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author | Andrew Mahone <andrew.mahone@gmail.com> | 2009-02-07 22:18:26 +0000 |
---|---|---|
committer | Andrew Mahone <andrew.mahone@gmail.com> | 2009-02-07 22:18:26 +0000 |
commit | eda5ed06244abba643e09a775d71542d91691d4d (patch) | |
tree | 597889da517d450c8b4aa20981edab9bcfd27c41 /apps/plugins/pictureflow.c | |
parent | ef726cee6721f4a81951161c3d93347d4362d3d2 (diff) | |
download | rockbox-eda5ed06244abba643e09a775d71542d91691d4d.tar.gz rockbox-eda5ed06244abba643e09a775d71542d91691d4d.zip |
rewrite of pictureflow renderer with 3D projection, this will allow many possible tweaks in the future, such as moving only the center slide "closer", changing the angle of side slides, etc, while
keeping the same meaning for the center margin and spacing settings
git-svn-id: svn://svn.rockbox.org/rockbox/trunk@19942 a1c6a512-1295-4272-9138-f99709370657
Diffstat (limited to 'apps/plugins/pictureflow.c')
-rw-r--r-- | apps/plugins/pictureflow.c | 154 |
1 files changed, 98 insertions, 56 deletions
diff --git a/apps/plugins/pictureflow.c b/apps/plugins/pictureflow.c index 0e48a64e2d..bd51a88b36 100644 --- a/apps/plugins/pictureflow.c +++ b/apps/plugins/pictureflow.c | |||
@@ -111,6 +111,9 @@ typedef fb_data pix_t; | |||
111 | #define REFLECT_SC ((0x10000U * 3 + (REFLECT_HEIGHT * 5 - 1)) / \ | 111 | #define REFLECT_SC ((0x10000U * 3 + (REFLECT_HEIGHT * 5 - 1)) / \ |
112 | (REFLECT_HEIGHT * 5)) | 112 | (REFLECT_HEIGHT * 5)) |
113 | #define DISPLAY_OFFS ((LCD_HEIGHT / 2) - REFLECT_HEIGHT) | 113 | #define DISPLAY_OFFS ((LCD_HEIGHT / 2) - REFLECT_HEIGHT) |
114 | #define CAM_DIST MAX(MIN(LCD_HEIGHT,LCD_WIDTH),120) | ||
115 | #define CAM_DIST_R (CAM_DIST << PFREAL_SHIFT) | ||
116 | #define DISPLAY_LEFT_R (PFREAL_HALF - LCD_WIDTH * PFREAL_ONE / 2) | ||
114 | 117 | ||
115 | #define SLIDE_CACHE_SIZE 100 | 118 | #define SLIDE_CACHE_SIZE 100 |
116 | 119 | ||
@@ -235,7 +238,6 @@ static struct configdata config[] = | |||
235 | /** below we allocate the memory we want to use **/ | 238 | /** below we allocate the memory we want to use **/ |
236 | 239 | ||
237 | static pix_t *buffer; /* for now it always points to the lcd framebuffer */ | 240 | static pix_t *buffer; /* for now it always points to the lcd framebuffer */ |
238 | static PFreal rays[LCD_WIDTH]; | ||
239 | static uint16_t reflect_table[REFLECT_HEIGHT]; | 241 | static uint16_t reflect_table[REFLECT_HEIGHT]; |
240 | static struct slide_data center_slide; | 242 | static struct slide_data center_slide; |
241 | static struct slide_data left_slides[MAX_SLIDES_COUNT]; | 243 | static struct slide_data left_slides[MAX_SLIDES_COUNT]; |
@@ -337,6 +339,16 @@ static inline PFreal fmul(PFreal a, PFreal b) | |||
337 | return (a*b) >> PFREAL_SHIFT; | 339 | return (a*b) >> PFREAL_SHIFT; |
338 | } | 340 | } |
339 | 341 | ||
342 | /** | ||
343 | * This version preshifts each operand, which is useful when we know how many | ||
344 | * of the least significant bits will be empty, or are worried about overflow | ||
345 | * in a particular calculation | ||
346 | */ | ||
347 | static inline PFreal fmuln(PFreal a, PFreal b, int ps1, int ps2) | ||
348 | { | ||
349 | return ((a >> ps1) * (b >> ps2)) >> (PFREAL_SHIFT - ps1 - ps2); | ||
350 | } | ||
351 | |||
340 | /* ARMv5+ has a clz instruction equivalent to our function. | 352 | /* ARMv5+ has a clz instruction equivalent to our function. |
341 | */ | 353 | */ |
342 | #if (defined(CPU_ARM) && (ARM_ARCH > 4)) | 354 | #if (defined(CPU_ARM) && (ARM_ARCH > 4)) |
@@ -1193,23 +1205,28 @@ void reset_slides(void) | |||
1193 | /** | 1205 | /** |
1194 | Updates look-up table and other stuff necessary for the rendering. | 1206 | Updates look-up table and other stuff necessary for the rendering. |
1195 | Call this when the viewport size or slide dimension is changed. | 1207 | Call this when the viewport size or slide dimension is changed. |
1208 | * | ||
1209 | * To calculate the offset that will provide the proper margin, we use the same | ||
1210 | * projection used to render the slides. Assuming zo == 0, the solution for xc, | ||
1211 | * the slide center, is: | ||
1212 | * xp * xs * sin(r) | ||
1213 | * xc = xp - xs * cos(r) + ──────────────── | ||
1214 | * z | ||
1215 | * TODO: support moving the side slides toward or away from the camera | ||
1196 | */ | 1216 | */ |
1197 | void recalc_table(void) | 1217 | void recalc_offsets(void) |
1198 | { | 1218 | { |
1199 | int w = (LCD_WIDTH + 1) / 2; | 1219 | PFreal xs = PFREAL_HALF - DISPLAY_WIDTH * PFREAL_HALF; |
1200 | int h = (LCD_HEIGHT + 1) / 2; | 1220 | PFreal xp = DISPLAY_WIDTH * PFREAL_HALF - PFREAL_HALF + center_margin * |
1201 | int i; | 1221 | PFREAL_ONE; |
1202 | for (i = 0; i < w; i++) { | 1222 | PFreal cosr, sinr; |
1203 | PFreal gg = (PFREAL_HALF + i * PFREAL_ONE) / (2 * h); | ||
1204 | rays[w - i - 1] = -gg; | ||
1205 | rays[w + i] = gg; | ||
1206 | } | ||
1207 | 1223 | ||
1208 | itilt = 70 * IANGLE_MAX / 360; /* approx. 70 degrees tilted */ | 1224 | itilt = 70 * IANGLE_MAX / 360; /* approx. 70 degrees tilted */ |
1209 | 1225 | cosr = fcos(-itilt); | |
1210 | offsetX = DISPLAY_WIDTH / 2 * (fsin(itilt) + PFREAL_ONE); | 1226 | sinr = fsin(-itilt); |
1227 | offsetX = xp - fmul(xs, cosr) + fmuln(xp, | ||
1228 | fmuln(xs, sinr, PFREAL_SHIFT - 2, 0), PFREAL_SHIFT - 2, 0)/CAM_DIST; | ||
1211 | offsetY = DISPLAY_WIDTH / 2 * (fsin(itilt) + PFREAL_ONE / 2); | 1229 | offsetY = DISPLAY_WIDTH / 2 * (fsin(itilt) + PFREAL_ONE / 2); |
1212 | offsetX += center_margin << PFREAL_SHIFT; | ||
1213 | } | 1230 | } |
1214 | 1231 | ||
1215 | 1232 | ||
@@ -1246,68 +1263,83 @@ static inline pix_t fade_color(pix_t c, unsigned int a) | |||
1246 | #endif | 1263 | #endif |
1247 | 1264 | ||
1248 | /** | 1265 | /** |
1249 | Render a single slide | 1266 | * Render a single slide |
1250 | */ | 1267 | * Where xc is the slide's horizontal offset from center, xs is the horizontal |
1268 | * on the slide from its center, zo is the slide's depth offset from the plane | ||
1269 | * of the display, r is the angle at which the slide is tilted, and xp is the | ||
1270 | * point on the display corresponding to xs on the slide, the projection | ||
1271 | * formulas are: | ||
1272 | * | ||
1273 | * z * (xc + xs * cos(r)) | ||
1274 | * xp = ────────────────────── | ||
1275 | * z + zo + xs * sin(r) | ||
1276 | * | ||
1277 | * z * (xc - xp) - xp * zo | ||
1278 | * xs = ──────────────────────── | ||
1279 | * xp * sin(r) - z * cos(r) | ||
1280 | * | ||
1281 | * We use the xp projection once, to find the left edge of the slide on the | ||
1282 | * display. From there, we use the xs reverse projection to find the horizontal | ||
1283 | * offset from the slide center of each column on the screen, until we reach | ||
1284 | * the right edge of the slide, or the screen. The reverse projection can be | ||
1285 | * optimized by saving the numerator and denominator of the fraction, which can | ||
1286 | * then be incremented by (z + zo) and sin(r) respectively. | ||
1287 | */ | ||
1251 | void render_slide(struct slide_data *slide, const int alpha) | 1288 | void render_slide(struct slide_data *slide, const int alpha) |
1252 | { | 1289 | { |
1253 | struct bitmap *bmp = surface(slide->slide_index); | 1290 | struct bitmap *bmp = surface(slide->slide_index); |
1254 | if (!bmp) { | 1291 | if (!bmp) { |
1255 | return; | 1292 | return; |
1256 | } | 1293 | } |
1294 | if (slide->angle > 255 || slide->angle < -255) | ||
1295 | return; | ||
1257 | pix_t *src = (pix_t *)bmp->data; | 1296 | pix_t *src = (pix_t *)bmp->data; |
1258 | 1297 | ||
1259 | const int sw = bmp->width; | 1298 | const int sw = bmp->width; |
1260 | const int sh = bmp->height; | 1299 | const int sh = bmp->height; |
1300 | const PFreal slide_left = -sw * PFREAL_HALF + PFREAL_HALF; | ||
1261 | 1301 | ||
1262 | const int h = LCD_HEIGHT; | 1302 | const int h = LCD_HEIGHT; |
1263 | const int w = LCD_WIDTH; | 1303 | const int w = LCD_WIDTH; |
1264 | 1304 | ||
1265 | 1305 | ||
1266 | int distance = (h + slide->distance) * 100 / zoom; | 1306 | PFreal zo = (CAM_DIST_R + PFREAL_ONE * slide->distance) * 100 / zoom - |
1267 | if (distance < 100 ) distance = 100; /* clamp distances */ | 1307 | CAM_DIST_R; |
1268 | PFreal dist = distance * PFREAL_ONE; | 1308 | PFreal cosr = fcos(slide->angle); |
1269 | PFreal sdx = fcos(slide->angle); | 1309 | PFreal sinr = fsin(slide->angle); |
1270 | PFreal sdy = fsin(slide->angle); | 1310 | PFreal xs = slide_left, xsnum, xsnumi, xsden, xsdeni; |
1271 | PFreal xs = slide->cx - sw * fdiv(sdx, dist) / 2; | 1311 | PFreal xp = fdiv(CAM_DIST * (slide->cx + fmul(xs, cosr)), |
1272 | 1312 | (CAM_DIST_R + zo + fmul(xs,sinr))); | |
1273 | int xi = fmax(0, xs) >> PFREAL_SHIFT; | 1313 | |
1314 | /* Since we're finding the screen position of the left edge of the slide, | ||
1315 | * we round up. | ||
1316 | */ | ||
1317 | int xi = (fmax(DISPLAY_LEFT_R, xp) - DISPLAY_LEFT_R + PFREAL_ONE - 1) | ||
1318 | >> PFREAL_SHIFT; | ||
1319 | xp = DISPLAY_LEFT_R + xi * PFREAL_ONE; | ||
1274 | if (xi >= w) { | 1320 | if (xi >= w) { |
1275 | return; | 1321 | return; |
1276 | } | 1322 | } |
1277 | 1323 | xsnum = CAM_DIST * (slide->cx - xp) - fmuln(xp, zo, PFREAL_SHIFT - 2, 0); | |
1324 | xsden = fmuln(xp, sinr, PFREAL_SHIFT - 2, 0) - CAM_DIST * cosr; | ||
1325 | xs = fdiv(xsnum, xsden); | ||
1326 | |||
1327 | xsnumi = -CAM_DIST_R - zo; | ||
1328 | xsdeni = sinr; | ||
1278 | int x; | 1329 | int x; |
1279 | for (x = fmax(xi, 0); x < w; x++) { | 1330 | int dy = PFREAL_ONE; |
1280 | PFreal hity = 0; | 1331 | for (x = xi; x < w; x++) { |
1281 | PFreal fk = rays[x]; | 1332 | int column = (xs - slide_left) / PFREAL_ONE; |
1282 | if (sdy) { | ||
1283 | fk = fk - fdiv(sdx, sdy); | ||
1284 | if (fk) | ||
1285 | hity = -fdiv(( rays[x] * distance | ||
1286 | - slide->cx | ||
1287 | + slide->cy * sdx / sdy), fk); | ||
1288 | } | ||
1289 | |||
1290 | dist = distance * PFREAL_ONE + hity; | ||
1291 | if (dist < 0) | ||
1292 | continue; | ||
1293 | |||
1294 | PFreal hitx = fmul(dist, rays[x]); | ||
1295 | |||
1296 | PFreal hitdist = fdiv(hitx - slide->cx, sdx); | ||
1297 | |||
1298 | const int column = (sw >> 1) + (hitdist >> PFREAL_SHIFT); | ||
1299 | if (column >= sw) | 1333 | if (column >= sw) |
1300 | break; | 1334 | break; |
1301 | if (column < 0) | 1335 | if (zo || slide->angle) |
1302 | continue; | 1336 | dy = (CAM_DIST_R + zo + fmul(xs, sinr)) / CAM_DIST; |
1303 | |||
1304 | int y1 = (LCD_HEIGHT / 2) - 1; | 1337 | int y1 = (LCD_HEIGHT / 2) - 1; |
1305 | int y2 = y1 + 1; | 1338 | int y2 = y1 + 1; |
1306 | pix_t *pixel1 = &buffer[y1 * BUFFER_WIDTH + x]; | 1339 | pix_t *pixel1 = &buffer[y1 * BUFFER_WIDTH + x]; |
1307 | pix_t *pixel2 = &buffer[y2 * BUFFER_WIDTH + x]; | 1340 | pix_t *pixel2 = pixel1 + BUFFER_WIDTH; |
1308 | const int pixelstep = pixel2 - pixel1; | 1341 | const int pixelstep = BUFFER_WIDTH; |
1309 | 1342 | ||
1310 | int dy = dist / h; | ||
1311 | int p1 = (bmp->height - 1 - (DISPLAY_OFFS)) * PFREAL_ONE; | 1343 | int p1 = (bmp->height - 1 - (DISPLAY_OFFS)) * PFREAL_ONE; |
1312 | int p2 = p1 + dy; | 1344 | int p2 = p1 + dy; |
1313 | const pix_t *ptr = &src[column * bmp->height]; | 1345 | const pix_t *ptr = &src[column * bmp->height]; |
@@ -1340,6 +1372,7 @@ void render_slide(struct slide_data *slide, const int alpha) | |||
1340 | } | 1372 | } |
1341 | } | 1373 | } |
1342 | else | 1374 | else |
1375 | { | ||
1343 | while ((y1 >= 0) && (p1 >= 0)) | 1376 | while ((y1 >= 0) && (p1 >= 0)) |
1344 | { | 1377 | { |
1345 | *pixel1 = fade_color(ptr[p1 >> PFREAL_SHIFT],alpha); | 1378 | *pixel1 = fade_color(ptr[p1 >> PFREAL_SHIFT],alpha); |
@@ -1364,6 +1397,15 @@ void render_slide(struct slide_data *slide, const int alpha) | |||
1364 | y2++; | 1397 | y2++; |
1365 | pixel2 += pixelstep; | 1398 | pixel2 += pixelstep; |
1366 | } | 1399 | } |
1400 | } | ||
1401 | if (zo || slide->angle) | ||
1402 | { | ||
1403 | xsnum += xsnumi; | ||
1404 | xsden += xsdeni; | ||
1405 | xs = fdiv(xsnum, xsden); | ||
1406 | } else | ||
1407 | xs += PFREAL_ONE; | ||
1408 | |||
1367 | } | 1409 | } |
1368 | /* let the music play... */ | 1410 | /* let the music play... */ |
1369 | rb->yield(); | 1411 | rb->yield(); |
@@ -1684,7 +1726,7 @@ int settings_menu(void) | |||
1684 | rb->set_int("Spacing between slides", "", 1, | 1726 | rb->set_int("Spacing between slides", "", 1, |
1685 | &slide_spacing, | 1727 | &slide_spacing, |
1686 | NULL, 1, 0, 100, NULL ); | 1728 | NULL, 1, 0, 100, NULL ); |
1687 | recalc_table(); | 1729 | recalc_offsets(); |
1688 | reset_slides(); | 1730 | reset_slides(); |
1689 | break; | 1731 | break; |
1690 | 1732 | ||
@@ -1692,27 +1734,27 @@ int settings_menu(void) | |||
1692 | rb->set_int("Center margin", "", 1, | 1734 | rb->set_int("Center margin", "", 1, |
1693 | ¢er_margin, | 1735 | ¢er_margin, |
1694 | NULL, 1, 0, 80, NULL ); | 1736 | NULL, 1, 0, 80, NULL ); |
1695 | recalc_table(); | 1737 | recalc_offsets(); |
1696 | reset_slides(); | 1738 | reset_slides(); |
1697 | break; | 1739 | break; |
1698 | 1740 | ||
1699 | case 3: | 1741 | case 3: |
1700 | rb->set_int("Number of slides", "", 1, &num_slides, | 1742 | rb->set_int("Number of slides", "", 1, &num_slides, |
1701 | NULL, 1, 1, MAX_SLIDES_COUNT, NULL ); | 1743 | NULL, 1, 1, MAX_SLIDES_COUNT, NULL ); |
1702 | recalc_table(); | 1744 | recalc_offsets(); |
1703 | reset_slides(); | 1745 | reset_slides(); |
1704 | break; | 1746 | break; |
1705 | 1747 | ||
1706 | case 4: | 1748 | case 4: |
1707 | rb->set_int("Zoom", "", 1, &zoom, | 1749 | rb->set_int("Zoom", "", 1, &zoom, |
1708 | NULL, 1, 10, 300, NULL ); | 1750 | NULL, 1, 10, 300, NULL ); |
1709 | recalc_table(); | 1751 | recalc_offsets(); |
1710 | reset_slides(); | 1752 | reset_slides(); |
1711 | break; | 1753 | break; |
1712 | case 5: | 1754 | case 5: |
1713 | album_name_menu(); | 1755 | album_name_menu(); |
1714 | reset_track_list(); | 1756 | reset_track_list(); |
1715 | recalc_table(); | 1757 | recalc_offsets(); |
1716 | reset_slides(); | 1758 | reset_slides(); |
1717 | break; | 1759 | break; |
1718 | case 6: | 1760 | case 6: |
@@ -2076,7 +2118,7 @@ int main(void) | |||
2076 | target = 0; | 2118 | target = 0; |
2077 | fade = 256; | 2119 | fade = 256; |
2078 | 2120 | ||
2079 | recalc_table(); | 2121 | recalc_offsets(); |
2080 | reset_slides(); | 2122 | reset_slides(); |
2081 | 2123 | ||
2082 | char fpstxt[10]; | 2124 | char fpstxt[10]; |