb_completed() ) 183 { 184 PRINTF("echec fb_completed\n"); 185 exit(); 186 } 187 188 date = proctime(); 189 PRINTF("*** Completing display for image %d at cycle %d\n", image, date); 190 DISP_ENDED[cluster_id][local_id] = date; 191 192 barrier_wait(2); 193 194 // Instrumentation (done by processor 0 in cluster 0) 195 if ( local_id == 0 ) 196 { 197 date = proctime(); 198 PRINTF("\n*** Starting Instrumentation for image %d at cycle %d\n\n", image, date); 199 200 int cc, pp; 201 unsigned int min_load_start = 1000000000; 202 unsigned int max_load_start = 0; 203 unsigned int min_load_ended = 1000000000; 204 unsigned int max_load_ended = 0; 205 unsigned int min_trsp_start = 1000000000; 206 unsigned int max_trsp_start = 0; 207 unsigned int min_trsp_ended = 1000000000; 208 unsigned int max_trsp_ended = 0; 209 unsigned int min_disp_start = 1000000000; 210 unsigned int max_disp_start = 0; 211 unsigned int min_disp_ended = 1000000000; 212 unsigned int max_disp_ended = 0; 213 214 for ( cc=0 ; cc<nclusters ; cc++ ) 215 { 216 for ( pp=0 ; pp<nprocs ; pp++ ) 217 { 218 if ( LOAD_START[cc][pp] < min_load_start ) min_load_start = LOAD_START[cc][pp]; 219 if ( LOAD_START[cc][pp] > max_load_start ) max_load_start = LOAD_START[cc][pp]; 220 if ( LOAD_ENDED[cc][pp] < min_load_ended ) min_load_ended = LOAD_ENDED[cc][pp]; 221 if ( LOAD_ENDED[cc][pp] > max_load_ended ) max_load_ended = LOAD_ENDED[cc][pp]; 222 223 if ( TRSP_START[cc][pp] < min_trsp_start ) min_trsp_start = TRSP_START[cc][pp]; 224 if ( TRSP_START[cc][pp] > max_trsp_start ) max_trsp_start = TRSP_START[cc][pp]; 225 if ( TRSP_ENDED[cc][pp] < min_trsp_ended ) min_trsp_ended = TRSP_ENDED[cc][pp]; 226 if ( TRSP_ENDED[cc][pp] > max_trsp_ended ) max_trsp_ended = TRSP_ENDED[cc][pp]; 227 228 if ( DISP_START[cc][pp] < min_disp_start ) min_disp_start = DISP_START[cc][pp]; 229 if ( DISP_START[cc][pp] > max_disp_start ) max_disp_start = DISP_START[cc][pp]; 230 if ( DISP_ENDED[cc][pp] < min_disp_ended ) min_disp_ended = DISP_ENDED[cc][pp]; 231 if ( DISP_ENDED[cc][pp] > max_disp_ended ) max_disp_ended = DISP_ENDED[cc][pp]; 232 233 } 234 } 235 PRINTF(" - LOAD_START : min = %d / max = %d / med = %d / delta = %d\n", 236 min_load_start, max_load_start, (min_load_start+max_load_start)/2, max_load_start-min_load_start); 237 PRINTF(" - LOAD_END : min = %d / max = %d / med = %d / delta = %d\n", 238 min_load_ended, max_load_ended, (min_load_ended+max_load_ended)/2, max_load_ended-min_load_ended); 239 240 PRINTF(" - TRSP_START : min = %d / max = %d / med = %d / delta = %d\n", 241 min_trsp_start, max_trsp_start, (min_trsp_start+max_trsp_start)/2, max_trsp_start-min_trsp_start); 242 PRINTF(" - TRSP_END : min = %d / max = %d / med = %d / delta = %d\n", 243 min_trsp_ended, max_trsp_ended, (min_trsp_ended+max_trsp_ended)/2, max_trsp_ended-min_trsp_ended); 244 245 PRINTF(" - DISP_START : min = %d / max = %d / med = %d / delta = %d\n", 246 min_disp_start, max_disp_start, (min_disp_start+max_disp_start)/2, max_disp_start-min_disp_start); 247 PRINTF(" - DISP_END : min = %d / max = %d / med = %d / delta = %d\n", 248 min_disp_ended, max_disp_ended, (min_disp_ended+max_disp_ended)/2, max_disp_ended-min_disp_ended); 249 250 PRINTF(" - BARRIER TRSP/DISP = %d\n", min_disp_start - max_trsp_ended); 251 } 252 // next image 253 image++; 254 255 } // end while image 256 257 while(1); 270 } 271 272 PRINTF(" - LOAD_START : min = %d / max = %d / med = %d / delta = %d\n", 273 min_load_start, max_load_start, (min_load_start+max_load_start)/2, max_load_start-min_load_start); 274 PRINTF(" - LOAD_END : min = %d / max = %d / med = %d / delta = %d\n", 275 min_load_ended, max_load_ended, (min_load_ended+max_load_ended)/2, max_load_ended-min_load_ended); 276 277 PRINTF(" - TRSP_START : min = %d / max = %d / med = %d / delta = %d\n", 278 min_trsp_start, max_trsp_start, (min_trsp_start+max_trsp_start)/2, max_trsp_start-min_trsp_start); 279 PRINTF(" - TRSP_END : min = %d / max = %d / med = %d / delta = %d\n", 280 min_trsp_ended, max_trsp_ended, (min_trsp_ended+max_trsp_ended)/2, max_trsp_ended-min_trsp_ended); 281 282 PRINTF(" - DISP_START : min = %d / max = %d / med = %d / delta = %d\n", 283 min_disp_start, max_disp_start, (min_disp_start+max_disp_start)/2, max_disp_start-min_disp_start); 284 PRINTF(" - DISP_END : min = %d / max = %d / med = %d / delta = %d\n", 285 min_disp_ended, max_disp_ended, (min_disp_ended+max_disp_ended)/2, max_disp_ended-min_disp_ended); 286 287 PRINTF(" - BARRIER TRSP/DISP = %d\n", min_disp_start - max_trsp_ended); 288 } 289 frame++; 290 291 } // end while frame 292 293 PRINTF("*** End of main ***\n"); 294 295 while(1); 258 296 } // end main() 259 297 298 // Local Variables: 299 // tab-width: 3 300 // c-basic-offset: 3 301 // c-file-offsets:((innamespace . 0)(inline-open . 0)) 302 // indent-tabs-mode: nil 303 // End: 304 305 // vim: filetype=cpp:expandtab:shiftwidth=3:tabstop=3:softtabstop=3 306 307 308
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