1 /* 2 * Copyright (C) 2010 The Android Open Source Project 3 * Copyright (C) 2012-2014, The Linux Foundation All rights reserved. 4 * 5 * Not a Contribution, Apache license notifications and license are retained 6 * for attribution purposes only. 7 * 8 * Licensed under the Apache License, Version 2.0 (the "License"); 9 * you may not use this file except in compliance with the License. 10 * You may obtain a copy of the License at 11 * 12 * http://www.apache.org/licenses/LICENSE-2.0 13 * 14 * Unless required by applicable law or agreed to in writing, software 15 * distributed under the License is distributed on an "AS IS" BASIS, 16 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 17 * See the License for the specific language governing permissions and 18 * limitations under the License. 19 */ 20 #define ATRACE_TAG (ATRACE_TAG_GRAPHICS | ATRACE_TAG_HAL) 21 #define HWC_UTILS_DEBUG 0 22 #include <math.h> 23 #include <sys/ioctl.h> 24 #include <linux/fb.h> 25 #include <binder/IServiceManager.h> 26 #include <EGL/egl.h> 27 #include <cutils/properties.h> 28 #include <utils/Trace.h> 29 #include <gralloc_priv.h> 30 #include <overlay.h> 31 #include <overlayRotator.h> 32 #include <overlayWriteback.h> 33 #include "hwc_utils.h" 34 #include "hwc_mdpcomp.h" 35 #include "hwc_fbupdate.h" 36 #include "hwc_ad.h" 37 #include "mdp_version.h" 38 #include "hwc_copybit.h" 39 #include "hwc_dump_layers.h" 40 #include "hdmi.h" 41 #include "hwc_qclient.h" 42 #include "QService.h" 43 #include "comptype.h" 44 #include "hwc_virtual.h" 45 #include "qd_utils.h" 46 #include <sys/sysinfo.h> 47 #include <dlfcn.h> 48 49 using namespace qClient; 50 using namespace qService; 51 using namespace android; 52 using namespace overlay; 53 using namespace overlay::utils; 54 namespace ovutils = overlay::utils; 55 56 #ifdef QCOM_BSP 57 #ifdef __cplusplus 58 extern "C" { 59 #endif 60 61 EGLAPI EGLBoolean eglGpuPerfHintQCOM(EGLDisplay dpy, EGLContext ctx, 62 EGLint *attrib_list); 63 #define EGL_GPU_HINT_1 0x32D0 64 #define EGL_GPU_HINT_2 0x32D1 65 66 #define EGL_GPU_LEVEL_0 0x0 67 #define EGL_GPU_LEVEL_1 0x1 68 #define EGL_GPU_LEVEL_2 0x2 69 #define EGL_GPU_LEVEL_3 0x3 70 #define EGL_GPU_LEVEL_4 0x4 71 #define EGL_GPU_LEVEL_5 0x5 72 73 #ifdef __cplusplus 74 } 75 #endif 76 #endif 77 78 #define PROP_DEFAULT_APPBUFFER "ro.sf.default_app_buffer" 79 #define MAX_RAM_SIZE 512*1024*1024 80 #define qHD_WIDTH 540 81 82 83 namespace qhwc { 84 85 // Std refresh rates for digital videos- 24p, 30p, 48p and 60p 86 uint32_t stdRefreshRates[] = { 30, 24, 48, 60 }; 87 88 bool isValidResolution(hwc_context_t *ctx, uint32_t xres, uint32_t yres) 89 { 90 return !((xres > qdutils::MDPVersion::getInstance().getMaxPipeWidth() && 91 !isDisplaySplit(ctx, HWC_DISPLAY_PRIMARY)) || 92 (xres < MIN_DISPLAY_XRES || yres < MIN_DISPLAY_YRES)); 93 } 94 95 void changeResolution(hwc_context_t *ctx, int xres_orig, int yres_orig, 96 int width, int height) { 97 //Store original display resolution. 98 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres_new = xres_orig; 99 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres_new = yres_orig; 100 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].customFBSize = false; 101 char property[PROPERTY_VALUE_MAX] = {'\0'}; 102 char *yptr = NULL; 103 if (property_get("debug.hwc.fbsize", property, NULL) > 0) { 104 yptr = strcasestr(property,"x"); 105 if(yptr) { 106 int xres_new = atoi(property); 107 int yres_new = atoi(yptr + 1); 108 if (isValidResolution(ctx,xres_new,yres_new) && 109 xres_new != xres_orig && yres_new != yres_orig) { 110 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres_new = xres_new; 111 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres_new = yres_new; 112 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].customFBSize = true; 113 114 //Caluculate DPI according to changed resolution. 115 float xdpi = ((float)xres_new * 25.4f) / (float)width; 116 float ydpi = ((float)yres_new * 25.4f) / (float)height; 117 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xdpi = xdpi; 118 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].ydpi = ydpi; 119 } 120 } 121 } 122 } 123 124 // Initialize hdmi display attributes based on 125 // hdmi display class state 126 void updateDisplayInfo(hwc_context_t* ctx, int dpy) { 127 ctx->dpyAttr[dpy].fd = ctx->mHDMIDisplay->getFd(); 128 ctx->dpyAttr[dpy].xres = ctx->mHDMIDisplay->getWidth(); 129 ctx->dpyAttr[dpy].yres = ctx->mHDMIDisplay->getHeight(); 130 ctx->dpyAttr[dpy].mMDPScalingMode = ctx->mHDMIDisplay->getMDPScalingMode(); 131 ctx->dpyAttr[dpy].vsync_period = ctx->mHDMIDisplay->getVsyncPeriod(); 132 //FIXME: for now assume HDMI as secure 133 //Will need to read the HDCP status from the driver 134 //and update this accordingly 135 ctx->dpyAttr[dpy].secure = true; 136 ctx->mViewFrame[dpy].left = 0; 137 ctx->mViewFrame[dpy].top = 0; 138 ctx->mViewFrame[dpy].right = ctx->dpyAttr[dpy].xres; 139 ctx->mViewFrame[dpy].bottom = ctx->dpyAttr[dpy].yres; 140 } 141 142 // Reset hdmi display attributes and list stats structures 143 void resetDisplayInfo(hwc_context_t* ctx, int dpy) { 144 memset(&(ctx->dpyAttr[dpy]), 0, sizeof(ctx->dpyAttr[dpy])); 145 memset(&(ctx->listStats[dpy]), 0, sizeof(ctx->listStats[dpy])); 146 // We reset the fd to -1 here but External display class is responsible 147 // for it when the display is disconnected. This is handled as part of 148 // EXTERNAL_OFFLINE event. 149 ctx->dpyAttr[dpy].fd = -1; 150 } 151 152 // Initialize composition resources 153 void initCompositionResources(hwc_context_t* ctx, int dpy) { 154 ctx->mFBUpdate[dpy] = IFBUpdate::getObject(ctx, dpy); 155 ctx->mMDPComp[dpy] = MDPComp::getObject(ctx, dpy); 156 } 157 158 void destroyCompositionResources(hwc_context_t* ctx, int dpy) { 159 if(ctx->mFBUpdate[dpy]) { 160 delete ctx->mFBUpdate[dpy]; 161 ctx->mFBUpdate[dpy] = NULL; 162 } 163 if(ctx->mMDPComp[dpy]) { 164 delete ctx->mMDPComp[dpy]; 165 ctx->mMDPComp[dpy] = NULL; 166 } 167 } 168 169 static int openFramebufferDevice(hwc_context_t *ctx) 170 { 171 struct fb_fix_screeninfo finfo; 172 struct fb_var_screeninfo info; 173 174 int fb_fd = openFb(HWC_DISPLAY_PRIMARY); 175 if(fb_fd < 0) { 176 ALOGE("%s: Error Opening FB : %s", __FUNCTION__, strerror(errno)); 177 return -errno; 178 } 179 180 if (ioctl(fb_fd, FBIOGET_VSCREENINFO, &info) == -1) { 181 ALOGE("%s:Error in ioctl FBIOGET_VSCREENINFO: %s", __FUNCTION__, 182 strerror(errno)); 183 close(fb_fd); 184 return -errno; 185 } 186 187 if (int(info.width) <= 0 || int(info.height) <= 0) { 188 // the driver doesn't return that information 189 // default to 160 dpi 190 info.width = (int)(((float)info.xres * 25.4f)/160.0f + 0.5f); 191 info.height = (int)(((float)info.yres * 25.4f)/160.0f + 0.5f); 192 } 193 194 float xdpi = ((float)info.xres * 25.4f) / (float)info.width; 195 float ydpi = ((float)info.yres * 25.4f) / (float)info.height; 196 197 #ifdef MSMFB_METADATA_GET 198 struct msmfb_metadata metadata; 199 memset(&metadata, 0 , sizeof(metadata)); 200 metadata.op = metadata_op_frame_rate; 201 202 if (ioctl(fb_fd, MSMFB_METADATA_GET, &metadata) == -1) { 203 ALOGE("%s:Error retrieving panel frame rate: %s", __FUNCTION__, 204 strerror(errno)); 205 close(fb_fd); 206 return -errno; 207 } 208 209 float fps = (float)metadata.data.panel_frame_rate; 210 #else 211 //XXX: Remove reserved field usage on all baselines 212 //The reserved[3] field is used to store FPS by the driver. 213 float fps = info.reserved[3] & 0xFF; 214 #endif 215 216 if (ioctl(fb_fd, FBIOGET_FSCREENINFO, &finfo) == -1) { 217 ALOGE("%s:Error in ioctl FBIOGET_FSCREENINFO: %s", __FUNCTION__, 218 strerror(errno)); 219 close(fb_fd); 220 return -errno; 221 } 222 223 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].fd = fb_fd; 224 //xres, yres may not be 32 aligned 225 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].stride = finfo.line_length /(info.xres/8); 226 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres = info.xres; 227 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres = info.yres; 228 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xdpi = xdpi; 229 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].ydpi = ydpi; 230 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].refreshRate = (uint32_t)fps; 231 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].dynRefreshRate = (uint32_t)fps; 232 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].secure = true; 233 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].vsync_period = 234 (uint32_t)(1000000000l / fps); 235 236 //To change resolution of primary display 237 changeResolution(ctx, info.xres, info.yres, info.width, info.height); 238 239 //Unblank primary on first boot 240 if(ioctl(fb_fd, FBIOBLANK,FB_BLANK_UNBLANK) < 0) { 241 ALOGE("%s: Failed to unblank display", __FUNCTION__); 242 return -errno; 243 } 244 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].isActive = true; 245 246 return 0; 247 } 248 249 static void changeDefaultAppBufferCount() { 250 struct sysinfo info; 251 unsigned long int ramSize = 0; 252 if (!sysinfo(&info)) { 253 ramSize = info.totalram ; 254 } 255 int fb_fd = -1; 256 struct fb_var_screeninfo sInfo ={0}; 257 fb_fd = open("/dev/graphics/fb0", O_RDONLY); 258 if (fb_fd >=0) { 259 ioctl(fb_fd, FBIOGET_VSCREENINFO, &sInfo); 260 close(fb_fd); 261 } 262 if ((ramSize && ramSize < MAX_RAM_SIZE) && 263 (sInfo.xres && sInfo.xres <= qHD_WIDTH )) { 264 property_set(PROP_DEFAULT_APPBUFFER, "2"); 265 } 266 } 267 268 void initContext(hwc_context_t *ctx) 269 { 270 overlay::Overlay::initOverlay(); 271 ctx->mHDMIDisplay = new HDMIDisplay(); 272 uint32_t priW = 0, priH = 0; 273 // 1. HDMI as Primary 274 // -If HDMI cable is connected, read display configs from edid data 275 // -If HDMI cable is not connected then use default data in vscreeninfo 276 // 2. HDMI as External 277 // -Initialize HDMI class for use with external display 278 // -Use vscreeninfo to populate display configs 279 if(ctx->mHDMIDisplay->isHDMIPrimaryDisplay()) { 280 int connected = ctx->mHDMIDisplay->getConnectedState(); 281 if(connected == 1) { 282 ctx->mHDMIDisplay->configure(); 283 updateDisplayInfo(ctx, HWC_DISPLAY_PRIMARY); 284 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].connected = true; 285 } else { 286 openFramebufferDevice(ctx); 287 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].connected = false; 288 } 289 } else { 290 openFramebufferDevice(ctx); 291 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].connected = true; 292 // Send the primary resolution to the hdmi display class 293 // to be used for MDP scaling functionality 294 priW = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres; 295 priH = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres; 296 ctx->mHDMIDisplay->setPrimaryAttributes(priW, priH); 297 } 298 299 char value[PROPERTY_VALUE_MAX]; 300 ctx->mMDP.version = qdutils::MDPVersion::getInstance().getMDPVersion(); 301 ctx->mMDP.hasOverlay = qdutils::MDPVersion::getInstance().hasOverlay(); 302 ctx->mMDP.panel = qdutils::MDPVersion::getInstance().getPanelType(); 303 ctx->mOverlay = overlay::Overlay::getInstance(); 304 ctx->mRotMgr = RotMgr::getInstance(); 305 ctx->mBWCEnabled = qdutils::MDPVersion::getInstance().supportsBWC(); 306 307 //default_app_buffer for ferrum 308 if (ctx->mMDP.version == qdutils::MDP_V3_0_5) { 309 changeDefaultAppBufferCount(); 310 } 311 // Initialize composition objects for the primary display 312 initCompositionResources(ctx, HWC_DISPLAY_PRIMARY); 313 314 // Check if the target supports copybit compostion (dyn/mdp) to 315 // decide if we need to open the copybit module. 316 int compositionType = 317 qdutils::QCCompositionType::getInstance().getCompositionType(); 318 319 // Only MDP copybit is used 320 if ((compositionType & (qdutils::COMPOSITION_TYPE_DYN | 321 qdutils::COMPOSITION_TYPE_MDP)) && 322 ((qdutils::MDPVersion::getInstance().getMDPVersion() == 323 qdutils::MDP_V3_0_4) || 324 (qdutils::MDPVersion::getInstance().getMDPVersion() == 325 qdutils::MDP_V3_0_5))) { 326 ctx->mCopyBit[HWC_DISPLAY_PRIMARY] = new CopyBit(ctx, 327 HWC_DISPLAY_PRIMARY); 328 } 329 330 ctx->mHWCVirtual = new HWCVirtualVDS(); 331 ctx->dpyAttr[HWC_DISPLAY_EXTERNAL].isActive = false; 332 ctx->dpyAttr[HWC_DISPLAY_EXTERNAL].connected = false; 333 ctx->dpyAttr[HWC_DISPLAY_VIRTUAL].isActive = false; 334 ctx->dpyAttr[HWC_DISPLAY_VIRTUAL].connected = false; 335 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].mMDPScalingMode= false; 336 ctx->dpyAttr[HWC_DISPLAY_EXTERNAL].mMDPScalingMode = false; 337 ctx->dpyAttr[HWC_DISPLAY_VIRTUAL].mMDPScalingMode = false; 338 339 //Initialize the primary display viewFrame info 340 ctx->mViewFrame[HWC_DISPLAY_PRIMARY].left = 0; 341 ctx->mViewFrame[HWC_DISPLAY_PRIMARY].top = 0; 342 ctx->mViewFrame[HWC_DISPLAY_PRIMARY].right = 343 (int)ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres; 344 ctx->mViewFrame[HWC_DISPLAY_PRIMARY].bottom = 345 (int)ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres; 346 347 for (uint32_t i = 0; i < HWC_NUM_DISPLAY_TYPES; i++) { 348 ctx->mHwcDebug[i] = new HwcDebug(i); 349 ctx->mLayerRotMap[i] = new LayerRotMap(); 350 ctx->mAnimationState[i] = ANIMATION_STOPPED; 351 ctx->dpyAttr[i].mActionSafePresent = false; 352 ctx->dpyAttr[i].mAsWidthRatio = 0; 353 ctx->dpyAttr[i].mAsHeightRatio = 0; 354 } 355 356 for (uint32_t i = 0; i < HWC_NUM_DISPLAY_TYPES; i++) { 357 ctx->mPrevHwLayerCount[i] = 0; 358 } 359 360 MDPComp::init(ctx); 361 ctx->mAD = new AssertiveDisplay(ctx); 362 363 ctx->vstate.enable = false; 364 ctx->vstate.fakevsync = false; 365 ctx->mExtOrientation = 0; 366 ctx->numActiveDisplays = 1; 367 368 //Right now hwc starts the service but anybody could do it, or it could be 369 //independent process as well. 370 QService::init(); 371 sp<IQClient> client = new QClient(ctx); 372 android::sp<qService::IQService> qservice_sp = interface_cast<IQService>( 373 defaultServiceManager()->getService( 374 String16("display.qservice"))); 375 if (qservice_sp.get()) { 376 qservice_sp->connect(client); 377 } else { 378 ALOGE("%s: Failed to acquire service pointer", __FUNCTION__); 379 return ; 380 } 381 382 // Initialize device orientation to its default orientation 383 ctx->deviceOrientation = 0; 384 ctx->mBufferMirrorMode = false; 385 386 property_get("sys.hwc.windowbox_aspect_ratio_tolerance", value, "0"); 387 ctx->mAspectRatioToleranceLevel = (((float)atoi(value)) / 100.0f); 388 389 ctx->enableABC = false; 390 property_get("debug.sf.hwc.canUseABC", value, "0"); 391 ctx->enableABC = atoi(value) ? true : false; 392 393 // Initializing boot anim completed check to false 394 ctx->mDefaultModeApplied = false; 395 396 ctx->mCoolColorTemperatureEnabled = false; 397 398 // Initialize gpu perfomance hint related parameters 399 property_get("sys.hwc.gpu_perf_mode", value, "0"); 400 #ifdef QCOM_BSP 401 ctx->mGPUHintInfo.mGpuPerfModeEnable = atoi(value)? true : false; 402 403 ctx->mGPUHintInfo.mEGLDisplay = NULL; 404 ctx->mGPUHintInfo.mEGLContext = NULL; 405 ctx->mGPUHintInfo.mCompositionState = COMPOSITION_STATE_MDP; 406 ctx->mGPUHintInfo.mCurrGPUPerfMode = EGL_GPU_LEVEL_0; 407 #endif 408 // Read the system property to determine if windowboxing feature is enabled. 409 ctx->mWindowboxFeature = false; 410 if(property_get("sys.hwc.windowbox_feature", value, "false") 411 && !strcmp(value, "true")) { 412 ctx->mWindowboxFeature = true; 413 } 414 415 ctx->mUseMetaDataRefreshRate = true; 416 if(property_get("persist.metadata_dynfps.disable", value, "false") 417 && !strcmp(value, "true")) { 418 ctx->mUseMetaDataRefreshRate = false; 419 } 420 421 memset(&(ctx->mPtorInfo), 0, sizeof(ctx->mPtorInfo)); 422 ctx->mHPDEnabled = false; 423 ctx->mColorMode = new ColorMode(); 424 ctx->mColorMode->init(); 425 ALOGI("Initializing Qualcomm Hardware Composer"); 426 ALOGI("MDP version: %d", ctx->mMDP.version); 427 } 428 429 void closeContext(hwc_context_t *ctx) 430 { 431 if(ctx->mOverlay) { 432 delete ctx->mOverlay; 433 ctx->mOverlay = NULL; 434 } 435 436 if(ctx->mRotMgr) { 437 delete ctx->mRotMgr; 438 ctx->mRotMgr = NULL; 439 } 440 441 for(int i = 0; i < HWC_NUM_DISPLAY_TYPES; i++) { 442 if(ctx->mCopyBit[i]) { 443 delete ctx->mCopyBit[i]; 444 ctx->mCopyBit[i] = NULL; 445 } 446 } 447 448 if(ctx->dpyAttr[HWC_DISPLAY_PRIMARY].fd) { 449 close(ctx->dpyAttr[HWC_DISPLAY_PRIMARY].fd); 450 ctx->dpyAttr[HWC_DISPLAY_PRIMARY].fd = -1; 451 } 452 453 if(ctx->mHDMIDisplay) { 454 delete ctx->mHDMIDisplay; 455 ctx->mHDMIDisplay = NULL; 456 } 457 458 for(int i = 0; i < HWC_NUM_DISPLAY_TYPES; i++) { 459 destroyCompositionResources(ctx, i); 460 461 if(ctx->mHwcDebug[i]) { 462 delete ctx->mHwcDebug[i]; 463 ctx->mHwcDebug[i] = NULL; 464 } 465 if(ctx->mLayerRotMap[i]) { 466 delete ctx->mLayerRotMap[i]; 467 ctx->mLayerRotMap[i] = NULL; 468 } 469 } 470 if(ctx->mHWCVirtual) { 471 delete ctx->mHWCVirtual; 472 ctx->mHWCVirtual = NULL; 473 } 474 if(ctx->mAD) { 475 delete ctx->mAD; 476 ctx->mAD = NULL; 477 } 478 479 if(ctx->mColorMode) { 480 ctx->mColorMode->destroy(); 481 delete ctx->mColorMode; 482 ctx->mColorMode = NULL; 483 } 484 } 485 486 //Helper to roundoff the refreshrates 487 uint32_t roundOff(uint32_t refreshRate) { 488 int count = (int) (sizeof(stdRefreshRates)/sizeof(stdRefreshRates[0])); 489 uint32_t rate = refreshRate; 490 for(int i=0; i< count; i++) { 491 if(abs(stdRefreshRates[i] - refreshRate) < 2) { 492 // Most likely used for video, the fps can fluctuate 493 // Ex: b/w 29 and 30 for 30 fps clip 494 rate = stdRefreshRates[i]; 495 break; 496 } 497 } 498 return rate; 499 } 500 501 //Helper func to set the dyn fps 502 void setRefreshRate(hwc_context_t* ctx, int dpy, uint32_t refreshRate) { 503 //Update only if different 504 if(!ctx || refreshRate == ctx->dpyAttr[dpy].dynRefreshRate) 505 return; 506 const int fbNum = Overlay::getFbForDpy(dpy); 507 char sysfsPath[qdutils::MAX_SYSFS_FILE_PATH]; 508 snprintf (sysfsPath, sizeof(sysfsPath), 509 "/sys/devices/virtual/graphics/fb%d/dynamic_fps", fbNum); 510 511 int fd = open(sysfsPath, O_WRONLY); 512 if(fd >= 0) { 513 char str[64]; 514 snprintf(str, sizeof(str), "%d", refreshRate); 515 ssize_t ret = write(fd, str, strlen(str)); 516 if(ret < 0) { 517 ALOGE("%s: Failed to write %d with error %s", 518 __FUNCTION__, refreshRate, strerror(errno)); 519 } else { 520 ctx->dpyAttr[dpy].dynRefreshRate = refreshRate; 521 ALOGD_IF(HWC_UTILS_DEBUG, "%s: Wrote %d to dynamic_fps", 522 __FUNCTION__, refreshRate); 523 } 524 close(fd); 525 } else { 526 ALOGE("%s: Failed to open %s with error %s", __FUNCTION__, sysfsPath, 527 strerror(errno)); 528 } 529 } 530 531 void dumpsys_log(android::String8& buf, const char* fmt, ...) 532 { 533 va_list varargs; 534 va_start(varargs, fmt); 535 buf.appendFormatV(fmt, varargs); 536 va_end(varargs); 537 } 538 539 int getExtOrientation(hwc_context_t* ctx) { 540 int extOrient = ctx->mExtOrientation; 541 if(ctx->mBufferMirrorMode) 542 extOrient = getMirrorModeOrientation(ctx); 543 return extOrient; 544 } 545 546 /* Calculates the destination position based on the action safe rectangle */ 547 void getActionSafePosition(hwc_context_t *ctx, int dpy, hwc_rect_t& rect) { 548 // Position 549 int x = rect.left, y = rect.top; 550 int w = rect.right - rect.left; 551 int h = rect.bottom - rect.top; 552 553 if(!ctx->dpyAttr[dpy].mActionSafePresent) 554 return; 555 // Read action safe properties 556 int asWidthRatio = ctx->dpyAttr[dpy].mAsWidthRatio; 557 int asHeightRatio = ctx->dpyAttr[dpy].mAsHeightRatio; 558 559 float wRatio = 1.0; 560 float hRatio = 1.0; 561 float xRatio = 1.0; 562 float yRatio = 1.0; 563 564 uint32_t fbWidth = ctx->dpyAttr[dpy].xres; 565 uint32_t fbHeight = ctx->dpyAttr[dpy].yres; 566 if(ctx->dpyAttr[dpy].mMDPScalingMode) { 567 // if MDP scaling mode is enabled for external, need to query 568 // the actual width and height, as that is the physical w & h 569 ctx->mHDMIDisplay->getAttributes(fbWidth, fbHeight); 570 } 571 572 573 // Since external is rotated 90, need to swap width/height 574 int extOrient = getExtOrientation(ctx); 575 576 if(extOrient & HWC_TRANSFORM_ROT_90) 577 swap(fbWidth, fbHeight); 578 579 float asX = 0; 580 float asY = 0; 581 float asW = (float)fbWidth; 582 float asH = (float)fbHeight; 583 584 // based on the action safe ratio, get the Action safe rectangle 585 asW = ((float)fbWidth * (1.0f - (float)asWidthRatio / 100.0f)); 586 asH = ((float)fbHeight * (1.0f - (float)asHeightRatio / 100.0f)); 587 asX = ((float)fbWidth - asW) / 2; 588 asY = ((float)fbHeight - asH) / 2; 589 590 // calculate the position ratio 591 xRatio = (float)x/(float)fbWidth; 592 yRatio = (float)y/(float)fbHeight; 593 wRatio = (float)w/(float)fbWidth; 594 hRatio = (float)h/(float)fbHeight; 595 596 //Calculate the position... 597 x = int((xRatio * asW) + asX); 598 y = int((yRatio * asH) + asY); 599 w = int(wRatio * asW); 600 h = int(hRatio * asH); 601 602 // Convert it back to hwc_rect_t 603 rect.left = x; 604 rect.top = y; 605 rect.right = w + rect.left; 606 rect.bottom = h + rect.top; 607 608 return; 609 } 610 611 // This function gets the destination position for Seconday display 612 // based on the position and aspect ratio with orientation 613 void getAspectRatioPosition(hwc_context_t* ctx, int dpy, int extOrientation, 614 hwc_rect_t& inRect, hwc_rect_t& outRect) { 615 // Physical display resolution 616 float fbWidth = (float)ctx->dpyAttr[dpy].xres; 617 float fbHeight = (float)ctx->dpyAttr[dpy].yres; 618 //display position(x,y,w,h) in correct aspectratio after rotation 619 int xPos = 0; 620 int yPos = 0; 621 float width = fbWidth; 622 float height = fbHeight; 623 // Width/Height used for calculation, after rotation 624 float actualWidth = fbWidth; 625 float actualHeight = fbHeight; 626 627 float wRatio = 1.0; 628 float hRatio = 1.0; 629 float xRatio = 1.0; 630 float yRatio = 1.0; 631 hwc_rect_t rect = {0, 0, (int)fbWidth, (int)fbHeight}; 632 633 Dim inPos(inRect.left, inRect.top, inRect.right - inRect.left, 634 inRect.bottom - inRect.top); 635 Dim outPos(outRect.left, outRect.top, outRect.right - outRect.left, 636 outRect.bottom - outRect.top); 637 638 Whf whf((uint32_t)fbWidth, (uint32_t)fbHeight, 0); 639 eTransform extorient = static_cast<eTransform>(extOrientation); 640 // To calculate the destination co-ordinates in the new orientation 641 preRotateSource(extorient, whf, inPos); 642 643 if(extOrientation & HAL_TRANSFORM_ROT_90) { 644 // Swap width/height for input position 645 swapWidthHeight(actualWidth, actualHeight); 646 qdutils::getAspectRatioPosition((int)fbWidth, (int)fbHeight, 647 (int)actualWidth, (int)actualHeight, rect); 648 xPos = rect.left; 649 yPos = rect.top; 650 width = float(rect.right - rect.left); 651 height = float(rect.bottom - rect.top); 652 } 653 xRatio = (float)((float)inPos.x/actualWidth); 654 yRatio = (float)((float)inPos.y/actualHeight); 655 wRatio = (float)((float)inPos.w/actualWidth); 656 hRatio = (float)((float)inPos.h/actualHeight); 657 658 //Calculate the pos9ition... 659 outPos.x = uint32_t((xRatio * width) + (float)xPos); 660 outPos.y = uint32_t((yRatio * height) + (float)yPos); 661 outPos.w = uint32_t(wRatio * width); 662 outPos.h = uint32_t(hRatio * height); 663 ALOGD_IF(HWC_UTILS_DEBUG, "%s: Calculated AspectRatio Position: x = %d," 664 "y = %d w = %d h = %d", __FUNCTION__, outPos.x, outPos.y, 665 outPos.w, outPos.h); 666 667 // For sidesync, the dest fb will be in portrait orientation, and the crop 668 // will be updated to avoid the black side bands, and it will be upscaled 669 // to fit the dest RB, so recalculate 670 // the position based on the new width and height 671 if ((extOrientation & HWC_TRANSFORM_ROT_90) && 672 isOrientationPortrait(ctx)) { 673 hwc_rect_t r = {0, 0, 0, 0}; 674 //Calculate the position 675 xRatio = (float)(outPos.x - xPos)/width; 676 // GetaspectRatio -- tricky to get the correct aspect ratio 677 // But we need to do this. 678 qdutils::getAspectRatioPosition((int)width, (int)height, 679 (int)width,(int)height, r); 680 xPos = r.left; 681 yPos = r.top; 682 float tempHeight = float(r.bottom - r.top); 683 yRatio = (float)yPos/height; 684 wRatio = (float)outPos.w/width; 685 hRatio = tempHeight/height; 686 687 //Map the coordinates back to Framebuffer domain 688 outPos.x = uint32_t(xRatio * fbWidth); 689 outPos.y = uint32_t(yRatio * fbHeight); 690 outPos.w = uint32_t(wRatio * fbWidth); 691 outPos.h = uint32_t(hRatio * fbHeight); 692 693 ALOGD_IF(HWC_UTILS_DEBUG, "%s: Calculated AspectRatio for device in" 694 "portrait: x = %d,y = %d w = %d h = %d", __FUNCTION__, 695 outPos.x, outPos.y, 696 outPos.w, outPos.h); 697 } 698 if(ctx->dpyAttr[dpy].mMDPScalingMode) { 699 uint32_t extW = 0, extH = 0; 700 if(dpy == HWC_DISPLAY_EXTERNAL) { 701 ctx->mHDMIDisplay->getAttributes(extW, extH); 702 } else if(dpy == HWC_DISPLAY_VIRTUAL) { 703 extW = ctx->mHWCVirtual->getScalingWidth(); 704 extH = ctx->mHWCVirtual->getScalingHeight(); 705 } 706 ALOGD_IF(HWC_UTILS_DEBUG, "%s: Scaling mode extW=%d extH=%d", 707 __FUNCTION__, extW, extH); 708 709 fbWidth = (float)ctx->dpyAttr[dpy].xres; 710 fbHeight = (float)ctx->dpyAttr[dpy].yres; 711 //Calculate the position... 712 xRatio = (float)outPos.x/fbWidth; 713 yRatio = (float)outPos.y/fbHeight; 714 wRatio = (float)outPos.w/fbWidth; 715 hRatio = (float)outPos.h/fbHeight; 716 717 outPos.x = uint32_t(xRatio * (float)extW); 718 outPos.y = uint32_t(yRatio * (float)extH); 719 outPos.w = uint32_t(wRatio * (float)extW); 720 outPos.h = uint32_t(hRatio * (float)extH); 721 } 722 // Convert Dim to hwc_rect_t 723 outRect.left = outPos.x; 724 outRect.top = outPos.y; 725 outRect.right = outPos.x + outPos.w; 726 outRect.bottom = outPos.y + outPos.h; 727 728 return; 729 } 730 731 bool isPrimaryPortrait(hwc_context_t *ctx) { 732 int fbWidth = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres; 733 int fbHeight = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres; 734 if(fbWidth < fbHeight) { 735 return true; 736 } 737 return false; 738 } 739 740 bool isOrientationPortrait(hwc_context_t *ctx) { 741 if(isPrimaryPortrait(ctx)) { 742 return !(ctx->deviceOrientation & 0x1); 743 } 744 return (ctx->deviceOrientation & 0x1); 745 } 746 747 void calcExtDisplayPosition(hwc_context_t *ctx, 748 private_handle_t *hnd, 749 int dpy, 750 hwc_rect_t& sourceCrop, 751 hwc_rect_t& displayFrame, 752 int& transform, 753 ovutils::eTransform& orient) { 754 // Swap width and height when there is a 90deg transform 755 int extOrient = getExtOrientation(ctx); 756 if(dpy && ctx->mOverlay->isUIScalingOnExternalSupported()) { 757 if(!isYuvBuffer(hnd)) { 758 if(extOrient & HWC_TRANSFORM_ROT_90) { 759 int dstWidth = ctx->dpyAttr[dpy].xres; 760 int dstHeight = ctx->dpyAttr[dpy].yres;; 761 int srcWidth = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].xres; 762 int srcHeight = ctx->dpyAttr[HWC_DISPLAY_PRIMARY].yres; 763 if(!isPrimaryPortrait(ctx)) { 764 swap(srcWidth, srcHeight); 765 } // Get Aspect Ratio for external 766 qdutils::getAspectRatioPosition(dstWidth, dstHeight, srcWidth, 767 srcHeight, displayFrame); 768 // Crop - this is needed, because for sidesync, the dest fb will 769 // be in portrait orientation, so update the crop to not show the 770 // black side bands. 771 if (isOrientationPortrait(ctx)) { 772 sourceCrop = displayFrame; 773 displayFrame.left = 0; 774 displayFrame.top = 0; 775 displayFrame.right = dstWidth; 776 displayFrame.bottom = dstHeight; 777 } 778 } 779 if(ctx->dpyAttr[dpy].mMDPScalingMode) { 780 uint32_t extW = 0, extH = 0; 781 // if MDP scaling mode is enabled, map the co-ordinates to new 782 // domain(downscaled) 783 float fbWidth = (float)ctx->dpyAttr[dpy].xres; 784 float fbHeight = (float)ctx->dpyAttr[dpy].yres; 785 // query MDP configured attributes 786 if(dpy == HWC_DISPLAY_EXTERNAL) { 787 ctx->mHDMIDisplay->getAttributes(extW, extH); 788 } else if(dpy == HWC_DISPLAY_VIRTUAL) { 789 extW = ctx->mHWCVirtual->getScalingWidth(); 790 extH = ctx->mHWCVirtual->getScalingHeight(); 791 } 792 ALOGD_IF(HWC_UTILS_DEBUG, "%s: Scaling mode extW=%d extH=%d", 793 __FUNCTION__, extW, extH); 794 795 //Calculate the ratio... 796 float wRatio = ((float)extW)/fbWidth; 797 float hRatio = ((float)extH)/fbHeight; 798 799 //convert Dim to hwc_rect_t 800 displayFrame.left = int(wRatio*(float)displayFrame.left); 801 displayFrame.top = int(hRatio*(float)displayFrame.top); 802 displayFrame.right = int(wRatio*(float)displayFrame.right); 803 displayFrame.bottom = int(hRatio*(float)displayFrame.bottom); 804 ALOGD_IF(DEBUG_MDPDOWNSCALE, "Calculated external display frame" 805 " for MDPDownscale feature [%d %d %d %d]", 806 displayFrame.left, displayFrame.top, 807 displayFrame.right, displayFrame.bottom); 808 } 809 }else { 810 if(extOrient || ctx->dpyAttr[dpy].mMDPScalingMode) { 811 getAspectRatioPosition(ctx, dpy, extOrient, 812 displayFrame, displayFrame); 813 } 814 } 815 // If there is a external orientation set, use that 816 if(extOrient) { 817 transform = extOrient; 818 orient = static_cast<ovutils::eTransform >(extOrient); 819 } 820 // Calculate the actionsafe dimensions for External(dpy = 1 or 2) 821 getActionSafePosition(ctx, dpy, displayFrame); 822 } 823 } 824 825 /* Returns the orientation which needs to be set on External for 826 * SideSync/Buffer Mirrormode 827 */ 828 int getMirrorModeOrientation(hwc_context_t *ctx) { 829 int extOrientation = 0; 830 int deviceOrientation = ctx->deviceOrientation; 831 if(!isPrimaryPortrait(ctx)) 832 deviceOrientation = (deviceOrientation + 1) % 4; 833 if (deviceOrientation == 0) 834 extOrientation = HWC_TRANSFORM_ROT_270; 835 else if (deviceOrientation == 1)//90 836 extOrientation = 0; 837 else if (deviceOrientation == 2)//180 838 extOrientation = HWC_TRANSFORM_ROT_90; 839 else if (deviceOrientation == 3)//270 840 extOrientation = HWC_TRANSFORM_FLIP_V | HWC_TRANSFORM_FLIP_H; 841 842 return extOrientation; 843 } 844 845 /* Get External State names */ 846 const char* getExternalDisplayState(uint32_t external_state) { 847 static const char* externalStates[EXTERNAL_MAXSTATES] = {0}; 848 externalStates[EXTERNAL_OFFLINE] = STR(EXTERNAL_OFFLINE); 849 externalStates[EXTERNAL_ONLINE] = STR(EXTERNAL_ONLINE); 850 externalStates[EXTERNAL_PAUSE] = STR(EXTERNAL_PAUSE); 851 externalStates[EXTERNAL_RESUME] = STR(EXTERNAL_RESUME); 852 853 if(external_state >= EXTERNAL_MAXSTATES) { 854 return "EXTERNAL_INVALID"; 855 } 856 857 return externalStates[external_state]; 858 } 859 860 bool isDownscaleRequired(hwc_layer_1_t const* layer) { 861 hwc_rect_t displayFrame = layer->displayFrame; 862 hwc_rect_t sourceCrop = integerizeSourceCrop(layer->sourceCropf); 863 int dst_w, dst_h, src_w, src_h; 864 dst_w = displayFrame.right - displayFrame.left; 865 dst_h = displayFrame.bottom - displayFrame.top; 866 src_w = sourceCrop.right - sourceCrop.left; 867 src_h = sourceCrop.bottom - sourceCrop.top; 868 869 if(((src_w > dst_w) || (src_h > dst_h))) 870 return true; 871 872 return false; 873 } 874 bool needsScaling(hwc_layer_1_t const* layer) { 875 int dst_w, dst_h, src_w, src_h; 876 hwc_rect_t displayFrame = layer->displayFrame; 877 hwc_rect_t sourceCrop = integerizeSourceCrop(layer->sourceCropf); 878 879 dst_w = displayFrame.right - displayFrame.left; 880 dst_h = displayFrame.bottom - displayFrame.top; 881 src_w = sourceCrop.right - sourceCrop.left; 882 src_h = sourceCrop.bottom - sourceCrop.top; 883 884 if(layer->transform & HWC_TRANSFORM_ROT_90) 885 swap(src_w, src_h); 886 887 if(((src_w != dst_w) || (src_h != dst_h))) 888 return true; 889 890 return false; 891 } 892 893 // Checks if layer needs scaling with split 894 bool needsScalingWithSplit(hwc_context_t* ctx, hwc_layer_1_t const* layer, 895 const int& dpy) { 896 897 int src_width_l, src_height_l; 898 int src_width_r, src_height_r; 899 int dst_width_l, dst_height_l; 900 int dst_width_r, dst_height_r; 901 int hw_w = ctx->dpyAttr[dpy].xres; 902 int hw_h = ctx->dpyAttr[dpy].yres; 903 hwc_rect_t cropL, dstL, cropR, dstR; 904 const int lSplit = getLeftSplit(ctx, dpy); 905 hwc_rect_t sourceCrop = integerizeSourceCrop(layer->sourceCropf); 906 hwc_rect_t displayFrame = layer->displayFrame; 907 private_handle_t *hnd = (private_handle_t *)layer->handle; 908 909 cropL = sourceCrop; 910 dstL = displayFrame; 911 hwc_rect_t scissorL = { 0, 0, lSplit, hw_h }; 912 scissorL = getIntersection(ctx->mViewFrame[dpy], scissorL); 913 qhwc::calculate_crop_rects(cropL, dstL, scissorL, 0); 914 915 cropR = sourceCrop; 916 dstR = displayFrame; 917 hwc_rect_t scissorR = { lSplit, 0, hw_w, hw_h }; 918 scissorR = getIntersection(ctx->mViewFrame[dpy], scissorR); 919 qhwc::calculate_crop_rects(cropR, dstR, scissorR, 0); 920 921 // Sanitize Crop to stitch 922 sanitizeSourceCrop(cropL, cropR, hnd); 923 924 // Calculate the left dst 925 dst_width_l = dstL.right - dstL.left; 926 dst_height_l = dstL.bottom - dstL.top; 927 src_width_l = cropL.right - cropL.left; 928 src_height_l = cropL.bottom - cropL.top; 929 930 // check if there is any scaling on the left 931 if(((src_width_l != dst_width_l) || (src_height_l != dst_height_l))) 932 return true; 933 934 // Calculate the right dst 935 dst_width_r = dstR.right - dstR.left; 936 dst_height_r = dstR.bottom - dstR.top; 937 src_width_r = cropR.right - cropR.left; 938 src_height_r = cropR.bottom - cropR.top; 939 940 // check if there is any scaling on the right 941 if(((src_width_r != dst_width_r) || (src_height_r != dst_height_r))) 942 return true; 943 944 return false; 945 } 946 947 bool isAlphaScaled(hwc_layer_1_t const* layer) { 948 if(needsScaling(layer) && isAlphaPresent(layer)) { 949 return true; 950 } 951 return false; 952 } 953 954 bool isAlphaPresent(hwc_layer_1_t const* layer) { 955 private_handle_t *hnd = (private_handle_t *)layer->handle; 956 if(hnd) { 957 int format = hnd->format; 958 switch(format) { 959 case HAL_PIXEL_FORMAT_RGBA_8888: 960 case HAL_PIXEL_FORMAT_BGRA_8888: 961 // In any more formats with Alpha go here.. 962 return true; 963 default : return false; 964 } 965 } 966 return false; 967 } 968 969 static void trimLayer(hwc_context_t *ctx, const int& dpy, const int& transform, 970 hwc_rect_t& crop, hwc_rect_t& dst) { 971 int hw_w = ctx->dpyAttr[dpy].xres; 972 int hw_h = ctx->dpyAttr[dpy].yres; 973 if(dst.left < 0 || dst.top < 0 || 974 dst.right > hw_w || dst.bottom > hw_h) { 975 hwc_rect_t scissor = {0, 0, hw_w, hw_h }; 976 scissor = getIntersection(ctx->mViewFrame[dpy], scissor); 977 qhwc::calculate_crop_rects(crop, dst, scissor, transform); 978 } 979 } 980 981 static void trimList(hwc_context_t *ctx, hwc_display_contents_1_t *list, 982 const int& dpy) { 983 for(uint32_t i = 0; i < list->numHwLayers - 1; i++) { 984 hwc_layer_1_t *layer = &list->hwLayers[i]; 985 hwc_rect_t crop = integerizeSourceCrop(layer->sourceCropf); 986 int transform = (list->hwLayers[i].flags & HWC_COLOR_FILL) ? 0 : 987 list->hwLayers[i].transform; 988 trimLayer(ctx, dpy, 989 transform, 990 (hwc_rect_t&)crop, 991 (hwc_rect_t&)list->hwLayers[i].displayFrame); 992 layer->sourceCropf.left = (float)crop.left; 993 layer->sourceCropf.right = (float)crop.right; 994 layer->sourceCropf.top = (float)crop.top; 995 layer->sourceCropf.bottom = (float)crop.bottom; 996 } 997 } 998 999 void setListStats(hwc_context_t *ctx, 1000 hwc_display_contents_1_t *list, int dpy) { 1001 const int prevYuvCount = ctx->listStats[dpy].yuvCount; 1002 memset(&ctx->listStats[dpy], 0, sizeof(ListStats)); 1003 ctx->listStats[dpy].numAppLayers = (int)list->numHwLayers - 1; 1004 ctx->listStats[dpy].fbLayerIndex = (int)list->numHwLayers - 1; 1005 ctx->listStats[dpy].skipCount = 0; 1006 ctx->listStats[dpy].preMultipliedAlpha = false; 1007 ctx->listStats[dpy].isSecurePresent = false; 1008 ctx->listStats[dpy].yuvCount = 0; 1009 char property[PROPERTY_VALUE_MAX]; 1010 ctx->listStats[dpy].isDisplayAnimating = false; 1011 ctx->listStats[dpy].secureUI = false; 1012 ctx->listStats[dpy].yuv4k2kCount = 0; 1013 ctx->dpyAttr[dpy].mActionSafePresent = isActionSafePresent(ctx, dpy); 1014 ctx->listStats[dpy].renderBufIndexforABC = -1; 1015 ctx->listStats[dpy].secureRGBCount = 0; 1016 ctx->listStats[dpy].refreshRateRequest = ctx->dpyAttr[dpy].refreshRate; 1017 uint32_t refreshRate = 0; 1018 qdutils::MDPVersion& mdpHw = qdutils::MDPVersion::getInstance(); 1019 1020 ctx->listStats[dpy].mAIVVideoMode = false; 1021 resetROI(ctx, dpy); 1022 1023 trimList(ctx, list, dpy); 1024 optimizeLayerRects(list); 1025 for (size_t i = 0; i < (size_t)ctx->listStats[dpy].numAppLayers; i++) { 1026 hwc_layer_1_t const* layer = &list->hwLayers[i]; 1027 private_handle_t *hnd = (private_handle_t *)layer->handle; 1028 1029 #ifdef QCOM_BSP 1030 // Window boxing feature is applicable obly for external display, So 1031 // enable mAIVVideoMode only for external display 1032 if(ctx->mWindowboxFeature && dpy && isAIVVideoLayer(layer)) { 1033 ctx->listStats[dpy].mAIVVideoMode = true; 1034 } 1035 if (layer->flags & HWC_SCREENSHOT_ANIMATOR_LAYER) { 1036 ctx->listStats[dpy].isDisplayAnimating = true; 1037 } 1038 if(isSecureDisplayBuffer(hnd)) { 1039 ctx->listStats[dpy].secureUI = true; 1040 } 1041 #endif 1042 // continue if number of app layers exceeds MAX_NUM_APP_LAYERS 1043 if(ctx->listStats[dpy].numAppLayers > MAX_NUM_APP_LAYERS) 1044 continue; 1045 1046 //reset yuv indices 1047 ctx->listStats[dpy].yuvIndices[i] = -1; 1048 ctx->listStats[dpy].yuv4k2kIndices[i] = -1; 1049 1050 if (isSecureBuffer(hnd)) { 1051 ctx->listStats[dpy].isSecurePresent = true; 1052 if(not isYuvBuffer(hnd)) { 1053 // cache secureRGB layer parameters like we cache for YUV layers 1054 int& secureRGBCount = ctx->listStats[dpy].secureRGBCount; 1055 ctx->listStats[dpy].secureRGBIndices[secureRGBCount] = (int)i; 1056 secureRGBCount++; 1057 } 1058 } 1059 1060 if (isSkipLayer(&list->hwLayers[i])) { 1061 ctx->listStats[dpy].skipCount++; 1062 } 1063 1064 if (UNLIKELY(isYuvBuffer(hnd))) { 1065 int& yuvCount = ctx->listStats[dpy].yuvCount; 1066 ctx->listStats[dpy].yuvIndices[yuvCount] = (int)i; 1067 yuvCount++; 1068 1069 if(UNLIKELY(isYUVSplitNeeded(hnd))){ 1070 int& yuv4k2kCount = ctx->listStats[dpy].yuv4k2kCount; 1071 ctx->listStats[dpy].yuv4k2kIndices[yuv4k2kCount] = (int)i; 1072 yuv4k2kCount++; 1073 } 1074 } 1075 if(layer->blending == HWC_BLENDING_PREMULT) 1076 ctx->listStats[dpy].preMultipliedAlpha = true; 1077 1078 #ifdef DYNAMIC_FPS 1079 if (!dpy && mdpHw.isDynFpsSupported() && ctx->mUseMetaDataRefreshRate){ 1080 //dyn fps: get refreshrate from metadata 1081 //Support multiple refresh rates if they are same 1082 //else set to default 1083 MetaData_t *mdata = hnd ? (MetaData_t *)hnd->base_metadata : NULL; 1084 if (mdata && (mdata->operation & UPDATE_REFRESH_RATE)) { 1085 // Valid refreshRate in metadata and within the range 1086 uint32_t rate = roundOff(mdata->refreshrate); 1087 if((rate >= mdpHw.getMinFpsSupported() && 1088 rate <= mdpHw.getMaxFpsSupported())) { 1089 if (!refreshRate) { 1090 refreshRate = rate; 1091 } else if(refreshRate != rate) { 1092 // multiple refreshrate requests, set to default 1093 refreshRate = ctx->dpyAttr[dpy].refreshRate; 1094 } 1095 } 1096 } 1097 } 1098 #endif 1099 } 1100 if(ctx->listStats[dpy].yuvCount > 0) { 1101 if (property_get("hw.cabl.yuv", property, NULL) > 0) { 1102 if (atoi(property) != 1) { 1103 property_set("hw.cabl.yuv", "1"); 1104 } 1105 } 1106 } else { 1107 if (property_get("hw.cabl.yuv", property, NULL) > 0) { 1108 if (atoi(property) != 0) { 1109 property_set("hw.cabl.yuv", "0"); 1110 } 1111 } 1112 } 1113 1114 //The marking of video begin/end is useful on some targets where we need 1115 //to have a padding round to be able to shift pipes across mixers. 1116 if(prevYuvCount != ctx->listStats[dpy].yuvCount) { 1117 ctx->mVideoTransFlag = true; 1118 } 1119 1120 if(dpy == HWC_DISPLAY_PRIMARY) { 1121 ctx->mAD->markDoable(ctx, list); 1122 //Store the requested fresh rate 1123 ctx->listStats[dpy].refreshRateRequest = refreshRate ? 1124 refreshRate : ctx->dpyAttr[dpy].refreshRate; 1125 } 1126 } 1127 1128 1129 static void calc_cut(double& leftCutRatio, double& topCutRatio, 1130 double& rightCutRatio, double& bottomCutRatio, int orient) { 1131 if(orient & HAL_TRANSFORM_FLIP_H) { 1132 swap(leftCutRatio, rightCutRatio); 1133 } 1134 if(orient & HAL_TRANSFORM_FLIP_V) { 1135 swap(topCutRatio, bottomCutRatio); 1136 } 1137 if(orient & HAL_TRANSFORM_ROT_90) { 1138 //Anti clock swapping 1139 double tmpCutRatio = leftCutRatio; 1140 leftCutRatio = topCutRatio; 1141 topCutRatio = rightCutRatio; 1142 rightCutRatio = bottomCutRatio; 1143 bottomCutRatio = tmpCutRatio; 1144 } 1145 } 1146 1147 bool isSecuring(hwc_context_t* ctx, hwc_layer_1_t const* layer) { 1148 if((ctx->mMDP.version < qdutils::MDSS_V5) && 1149 (ctx->mMDP.version > qdutils::MDP_V3_0) && 1150 ctx->mSecuring) { 1151 return true; 1152 } 1153 if (isSecureModePolicy(ctx->mMDP.version)) { 1154 private_handle_t *hnd = (private_handle_t *)layer->handle; 1155 if(ctx->mSecureMode) { 1156 if (! isSecureBuffer(hnd)) { 1157 ALOGD_IF(HWC_UTILS_DEBUG,"%s:Securing Turning ON ...", 1158 __FUNCTION__); 1159 return true; 1160 } 1161 } else { 1162 if (isSecureBuffer(hnd)) { 1163 ALOGD_IF(HWC_UTILS_DEBUG,"%s:Securing Turning OFF ...", 1164 __FUNCTION__); 1165 return true; 1166 } 1167 } 1168 } 1169 return false; 1170 } 1171 1172 bool isSecureModePolicy(int mdpVersion) { 1173 if (mdpVersion < qdutils::MDSS_V5) 1174 return true; 1175 else 1176 return false; 1177 } 1178 1179 bool isRotatorSupportedFormat(private_handle_t *hnd) { 1180 // Following rotator src formats are supported by mdp driver 1181 // TODO: Add more formats in future, if mdp driver adds support 1182 if(hnd != NULL) { 1183 switch(hnd->format) { 1184 case HAL_PIXEL_FORMAT_RGBA_8888: 1185 case HAL_PIXEL_FORMAT_RGBA_5551: 1186 case HAL_PIXEL_FORMAT_RGBA_4444: 1187 case HAL_PIXEL_FORMAT_RGB_565: 1188 case HAL_PIXEL_FORMAT_RGB_888: 1189 case HAL_PIXEL_FORMAT_BGRA_8888: 1190 return true; 1191 default: 1192 return false; 1193 } 1194 } 1195 return false; 1196 } 1197 1198 bool isRotationDoable(hwc_context_t *ctx, private_handle_t *hnd) { 1199 // Rotate layers, if it is not secure display buffer and not 1200 // for the MDP versions below MDP5 1201 if((!isSecureDisplayBuffer(hnd) && isRotatorSupportedFormat(hnd) && 1202 !ctx->mMDP.version < qdutils::MDSS_V5) 1203 || isYuvBuffer(hnd)) { 1204 return true; 1205 } 1206 return false; 1207 } 1208 1209 // returns true if Action safe dimensions are set and target supports Actionsafe 1210 bool isActionSafePresent(hwc_context_t *ctx, int dpy) { 1211 // if external supports underscan, do nothing 1212 // it will be taken care in the driver 1213 // Disable Action safe for 8974 due to HW limitation for downscaling 1214 // layers with overlapped region 1215 // Disable Actionsafe for non HDMI displays. 1216 if(!(dpy == HWC_DISPLAY_EXTERNAL) || 1217 qdutils::MDPVersion::getInstance().is8x74v2() || 1218 ctx->mHDMIDisplay->isCEUnderscanSupported()) { 1219 return false; 1220 } 1221 1222 char value[PROPERTY_VALUE_MAX]; 1223 // Read action safe properties 1224 property_get("persist.sys.actionsafe.width", value, "0"); 1225 ctx->dpyAttr[dpy].mAsWidthRatio = atoi(value); 1226 property_get("persist.sys.actionsafe.height", value, "0"); 1227 ctx->dpyAttr[dpy].mAsHeightRatio = atoi(value); 1228 1229 if(!ctx->dpyAttr[dpy].mAsWidthRatio && !ctx->dpyAttr[dpy].mAsHeightRatio) { 1230 //No action safe ratio set, return 1231 return false; 1232 } 1233 return true; 1234 } 1235 1236 int getBlending(int blending) { 1237 switch(blending) { 1238 case HWC_BLENDING_NONE: 1239 return overlay::utils::OVERLAY_BLENDING_OPAQUE; 1240 case HWC_BLENDING_PREMULT: 1241 return overlay::utils::OVERLAY_BLENDING_PREMULT; 1242 case HWC_BLENDING_COVERAGE : 1243 default: 1244 return overlay::utils::OVERLAY_BLENDING_COVERAGE; 1245 } 1246 } 1247 1248 //Crops source buffer against destination and FB boundaries 1249 void calculate_crop_rects(hwc_rect_t& crop, hwc_rect_t& dst, 1250 const hwc_rect_t& scissor, int orient) { 1251 1252 int& crop_l = crop.left; 1253 int& crop_t = crop.top; 1254 int& crop_r = crop.right; 1255 int& crop_b = crop.bottom; 1256 int crop_w = crop.right - crop.left; 1257 int crop_h = crop.bottom - crop.top; 1258 1259 int& dst_l = dst.left; 1260 int& dst_t = dst.top; 1261 int& dst_r = dst.right; 1262 int& dst_b = dst.bottom; 1263 int dst_w = abs(dst.right - dst.left); 1264 int dst_h = abs(dst.bottom - dst.top); 1265 1266 const int& sci_l = scissor.left; 1267 const int& sci_t = scissor.top; 1268 const int& sci_r = scissor.right; 1269 const int& sci_b = scissor.bottom; 1270 1271 double leftCutRatio = 0.0, rightCutRatio = 0.0, topCutRatio = 0.0, 1272 bottomCutRatio = 0.0; 1273 1274 if(dst_l < sci_l) { 1275 leftCutRatio = (double)(sci_l - dst_l) / (double)dst_w; 1276 dst_l = sci_l; 1277 } 1278 1279 if(dst_r > sci_r) { 1280 rightCutRatio = (double)(dst_r - sci_r) / (double)dst_w; 1281 dst_r = sci_r; 1282 } 1283 1284 if(dst_t < sci_t) { 1285 topCutRatio = (double)(sci_t - dst_t) / (double)dst_h; 1286 dst_t = sci_t; 1287 } 1288 1289 if(dst_b > sci_b) { 1290 bottomCutRatio = (double)(dst_b - sci_b) / (double)dst_h; 1291 dst_b = sci_b; 1292 } 1293 1294 calc_cut(leftCutRatio, topCutRatio, rightCutRatio, bottomCutRatio, orient); 1295 crop_l += (int)round((double)crop_w * leftCutRatio); 1296 crop_t += (int)round((double)crop_h * topCutRatio); 1297 crop_r -= (int)round((double)crop_w * rightCutRatio); 1298 crop_b -= (int)round((double)crop_h * bottomCutRatio); 1299 } 1300 1301 bool areLayersIntersecting(const hwc_layer_1_t* layer1, 1302 const hwc_layer_1_t* layer2) { 1303 hwc_rect_t irect = getIntersection(layer1->displayFrame, 1304 layer2->displayFrame); 1305 return isValidRect(irect); 1306 } 1307 1308 bool isSameRect(const hwc_rect& rect1, const hwc_rect& rect2) 1309 { 1310 return ((rect1.left == rect2.left) && (rect1.top == rect2.top) && 1311 (rect1.right == rect2.right) && (rect1.bottom == rect2.bottom)); 1312 } 1313 1314 bool isValidRect(const hwc_rect& rect) 1315 { 1316 return ((rect.bottom > rect.top) && (rect.right > rect.left)) ; 1317 } 1318 1319 bool operator ==(const hwc_rect_t& lhs, const hwc_rect_t& rhs) { 1320 if(lhs.left == rhs.left && lhs.top == rhs.top && 1321 lhs.right == rhs.right && lhs.bottom == rhs.bottom ) 1322 return true ; 1323 return false; 1324 } 1325 1326 bool layerUpdating(const hwc_layer_1_t* layer) { 1327 hwc_region_t surfDamage = layer->surfaceDamage; 1328 return ((surfDamage.numRects == 0) || 1329 isValidRect(layer->surfaceDamage.rects[0])); 1330 } 1331 1332 hwc_rect_t moveRect(const hwc_rect_t& rect, const int& x_off, const int& y_off) 1333 { 1334 hwc_rect_t res; 1335 1336 if(!isValidRect(rect)) 1337 return (hwc_rect_t){0, 0, 0, 0}; 1338 1339 res.left = rect.left + x_off; 1340 res.top = rect.top + y_off; 1341 res.right = rect.right + x_off; 1342 res.bottom = rect.bottom + y_off; 1343 1344 return res; 1345 } 1346 1347 /* computes the intersection of two rects */ 1348 hwc_rect_t getIntersection(const hwc_rect_t& rect1, const hwc_rect_t& rect2) 1349 { 1350 hwc_rect_t res; 1351 1352 if(!isValidRect(rect1) || !isValidRect(rect2)){ 1353 return (hwc_rect_t){0, 0, 0, 0}; 1354 } 1355 1356 1357 res.left = max(rect1.left, rect2.left); 1358 res.top = max(rect1.top, rect2.top); 1359 res.right = min(rect1.right, rect2.right); 1360 res.bottom = min(rect1.bottom, rect2.bottom); 1361 1362 if(!isValidRect(res)) 1363 return (hwc_rect_t){0, 0, 0, 0}; 1364 1365 return res; 1366 } 1367 1368 /* computes the union of two rects */ 1369 hwc_rect_t getUnion(const hwc_rect &rect1, const hwc_rect &rect2) 1370 { 1371 hwc_rect_t res; 1372 1373 if(!isValidRect(rect1)){ 1374 return rect2; 1375 } 1376 1377 if(!isValidRect(rect2)){ 1378 return rect1; 1379 } 1380 1381 res.left = min(rect1.left, rect2.left); 1382 res.top = min(rect1.top, rect2.top); 1383 res.right = max(rect1.right, rect2.right); 1384 res.bottom = max(rect1.bottom, rect2.bottom); 1385 1386 return res; 1387 } 1388 1389 /* Not a geometrical rect deduction. Deducts rect2 from rect1 only if it results 1390 * a single rect */ 1391 hwc_rect_t deductRect(const hwc_rect_t& rect1, const hwc_rect_t& rect2) { 1392 1393 hwc_rect_t res = rect1; 1394 1395 if((rect1.left == rect2.left) && (rect1.right == rect2.right)) { 1396 if((rect1.top == rect2.top) && (rect2.bottom <= rect1.bottom)) 1397 res.top = rect2.bottom; 1398 else if((rect1.bottom == rect2.bottom)&& (rect2.top >= rect1.top)) 1399 res.bottom = rect2.top; 1400 } 1401 else if((rect1.top == rect2.top) && (rect1.bottom == rect2.bottom)) { 1402 if((rect1.left == rect2.left) && (rect2.right <= rect1.right)) 1403 res.left = rect2.right; 1404 else if((rect1.right == rect2.right)&& (rect2.left >= rect1.left)) 1405 res.right = rect2.left; 1406 } 1407 return res; 1408 } 1409 1410 void optimizeLayerRects(const hwc_display_contents_1_t *list) { 1411 int i= (int)list->numHwLayers-2; 1412 while(i > 0) { 1413 //see if there is no blending required. 1414 //If it is opaque see if we can substract this region from below 1415 //layers. 1416 if(list->hwLayers[i].blending == HWC_BLENDING_NONE && 1417 list->hwLayers[i].planeAlpha == 0xFF) { 1418 int j= i-1; 1419 hwc_rect_t& topframe = 1420 (hwc_rect_t&)list->hwLayers[i].displayFrame; 1421 while(j >= 0) { 1422 if(!needsScaling(&list->hwLayers[j])) { 1423 hwc_layer_1_t* layer = (hwc_layer_1_t*)&list->hwLayers[j]; 1424 hwc_rect_t& bottomframe = layer->displayFrame; 1425 hwc_rect_t bottomCrop = 1426 integerizeSourceCrop(layer->sourceCropf); 1427 int transform = (layer->flags & HWC_COLOR_FILL) ? 0 : 1428 layer->transform; 1429 1430 hwc_rect_t irect = getIntersection(bottomframe, topframe); 1431 if(isValidRect(irect)) { 1432 hwc_rect_t dest_rect; 1433 //if intersection is valid rect, deduct it 1434 dest_rect = deductRect(bottomframe, irect); 1435 qhwc::calculate_crop_rects(bottomCrop, bottomframe, 1436 dest_rect, transform); 1437 //Update layer sourceCropf 1438 layer->sourceCropf.left =(float)bottomCrop.left; 1439 layer->sourceCropf.top = (float)bottomCrop.top; 1440 layer->sourceCropf.right = (float)bottomCrop.right; 1441 layer->sourceCropf.bottom = (float)bottomCrop.bottom; 1442 #ifdef QCOM_BSP 1443 //Update layer dirtyRect 1444 layer->dirtyRect = getIntersection(bottomCrop, 1445 layer->dirtyRect); 1446 #endif 1447 } 1448 } 1449 j--; 1450 } 1451 } 1452 i--; 1453 } 1454 } 1455 1456 void getNonWormholeRegion(hwc_display_contents_1_t* list, 1457 hwc_rect_t& nwr) 1458 { 1459 size_t last = list->numHwLayers - 1; 1460 hwc_rect_t fbDisplayFrame = list->hwLayers[last].displayFrame; 1461 //Initiliaze nwr to first frame 1462 nwr.left = list->hwLayers[0].displayFrame.left; 1463 nwr.top = list->hwLayers[0].displayFrame.top; 1464 nwr.right = list->hwLayers[0].displayFrame.right; 1465 nwr.bottom = list->hwLayers[0].displayFrame.bottom; 1466 1467 for (size_t i = 1; i < last; i++) { 1468 hwc_rect_t displayFrame = list->hwLayers[i].displayFrame; 1469 nwr = getUnion(nwr, displayFrame); 1470 } 1471 1472 //Intersect with the framebuffer 1473 nwr = getIntersection(nwr, fbDisplayFrame); 1474 } 1475 1476 bool isExternalActive(hwc_context_t* ctx) { 1477 return ctx->dpyAttr[HWC_DISPLAY_EXTERNAL].isActive; 1478 } 1479 1480 void closeAcquireFds(hwc_display_contents_1_t* list) { 1481 if(LIKELY(list)) { 1482 for(uint32_t i = 0; i < list->numHwLayers; i++) { 1483 //Close the acquireFenceFds 1484 //HWC_FRAMEBUFFER are -1 already by SF, rest we close. 1485 if(list->hwLayers[i].acquireFenceFd >= 0) { 1486 close(list->hwLayers[i].acquireFenceFd); 1487 list->hwLayers[i].acquireFenceFd = -1; 1488 } 1489 } 1490 //Writeback 1491 if(list->outbufAcquireFenceFd >= 0) { 1492 close(list->outbufAcquireFenceFd); 1493 list->outbufAcquireFenceFd = -1; 1494 } 1495 } 1496 } 1497 1498 int hwc_sync(hwc_context_t *ctx, hwc_display_contents_1_t* list, int dpy, 1499 int fd) { 1500 ATRACE_CALL(); 1501 int ret = 0; 1502 int acquireFd[MAX_NUM_APP_LAYERS]; 1503 int count = 0; 1504 int releaseFd = -1; 1505 int retireFd = -1; 1506 int fbFd = -1; 1507 bool swapzero = false; 1508 1509 struct mdp_buf_sync data; 1510 memset(&data, 0, sizeof(data)); 1511 data.acq_fen_fd = acquireFd; 1512 data.rel_fen_fd = &releaseFd; 1513 data.retire_fen_fd = &retireFd; 1514 data.flags = MDP_BUF_SYNC_FLAG_RETIRE_FENCE; 1515 1516 char property[PROPERTY_VALUE_MAX]; 1517 if(property_get("debug.egl.swapinterval", property, "1") > 0) { 1518 if(atoi(property) == 0) 1519 swapzero = true; 1520 } 1521 1522 bool isExtAnimating = false; 1523 if(dpy) 1524 isExtAnimating = ctx->listStats[dpy].isDisplayAnimating; 1525 1526 //Send acquireFenceFds to rotator 1527 for(uint32_t i = 0; i < ctx->mLayerRotMap[dpy]->getCount(); i++) { 1528 int rotFd = ctx->mRotMgr->getRotDevFd(); 1529 int rotReleaseFd = -1; 1530 overlay::Rotator* currRot = ctx->mLayerRotMap[dpy]->getRot(i); 1531 hwc_layer_1_t* currLayer = ctx->mLayerRotMap[dpy]->getLayer(i); 1532 if((currRot == NULL) || (currLayer == NULL)) { 1533 continue; 1534 } 1535 struct mdp_buf_sync rotData; 1536 memset(&rotData, 0, sizeof(rotData)); 1537 rotData.acq_fen_fd = 1538 &currLayer->acquireFenceFd; 1539 rotData.rel_fen_fd = &rotReleaseFd; //driver to populate this 1540 rotData.session_id = currRot->getSessId(); 1541 if(currLayer->acquireFenceFd >= 0) { 1542 rotData.acq_fen_fd_cnt = 1; //1 ioctl call per rot session 1543 } 1544 int ret = 0; 1545 if(LIKELY(!swapzero) and (not ctx->mLayerRotMap[dpy]->isRotCached(i))) 1546 ret = ioctl(rotFd, MSMFB_BUFFER_SYNC, &rotData); 1547 1548 if(ret < 0) { 1549 ALOGE("%s: ioctl MSMFB_BUFFER_SYNC failed for rot sync, err=%s", 1550 __FUNCTION__, strerror(errno)); 1551 close(rotReleaseFd); 1552 } else { 1553 close(currLayer->acquireFenceFd); 1554 //For MDP to wait on. 1555 currLayer->acquireFenceFd = 1556 dup(rotReleaseFd); 1557 //A buffer is free to be used by producer as soon as its copied to 1558 //rotator 1559 currLayer->releaseFenceFd = 1560 rotReleaseFd; 1561 } 1562 } 1563 1564 //Accumulate acquireFenceFds for MDP Overlays 1565 if(list->outbufAcquireFenceFd >= 0) { 1566 //Writeback output buffer 1567 if(LIKELY(!swapzero) ) 1568 acquireFd[count++] = list->outbufAcquireFenceFd; 1569 } 1570 1571 for(uint32_t i = 0; i < list->numHwLayers; i++) { 1572 if(((isAbcInUse(ctx)== true ) || 1573 (list->hwLayers[i].compositionType == HWC_OVERLAY)) && 1574 list->hwLayers[i].acquireFenceFd >= 0) { 1575 if(LIKELY(!swapzero) ) { 1576 // if ABC is enabled for more than one layer. 1577 // renderBufIndexforABC will work as FB.Hence 1578 // set the acquireFD from fd - which is coming from copybit 1579 if(fd >= 0 && (isAbcInUse(ctx) == true)) { 1580 if(ctx->listStats[dpy].renderBufIndexforABC ==(int32_t)i) 1581 acquireFd[count++] = fd; 1582 else 1583 continue; 1584 } else 1585 acquireFd[count++] = list->hwLayers[i].acquireFenceFd; 1586 } 1587 } 1588 if(list->hwLayers[i].compositionType == HWC_FRAMEBUFFER_TARGET) { 1589 if(LIKELY(!swapzero) ) { 1590 if(fd >= 0) { 1591 //set the acquireFD from fd - which is coming from c2d 1592 acquireFd[count++] = fd; 1593 // Buffer sync IOCTL should be async when using c2d fence is 1594 // used 1595 data.flags &= ~MDP_BUF_SYNC_FLAG_WAIT; 1596 } else if(list->hwLayers[i].acquireFenceFd >= 0) 1597 acquireFd[count++] = list->hwLayers[i].acquireFenceFd; 1598 } 1599 } 1600 } 1601 1602 if ((fd >= 0) && !dpy && ctx->mPtorInfo.isActive()) { 1603 // Acquire c2d fence of Overlap render buffer 1604 if(LIKELY(!swapzero) ) 1605 acquireFd[count++] = fd; 1606 } 1607 1608 data.acq_fen_fd_cnt = count; 1609 fbFd = ctx->dpyAttr[dpy].fd; 1610 1611 //Waits for acquire fences, returns a release fence 1612 if(LIKELY(!swapzero)) { 1613 ret = ioctl(fbFd, MSMFB_BUFFER_SYNC, &data); 1614 } 1615 1616 if(ret < 0) { 1617 ALOGE("%s: ioctl MSMFB_BUFFER_SYNC failed, err=%s", 1618 __FUNCTION__, strerror(errno)); 1619 ALOGE("%s: acq_fen_fd_cnt=%d flags=%d fd=%d dpy=%d numHwLayers=%zu", 1620 __FUNCTION__, data.acq_fen_fd_cnt, data.flags, fbFd, 1621 dpy, list->numHwLayers); 1622 close(releaseFd); 1623 releaseFd = -1; 1624 close(retireFd); 1625 retireFd = -1; 1626 } 1627 1628 for(uint32_t i = 0; i < list->numHwLayers; i++) { 1629 if(list->hwLayers[i].compositionType == HWC_OVERLAY || 1630 #ifdef QCOM_BSP 1631 list->hwLayers[i].compositionType == HWC_BLIT || 1632 #endif 1633 list->hwLayers[i].compositionType == HWC_FRAMEBUFFER_TARGET) { 1634 //Populate releaseFenceFds. 1635 if(UNLIKELY(swapzero)) { 1636 list->hwLayers[i].releaseFenceFd = -1; 1637 } else if(isExtAnimating) { 1638 // Release all the app layer fds immediately, 1639 // if animation is in progress. 1640 list->hwLayers[i].releaseFenceFd = -1; 1641 } else if(list->hwLayers[i].releaseFenceFd < 0 ) { 1642 #ifdef QCOM_BSP 1643 //If rotator has not already populated this field 1644 // & if it's a not VPU layer 1645 1646 // if ABC is enabled for more than one layer 1647 if(fd >= 0 && (isAbcInUse(ctx) == true) && 1648 ctx->listStats[dpy].renderBufIndexforABC !=(int32_t)i){ 1649 list->hwLayers[i].releaseFenceFd = dup(fd); 1650 } else if((list->hwLayers[i].compositionType == HWC_BLIT)&& 1651 (isAbcInUse(ctx) == false)){ 1652 //For Blit, the app layers should be released when the Blit 1653 //is complete. This fd was passed from copybit->draw 1654 list->hwLayers[i].releaseFenceFd = dup(fd); 1655 } else 1656 #endif 1657 { 1658 list->hwLayers[i].releaseFenceFd = dup(releaseFd); 1659 } 1660 } 1661 } 1662 } 1663 1664 if(fd >= 0) { 1665 close(fd); 1666 fd = -1; 1667 } 1668 1669 if (ctx->mCopyBit[dpy]) { 1670 if (!dpy && ctx->mPtorInfo.isActive()) 1671 ctx->mCopyBit[dpy]->setReleaseFdSync(releaseFd); 1672 else 1673 ctx->mCopyBit[dpy]->setReleaseFd(releaseFd); 1674 } 1675 1676 //Signals when MDP finishes reading rotator buffers. 1677 ctx->mLayerRotMap[dpy]->setReleaseFd(releaseFd); 1678 close(releaseFd); 1679 releaseFd = -1; 1680 1681 if(UNLIKELY(swapzero)) { 1682 list->retireFenceFd = -1; 1683 } else { 1684 list->retireFenceFd = retireFd; 1685 } 1686 return ret; 1687 } 1688 1689 void setMdpFlags(hwc_context_t *ctx, hwc_layer_1_t *layer, 1690 ovutils::eMdpFlags &mdpFlags, 1691 int rotDownscale, int transform) { 1692 private_handle_t *hnd = (private_handle_t *)layer->handle; 1693 MetaData_t *metadata = hnd ? (MetaData_t *)hnd->base_metadata : NULL; 1694 1695 if(layer->blending == HWC_BLENDING_PREMULT) { 1696 ovutils::setMdpFlags(mdpFlags, 1697 ovutils::OV_MDP_BLEND_FG_PREMULT); 1698 } 1699 1700 if(metadata && (metadata->operation & PP_PARAM_INTERLACED) && 1701 metadata->interlaced) { 1702 ovutils::setMdpFlags(mdpFlags, 1703 ovutils::OV_MDP_DEINTERLACE); 1704 } 1705 1706 // Mark MDP flags with SECURE_OVERLAY_SESSION for driver 1707 if(isSecureBuffer(hnd)) { 1708 ovutils::setMdpFlags(mdpFlags, 1709 ovutils::OV_MDP_SECURE_OVERLAY_SESSION); 1710 ovutils::setMdpFlags(mdpFlags, 1711 ovutils::OV_MDP_SMP_FORCE_ALLOC); 1712 } 1713 1714 if(isProtectedBuffer(hnd)) { 1715 ovutils::setMdpFlags(mdpFlags, 1716 ovutils::OV_MDP_SMP_FORCE_ALLOC); 1717 } 1718 1719 if(isSecureDisplayBuffer(hnd)) { 1720 // Mark MDP flags with SECURE_DISPLAY_OVERLAY_SESSION for driver 1721 ovutils::setMdpFlags(mdpFlags, 1722 ovutils::OV_MDP_SECURE_DISPLAY_OVERLAY_SESSION); 1723 } 1724 1725 //Pre-rotation will be used using rotator. 1726 if(has90Transform(layer) && isRotationDoable(ctx, hnd)) { 1727 ovutils::setMdpFlags(mdpFlags, 1728 ovutils::OV_MDP_SOURCE_ROTATED_90); 1729 } 1730 //No 90 component and no rot-downscale then flips done by MDP 1731 //If we use rot then it might as well do flips 1732 if(!(transform & HWC_TRANSFORM_ROT_90) && !rotDownscale) { 1733 if(transform & HWC_TRANSFORM_FLIP_H) { 1734 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDP_FLIP_H); 1735 } 1736 1737 if(transform & HWC_TRANSFORM_FLIP_V) { 1738 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDP_FLIP_V); 1739 } 1740 } 1741 1742 if(metadata && 1743 ((metadata->operation & PP_PARAM_HSIC) 1744 || (metadata->operation & PP_PARAM_IGC) 1745 || (metadata->operation & PP_PARAM_SHARP2))) { 1746 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDP_PP_EN); 1747 } 1748 } 1749 1750 int configRotator(Rotator *rot, Whf& whf, 1751 hwc_rect_t& crop, const eMdpFlags& mdpFlags, 1752 const eTransform& orient, const int& downscale) { 1753 1754 // Fix alignments for TILED format 1755 if(whf.format == MDP_Y_CRCB_H2V2_TILE || 1756 whf.format == MDP_Y_CBCR_H2V2_TILE) { 1757 whf.w = utils::alignup(whf.w, 64); 1758 whf.h = utils::alignup(whf.h, 32); 1759 } 1760 rot->setSource(whf); 1761 1762 if (qdutils::MDPVersion::getInstance().getMDPVersion() >= 1763 qdutils::MDSS_V5) { 1764 Dim rotCrop(crop.left, crop.top, crop.right - crop.left, 1765 crop.bottom - crop.top); 1766 rot->setCrop(rotCrop); 1767 } 1768 1769 rot->setFlags(mdpFlags); 1770 rot->setTransform(orient); 1771 rot->setDownscale(downscale); 1772 if(!rot->commit()) return -1; 1773 return 0; 1774 } 1775 1776 int configMdp(Overlay *ov, const PipeArgs& parg, 1777 const eTransform& orient, const hwc_rect_t& crop, 1778 const hwc_rect_t& pos, const MetaData_t *metadata, 1779 const eDest& dest) { 1780 ov->setSource(parg, dest); 1781 ov->setTransform(orient, dest); 1782 1783 int crop_w = crop.right - crop.left; 1784 int crop_h = crop.bottom - crop.top; 1785 Dim dcrop(crop.left, crop.top, crop_w, crop_h); 1786 ov->setCrop(dcrop, dest); 1787 1788 int posW = pos.right - pos.left; 1789 int posH = pos.bottom - pos.top; 1790 Dim position(pos.left, pos.top, posW, posH); 1791 ov->setPosition(position, dest); 1792 1793 if (metadata) 1794 ov->setVisualParams(*metadata, dest); 1795 1796 if (!ov->commit(dest)) { 1797 return -1; 1798 } 1799 return 0; 1800 } 1801 1802 int configColorLayer(hwc_context_t *ctx, hwc_layer_1_t *layer, 1803 const int& dpy, eMdpFlags& mdpFlags, eZorder& z, 1804 const eDest& dest) { 1805 1806 hwc_rect_t dst = layer->displayFrame; 1807 trimLayer(ctx, dpy, 0, dst, dst); 1808 1809 int w = ctx->dpyAttr[dpy].xres; 1810 int h = ctx->dpyAttr[dpy].yres; 1811 int dst_w = dst.right - dst.left; 1812 int dst_h = dst.bottom - dst.top; 1813 uint32_t color = layer->transform; 1814 Whf whf(w, h, getMdpFormat(HAL_PIXEL_FORMAT_RGBA_8888)); 1815 1816 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDP_SOLID_FILL); 1817 if (layer->blending == HWC_BLENDING_PREMULT) 1818 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDP_BLEND_FG_PREMULT); 1819 1820 PipeArgs parg(mdpFlags, whf, z, static_cast<eRotFlags>(0), 1821 layer->planeAlpha, 1822 (ovutils::eBlending) getBlending(layer->blending)); 1823 1824 // Configure MDP pipe for Color layer 1825 Dim pos(dst.left, dst.top, dst_w, dst_h); 1826 ctx->mOverlay->setSource(parg, dest); 1827 ctx->mOverlay->setColor(color, dest); 1828 ctx->mOverlay->setTransform(0, dest); 1829 ctx->mOverlay->setCrop(pos, dest); 1830 ctx->mOverlay->setPosition(pos, dest); 1831 1832 if (!ctx->mOverlay->commit(dest)) { 1833 ALOGE("%s: Configure color layer failed!", __FUNCTION__); 1834 return -1; 1835 } 1836 return 0; 1837 } 1838 1839 void updateSource(eTransform& orient, Whf& whf, 1840 hwc_rect_t& crop, Rotator *rot) { 1841 Dim transformedCrop(crop.left, crop.top, 1842 crop.right - crop.left, 1843 crop.bottom - crop.top); 1844 if (qdutils::MDPVersion::getInstance().getMDPVersion() >= 1845 qdutils::MDSS_V5) { 1846 //B-family rotator internally could modify destination dimensions if 1847 //downscaling is supported 1848 whf = rot->getDstWhf(); 1849 transformedCrop = rot->getDstDimensions(); 1850 } else { 1851 //A-family rotator rotates entire buffer irrespective of crop, forcing 1852 //us to recompute the crop based on transform 1853 orient = static_cast<eTransform>(ovutils::getMdpOrient(orient)); 1854 preRotateSource(orient, whf, transformedCrop); 1855 } 1856 1857 crop.left = transformedCrop.x; 1858 crop.top = transformedCrop.y; 1859 crop.right = transformedCrop.x + transformedCrop.w; 1860 crop.bottom = transformedCrop.y + transformedCrop.h; 1861 } 1862 1863 int getRotDownscale(hwc_context_t *ctx, const hwc_layer_1_t *layer) { 1864 if(not qdutils::MDPVersion::getInstance().isRotDownscaleEnabled()) { 1865 return 0; 1866 } 1867 1868 int downscale = 0; 1869 hwc_rect_t crop = integerizeSourceCrop(layer->sourceCropf); 1870 hwc_rect_t dst = layer->displayFrame; 1871 private_handle_t *hnd = (private_handle_t *)layer->handle; 1872 1873 if(not hnd) { 1874 return 0; 1875 } 1876 1877 MetaData_t *metadata = (MetaData_t *)hnd->base_metadata; 1878 bool isInterlaced = metadata && (metadata->operation & PP_PARAM_INTERLACED) 1879 && metadata->interlaced; 1880 int transform = layer->transform; 1881 uint32_t format = ovutils::getMdpFormat(hnd->format, hnd->flags); 1882 1883 if(isYuvBuffer(hnd)) { 1884 if(ctx->mMDP.version >= qdutils::MDP_V4_2 && 1885 ctx->mMDP.version < qdutils::MDSS_V5) { 1886 downscale = Rotator::getDownscaleFactor(crop.right - crop.left, 1887 crop.bottom - crop.top, dst.right - dst.left, 1888 dst.bottom - dst.top, format, isInterlaced); 1889 } else { 1890 Dim adjCrop(crop.left, crop.top, crop.right - crop.left, 1891 crop.bottom - crop.top); 1892 Dim pos(dst.left, dst.top, dst.right - dst.left, 1893 dst.bottom - dst.top); 1894 if(transform & HAL_TRANSFORM_ROT_90) { 1895 swap(adjCrop.w, adjCrop.h); 1896 } 1897 downscale = Rotator::getDownscaleFactor(adjCrop.w, adjCrop.h, pos.w, 1898 pos.h, format, isInterlaced); 1899 } 1900 } 1901 return downscale; 1902 } 1903 1904 bool isZoomModeEnabled(hwc_rect_t crop) { 1905 // This does not work for zooming in top left corner of the image 1906 return(crop.top > 0 || crop.left > 0); 1907 } 1908 1909 void updateCropAIVVideoMode(hwc_context_t *ctx, hwc_rect_t& crop, int dpy) { 1910 ALOGD_IF(HWC_UTILS_DEBUG, "dpy %d Source crop [%d %d %d %d]", dpy, 1911 crop.left, crop.top, crop.right, crop.bottom); 1912 if(isZoomModeEnabled(crop)) { 1913 Dim srcCrop(crop.left, crop.top, 1914 crop.right - crop.left, 1915 crop.bottom - crop.top); 1916 int extW = ctx->dpyAttr[dpy].xres; 1917 int extH = ctx->dpyAttr[dpy].yres; 1918 //Crop the original video in order to fit external display aspect ratio 1919 if(srcCrop.w * extH < extW * srcCrop.h) { 1920 int offset = (srcCrop.h - ((srcCrop.w * extH) / extW)) / 2; 1921 crop.top += offset; 1922 crop.bottom -= offset; 1923 } else { 1924 int offset = (srcCrop.w - ((extW * srcCrop.h) / extH)) / 2; 1925 crop.left += offset; 1926 crop.right -= offset; 1927 } 1928 ALOGD_IF(HWC_UTILS_DEBUG, "External Resolution [%d %d] dpy %d Modified" 1929 " source crop [%d %d %d %d]", extW, extH, dpy, 1930 crop.left, crop.top, crop.right, crop.bottom); 1931 } 1932 } 1933 1934 void updateDestAIVVideoMode(hwc_context_t *ctx, hwc_rect_t crop, 1935 hwc_rect_t& dst, int dpy) { 1936 ALOGD_IF(HWC_UTILS_DEBUG, "dpy %d Destination position [%d %d %d %d]", dpy, 1937 dst.left, dst.top, dst.right, dst.bottom); 1938 Dim srcCrop(crop.left, crop.top, 1939 crop.right - crop.left, 1940 crop.bottom - crop.top); 1941 int extW = ctx->dpyAttr[dpy].xres; 1942 int extH = ctx->dpyAttr[dpy].yres; 1943 // Set the destination coordinates of external display to full screen, 1944 // when zoom in mode is enabled or the ratio between video aspect ratio 1945 // and external display aspect ratio is below the minimum tolerance level 1946 // and above maximum tolerance level 1947 float videoAspectRatio = ((float)srcCrop.w / (float)srcCrop.h); 1948 float extDisplayAspectRatio = ((float)extW / (float)extH); 1949 float videoToExternalRatio = videoAspectRatio / extDisplayAspectRatio; 1950 if((fabs(1.0f - videoToExternalRatio) <= ctx->mAspectRatioToleranceLevel) || 1951 (isZoomModeEnabled(crop))) { 1952 dst.left = 0; 1953 dst.top = 0; 1954 dst.right = extW; 1955 dst.bottom = extH; 1956 } 1957 ALOGD_IF(HWC_UTILS_DEBUG, "External Resolution [%d %d] dpy %d Modified" 1958 " Destination position [%d %d %d %d] Source crop [%d %d %d %d]", 1959 extW, extH, dpy, dst.left, dst.top, dst.right, dst.bottom, 1960 crop.left, crop.top, crop.right, crop.bottom); 1961 } 1962 1963 void updateCoordinates(hwc_context_t *ctx, hwc_rect_t& crop, 1964 hwc_rect_t& dst, int dpy) { 1965 updateCropAIVVideoMode(ctx, crop, dpy); 1966 updateDestAIVVideoMode(ctx, crop, dst, dpy); 1967 } 1968 1969 int configureNonSplit(hwc_context_t *ctx, hwc_layer_1_t *layer, 1970 const int& dpy, eMdpFlags& mdpFlags, eZorder& z, 1971 const eDest& dest, Rotator **rot) { 1972 1973 private_handle_t *hnd = (private_handle_t *)layer->handle; 1974 1975 if(!hnd) { 1976 if (layer->flags & HWC_COLOR_FILL) { 1977 // Configure Color layer 1978 return configColorLayer(ctx, layer, dpy, mdpFlags, z, dest); 1979 } 1980 ALOGE("%s: layer handle is NULL", __FUNCTION__); 1981 return -1; 1982 } 1983 1984 MetaData_t *metadata = (MetaData_t *)hnd->base_metadata; 1985 1986 hwc_rect_t crop = integerizeSourceCrop(layer->sourceCropf); 1987 hwc_rect_t dst = layer->displayFrame; 1988 int transform = layer->transform; 1989 eTransform orient = static_cast<eTransform>(transform); 1990 int rotFlags = ovutils::ROT_FLAGS_NONE; 1991 uint32_t format = ovutils::getMdpFormat(hnd->format, hnd->flags); 1992 Whf whf(getWidth(hnd), getHeight(hnd), format, (uint32_t)hnd->size); 1993 1994 // Handle R/B swap 1995 if (layer->flags & HWC_FORMAT_RB_SWAP) { 1996 if (hnd->format == HAL_PIXEL_FORMAT_RGBA_8888) 1997 whf.format = getMdpFormat(HAL_PIXEL_FORMAT_BGRA_8888); 1998 else if (hnd->format == HAL_PIXEL_FORMAT_RGBX_8888) 1999 whf.format = getMdpFormat(HAL_PIXEL_FORMAT_BGRX_8888); 2000 } 2001 // update source crop and destination position of AIV video layer. 2002 if(ctx->listStats[dpy].mAIVVideoMode && isYuvBuffer(hnd)) { 2003 updateCoordinates(ctx, crop, dst, dpy); 2004 } 2005 calcExtDisplayPosition(ctx, hnd, dpy, crop, dst, transform, orient); 2006 int downscale = getRotDownscale(ctx, layer); 2007 setMdpFlags(ctx, layer, mdpFlags, downscale, transform); 2008 2009 //if 90 component or downscale, use rot 2010 if((has90Transform(layer) or downscale) and isRotationDoable(ctx, hnd)) { 2011 *rot = ctx->mRotMgr->getNext(); 2012 if(*rot == NULL) return -1; 2013 ctx->mLayerRotMap[dpy]->add(layer, *rot); 2014 BwcPM::setBwc(ctx, dpy, hnd, crop, dst, transform, downscale, 2015 mdpFlags); 2016 //Configure rotator for pre-rotation 2017 if(configRotator(*rot, whf, crop, mdpFlags, orient, downscale) < 0) { 2018 ALOGE("%s: configRotator failed!", __FUNCTION__); 2019 return -1; 2020 } 2021 updateSource(orient, whf, crop, *rot); 2022 rotFlags |= ROT_PREROTATED; 2023 } 2024 2025 //For the mdp, since either we are pre-rotating or MDP does flips 2026 orient = OVERLAY_TRANSFORM_0; 2027 transform = 0; 2028 PipeArgs parg(mdpFlags, whf, z, 2029 static_cast<eRotFlags>(rotFlags), layer->planeAlpha, 2030 (ovutils::eBlending) getBlending(layer->blending)); 2031 2032 if(configMdp(ctx->mOverlay, parg, orient, crop, dst, metadata, dest) < 0) { 2033 ALOGE("%s: commit failed for low res panel", __FUNCTION__); 2034 return -1; 2035 } 2036 return 0; 2037 } 2038 2039 //Helper to 1) Ensure crops dont have gaps 2) Ensure L and W are even 2040 void sanitizeSourceCrop(hwc_rect_t& cropL, hwc_rect_t& cropR, 2041 private_handle_t *hnd) { 2042 if(cropL.right - cropL.left) { 2043 if(isYuvBuffer(hnd)) { 2044 //Always safe to even down left 2045 ovutils::even_floor(cropL.left); 2046 //If right is even, automatically width is even, since left is 2047 //already even 2048 ovutils::even_floor(cropL.right); 2049 } 2050 //Make sure there are no gaps between left and right splits if the layer 2051 //is spread across BOTH halves 2052 if(cropR.right - cropR.left) { 2053 cropR.left = cropL.right; 2054 } 2055 } 2056 2057 if(cropR.right - cropR.left) { 2058 if(isYuvBuffer(hnd)) { 2059 //Always safe to even down left 2060 ovutils::even_floor(cropR.left); 2061 //If right is even, automatically width is even, since left is 2062 //already even 2063 ovutils::even_floor(cropR.right); 2064 } 2065 } 2066 } 2067 2068 int configureSplit(hwc_context_t *ctx, hwc_layer_1_t *layer, 2069 const int& dpy, eMdpFlags& mdpFlagsL, eZorder& z, 2070 const eDest& lDest, const eDest& rDest, 2071 Rotator **rot) { 2072 private_handle_t *hnd = (private_handle_t *)layer->handle; 2073 if(!hnd) { 2074 ALOGE("%s: layer handle is NULL", __FUNCTION__); 2075 return -1; 2076 } 2077 2078 MetaData_t *metadata = (MetaData_t *)hnd->base_metadata; 2079 2080 int hw_w = ctx->dpyAttr[dpy].xres; 2081 int hw_h = ctx->dpyAttr[dpy].yres; 2082 hwc_rect_t crop = integerizeSourceCrop(layer->sourceCropf); 2083 hwc_rect_t dst = layer->displayFrame; 2084 int transform = layer->transform; 2085 eTransform orient = static_cast<eTransform>(transform); 2086 int rotFlags = ROT_FLAGS_NONE; 2087 uint32_t format = ovutils::getMdpFormat(hnd->format, hnd->flags); 2088 Whf whf(getWidth(hnd), getHeight(hnd), format, (uint32_t)hnd->size); 2089 2090 // Handle R/B swap 2091 if (layer->flags & HWC_FORMAT_RB_SWAP) { 2092 if (hnd->format == HAL_PIXEL_FORMAT_RGBA_8888) 2093 whf.format = getMdpFormat(HAL_PIXEL_FORMAT_BGRA_8888); 2094 else if (hnd->format == HAL_PIXEL_FORMAT_RGBX_8888) 2095 whf.format = getMdpFormat(HAL_PIXEL_FORMAT_BGRX_8888); 2096 } 2097 2098 // update source crop and destination position of AIV video layer. 2099 if(ctx->listStats[dpy].mAIVVideoMode && isYuvBuffer(hnd)) { 2100 updateCoordinates(ctx, crop, dst, dpy); 2101 } 2102 2103 /* Calculate the external display position based on MDP downscale, 2104 ActionSafe, and extorientation features. */ 2105 calcExtDisplayPosition(ctx, hnd, dpy, crop, dst, transform, orient); 2106 int downscale = getRotDownscale(ctx, layer); 2107 setMdpFlags(ctx, layer, mdpFlagsL, downscale, transform); 2108 2109 if(lDest != OV_INVALID && rDest != OV_INVALID) { 2110 //Enable overfetch 2111 setMdpFlags(mdpFlagsL, OV_MDSS_MDP_DUAL_PIPE); 2112 } 2113 2114 //Will do something only if feature enabled and conditions suitable 2115 //hollow call otherwise 2116 if(ctx->mAD->prepare(ctx, crop, whf, hnd)) { 2117 overlay::Writeback *wb = overlay::Writeback::getInstance(); 2118 whf.format = wb->getOutputFormat(); 2119 } 2120 2121 if((has90Transform(layer) or downscale) and isRotationDoable(ctx, hnd)) { 2122 (*rot) = ctx->mRotMgr->getNext(); 2123 if((*rot) == NULL) return -1; 2124 ctx->mLayerRotMap[dpy]->add(layer, *rot); 2125 //Configure rotator for pre-rotation 2126 if(configRotator(*rot, whf, crop, mdpFlagsL, orient, downscale) < 0) { 2127 ALOGE("%s: configRotator failed!", __FUNCTION__); 2128 return -1; 2129 } 2130 updateSource(orient, whf, crop, *rot); 2131 rotFlags |= ROT_PREROTATED; 2132 } 2133 2134 eMdpFlags mdpFlagsR = mdpFlagsL; 2135 setMdpFlags(mdpFlagsR, OV_MDSS_MDP_RIGHT_MIXER); 2136 2137 hwc_rect_t tmp_cropL = {0}, tmp_dstL = {0}; 2138 hwc_rect_t tmp_cropR = {0}, tmp_dstR = {0}; 2139 2140 const int lSplit = getLeftSplit(ctx, dpy); 2141 2142 // Calculate Left rects 2143 if(dst.left < lSplit) { 2144 tmp_cropL = crop; 2145 tmp_dstL = dst; 2146 hwc_rect_t scissor = {0, 0, lSplit, hw_h }; 2147 scissor = getIntersection(ctx->mViewFrame[dpy], scissor); 2148 qhwc::calculate_crop_rects(tmp_cropL, tmp_dstL, scissor, 0); 2149 } 2150 2151 // Calculate Right rects 2152 if(dst.right > lSplit) { 2153 tmp_cropR = crop; 2154 tmp_dstR = dst; 2155 hwc_rect_t scissor = {lSplit, 0, hw_w, hw_h }; 2156 scissor = getIntersection(ctx->mViewFrame[dpy], scissor); 2157 qhwc::calculate_crop_rects(tmp_cropR, tmp_dstR, scissor, 0); 2158 } 2159 2160 sanitizeSourceCrop(tmp_cropL, tmp_cropR, hnd); 2161 2162 //When buffer is H-flipped, contents of mixer config also needs to swapped 2163 //Not needed if the layer is confined to one half of the screen. 2164 //If rotator has been used then it has also done the flips, so ignore them. 2165 if((orient & OVERLAY_TRANSFORM_FLIP_H) && (dst.left < lSplit) && 2166 (dst.right > lSplit) && (*rot) == NULL) { 2167 hwc_rect_t new_cropR; 2168 new_cropR.left = tmp_cropL.left; 2169 new_cropR.right = new_cropR.left + (tmp_cropR.right - tmp_cropR.left); 2170 2171 hwc_rect_t new_cropL; 2172 new_cropL.left = new_cropR.right; 2173 new_cropL.right = tmp_cropR.right; 2174 2175 tmp_cropL.left = new_cropL.left; 2176 tmp_cropL.right = new_cropL.right; 2177 2178 tmp_cropR.left = new_cropR.left; 2179 tmp_cropR.right = new_cropR.right; 2180 2181 } 2182 2183 //For the mdp, since either we are pre-rotating or MDP does flips 2184 orient = OVERLAY_TRANSFORM_0; 2185 transform = 0; 2186 2187 //configure left mixer 2188 if(lDest != OV_INVALID) { 2189 PipeArgs pargL(mdpFlagsL, whf, z, 2190 static_cast<eRotFlags>(rotFlags), layer->planeAlpha, 2191 (ovutils::eBlending) getBlending(layer->blending)); 2192 2193 if(configMdp(ctx->mOverlay, pargL, orient, 2194 tmp_cropL, tmp_dstL, metadata, lDest) < 0) { 2195 ALOGE("%s: commit failed for left mixer config", __FUNCTION__); 2196 return -1; 2197 } 2198 } 2199 2200 //configure right mixer 2201 if(rDest != OV_INVALID) { 2202 PipeArgs pargR(mdpFlagsR, whf, z, 2203 static_cast<eRotFlags>(rotFlags), 2204 layer->planeAlpha, 2205 (ovutils::eBlending) getBlending(layer->blending)); 2206 tmp_dstR.right = tmp_dstR.right - lSplit; 2207 tmp_dstR.left = tmp_dstR.left - lSplit; 2208 if(configMdp(ctx->mOverlay, pargR, orient, 2209 tmp_cropR, tmp_dstR, metadata, rDest) < 0) { 2210 ALOGE("%s: commit failed for right mixer config", __FUNCTION__); 2211 return -1; 2212 } 2213 } 2214 2215 return 0; 2216 } 2217 2218 int configureSourceSplit(hwc_context_t *ctx, hwc_layer_1_t *layer, 2219 const int& dpy, eMdpFlags& mdpFlagsL, eZorder& z, 2220 const eDest& lDest, const eDest& rDest, 2221 Rotator **rot) { 2222 private_handle_t *hnd = (private_handle_t *)layer->handle; 2223 if(!hnd) { 2224 ALOGE("%s: layer handle is NULL", __FUNCTION__); 2225 return -1; 2226 } 2227 2228 MetaData_t *metadata = (MetaData_t *)hnd->base_metadata; 2229 2230 hwc_rect_t crop = integerizeSourceCrop(layer->sourceCropf);; 2231 hwc_rect_t dst = layer->displayFrame; 2232 int transform = layer->transform; 2233 eTransform orient = static_cast<eTransform>(transform); 2234 const int downscale = 0; 2235 int rotFlags = ROT_FLAGS_NONE; 2236 //Splitting only YUV layer on primary panel needs different zorders 2237 //for both layers as both the layers are configured to single mixer 2238 eZorder lz = z; 2239 eZorder rz = (eZorder)(z + 1); 2240 2241 Whf whf(getWidth(hnd), getHeight(hnd), 2242 getMdpFormat(hnd->format), (uint32_t)hnd->size); 2243 2244 // update source crop and destination position of AIV video layer. 2245 if(ctx->listStats[dpy].mAIVVideoMode && isYuvBuffer(hnd)) { 2246 updateCoordinates(ctx, crop, dst, dpy); 2247 } 2248 2249 /* Calculate the external display position based on MDP downscale, 2250 ActionSafe, and extorientation features. */ 2251 calcExtDisplayPosition(ctx, hnd, dpy, crop, dst, transform, orient); 2252 2253 setMdpFlags(ctx, layer, mdpFlagsL, 0, transform); 2254 trimLayer(ctx, dpy, transform, crop, dst); 2255 2256 if(has90Transform(layer) && isRotationDoable(ctx, hnd)) { 2257 (*rot) = ctx->mRotMgr->getNext(); 2258 if((*rot) == NULL) return -1; 2259 ctx->mLayerRotMap[dpy]->add(layer, *rot); 2260 //Configure rotator for pre-rotation 2261 if(configRotator(*rot, whf, crop, mdpFlagsL, orient, downscale) < 0) { 2262 ALOGE("%s: configRotator failed!", __FUNCTION__); 2263 return -1; 2264 } 2265 updateSource(orient, whf, crop, *rot); 2266 rotFlags |= ROT_PREROTATED; 2267 } 2268 2269 eMdpFlags mdpFlagsR = mdpFlagsL; 2270 int lSplit = dst.left + (dst.right - dst.left)/2; 2271 2272 hwc_rect_t tmp_cropL = {0}, tmp_dstL = {0}; 2273 hwc_rect_t tmp_cropR = {0}, tmp_dstR = {0}; 2274 2275 if(lDest != OV_INVALID) { 2276 tmp_cropL = crop; 2277 tmp_dstL = dst; 2278 hwc_rect_t scissor = {dst.left, dst.top, lSplit, dst.bottom }; 2279 qhwc::calculate_crop_rects(tmp_cropL, tmp_dstL, scissor, 0); 2280 } 2281 if(rDest != OV_INVALID) { 2282 tmp_cropR = crop; 2283 tmp_dstR = dst; 2284 hwc_rect_t scissor = {lSplit, dst.top, dst.right, dst.bottom }; 2285 qhwc::calculate_crop_rects(tmp_cropR, tmp_dstR, scissor, 0); 2286 } 2287 2288 sanitizeSourceCrop(tmp_cropL, tmp_cropR, hnd); 2289 2290 //When buffer is H-flipped, contents of mixer config also needs to swapped 2291 //Not needed if the layer is confined to one half of the screen. 2292 //If rotator has been used then it has also done the flips, so ignore them. 2293 if((orient & OVERLAY_TRANSFORM_FLIP_H) && lDest != OV_INVALID 2294 && rDest != OV_INVALID && (*rot) == NULL) { 2295 hwc_rect_t new_cropR; 2296 new_cropR.left = tmp_cropL.left; 2297 new_cropR.right = new_cropR.left + (tmp_cropR.right - tmp_cropR.left); 2298 2299 hwc_rect_t new_cropL; 2300 new_cropL.left = new_cropR.right; 2301 new_cropL.right = tmp_cropR.right; 2302 2303 tmp_cropL.left = new_cropL.left; 2304 tmp_cropL.right = new_cropL.right; 2305 2306 tmp_cropR.left = new_cropR.left; 2307 tmp_cropR.right = new_cropR.right; 2308 2309 } 2310 2311 //For the mdp, since either we are pre-rotating or MDP does flips 2312 orient = OVERLAY_TRANSFORM_0; 2313 transform = 0; 2314 2315 //configure left half 2316 if(lDest != OV_INVALID) { 2317 PipeArgs pargL(mdpFlagsL, whf, lz, 2318 static_cast<eRotFlags>(rotFlags), layer->planeAlpha, 2319 (ovutils::eBlending) getBlending(layer->blending)); 2320 2321 if(configMdp(ctx->mOverlay, pargL, orient, 2322 tmp_cropL, tmp_dstL, metadata, lDest) < 0) { 2323 ALOGE("%s: commit failed for left half config", __FUNCTION__); 2324 return -1; 2325 } 2326 } 2327 2328 //configure right half 2329 if(rDest != OV_INVALID) { 2330 PipeArgs pargR(mdpFlagsR, whf, rz, 2331 static_cast<eRotFlags>(rotFlags), 2332 layer->planeAlpha, 2333 (ovutils::eBlending) getBlending(layer->blending)); 2334 if(configMdp(ctx->mOverlay, pargR, orient, 2335 tmp_cropR, tmp_dstR, metadata, rDest) < 0) { 2336 ALOGE("%s: commit failed for right half config", __FUNCTION__); 2337 return -1; 2338 } 2339 } 2340 2341 return 0; 2342 } 2343 2344 bool canUseRotator(hwc_context_t *ctx, int dpy) { 2345 if(ctx->mOverlay->isDMAMultiplexingSupported() && 2346 isSecondaryConnected(ctx) && 2347 !ctx->dpyAttr[HWC_DISPLAY_VIRTUAL].isPause) { 2348 /* mdss driver on certain targets support multiplexing of DMA pipe 2349 * in LINE and BLOCK modes for writeback panels. 2350 */ 2351 if(dpy == HWC_DISPLAY_PRIMARY) 2352 return false; 2353 } 2354 if((ctx->mMDP.version == qdutils::MDP_V3_0_4) 2355 ||(ctx->mMDP.version == qdutils::MDP_V3_0_5)) 2356 return false; 2357 return true; 2358 } 2359 2360 int getLeftSplit(hwc_context_t *ctx, const int& dpy) { 2361 //Default even split for all displays with high res 2362 int lSplit = ctx->dpyAttr[dpy].xres / 2; 2363 if(dpy == HWC_DISPLAY_PRIMARY && 2364 qdutils::MDPVersion::getInstance().getLeftSplit()) { 2365 //Override if split published by driver for primary 2366 lSplit = qdutils::MDPVersion::getInstance().getLeftSplit(); 2367 } 2368 return lSplit; 2369 } 2370 2371 bool isDisplaySplit(hwc_context_t* ctx, int dpy) { 2372 qdutils::MDPVersion& mdpHw = qdutils::MDPVersion::getInstance(); 2373 if(ctx->dpyAttr[dpy].xres > mdpHw.getMaxPipeWidth()) { 2374 return true; 2375 } 2376 //For testing we could split primary via device tree values 2377 if(dpy == HWC_DISPLAY_PRIMARY && mdpHw.getRightSplit()) { 2378 return true; 2379 } 2380 return false; 2381 } 2382 2383 //clear prev layer prop flags and realloc for current frame 2384 void reset_layer_prop(hwc_context_t* ctx, int dpy, int numAppLayers) { 2385 if(ctx->layerProp[dpy]) { 2386 delete[] ctx->layerProp[dpy]; 2387 ctx->layerProp[dpy] = NULL; 2388 } 2389 ctx->layerProp[dpy] = new LayerProp[numAppLayers]; 2390 } 2391 2392 bool isAbcInUse(hwc_context_t *ctx){ 2393 return (ctx->enableABC && ctx->listStats[0].renderBufIndexforABC == 0); 2394 } 2395 2396 void dumpBuffer(private_handle_t *ohnd, char *bufferName) { 2397 if (ohnd != NULL && ohnd->base) { 2398 char dumpFilename[PATH_MAX]; 2399 bool bResult = false; 2400 int width = getWidth(ohnd); 2401 int height = getHeight(ohnd); 2402 int format = ohnd->format; 2403 //dummy aligned w & h. 2404 int alW = 0, alH = 0; 2405 int size = getBufferSizeAndDimensions(width, height, format, alW, alH); 2406 snprintf(dumpFilename, sizeof(dumpFilename), "/data/%s.%s.%dx%d.raw", 2407 bufferName, 2408 overlay::utils::getFormatString(utils::getMdpFormat(format)), 2409 width, height); 2410 FILE* fp = fopen(dumpFilename, "w+"); 2411 if (NULL != fp) { 2412 bResult = (bool) fwrite((void*)ohnd->base, size, 1, fp); 2413 fclose(fp); 2414 } 2415 ALOGD("Buffer[%s] Dump to %s: %s", 2416 bufferName, dumpFilename, bResult ? "Success" : "Fail"); 2417 } 2418 } 2419 2420 bool isGLESComp(hwc_context_t *ctx, 2421 hwc_display_contents_1_t* list) { 2422 int numAppLayers = ctx->listStats[HWC_DISPLAY_PRIMARY].numAppLayers; 2423 for(int index = 0; index < numAppLayers; index++) { 2424 hwc_layer_1_t* layer = &(list->hwLayers[index]); 2425 if(layer->compositionType == HWC_FRAMEBUFFER) 2426 return true; 2427 } 2428 return false; 2429 } 2430 2431 void setGPUHint(hwc_context_t* ctx, hwc_display_contents_1_t* list) { 2432 struct gpu_hint_info *gpuHint = &ctx->mGPUHintInfo; 2433 if(!gpuHint->mGpuPerfModeEnable || !ctx || !list) 2434 return; 2435 2436 #ifdef QCOM_BSP 2437 /* Set the GPU hint flag to high for MIXED/GPU composition only for 2438 first frame after MDP -> GPU/MIXED mode transition. Set the GPU 2439 hint to default if the previous composition is GPU or current GPU 2440 composition is due to idle fallback */ 2441 if(!gpuHint->mEGLDisplay || !gpuHint->mEGLContext) { 2442 gpuHint->mEGLDisplay = eglGetCurrentDisplay(); 2443 if(!gpuHint->mEGLDisplay) { 2444 ALOGW("%s Warning: EGL current display is NULL", __FUNCTION__); 2445 return; 2446 } 2447 gpuHint->mEGLContext = eglGetCurrentContext(); 2448 if(!gpuHint->mEGLContext) { 2449 ALOGW("%s Warning: EGL current context is NULL", __FUNCTION__); 2450 return; 2451 } 2452 } 2453 if(isGLESComp(ctx, list)) { 2454 if(gpuHint->mCompositionState != COMPOSITION_STATE_GPU 2455 && !MDPComp::isIdleFallback()) { 2456 EGLint attr_list[] = {EGL_GPU_HINT_1, 2457 EGL_GPU_LEVEL_3, 2458 EGL_NONE }; 2459 if((gpuHint->mCurrGPUPerfMode != EGL_GPU_LEVEL_3) && 2460 !eglGpuPerfHintQCOM(gpuHint->mEGLDisplay, 2461 gpuHint->mEGLContext, attr_list)) { 2462 ALOGW("eglGpuPerfHintQCOM failed for Built in display"); 2463 } else { 2464 gpuHint->mCurrGPUPerfMode = EGL_GPU_LEVEL_3; 2465 gpuHint->mCompositionState = COMPOSITION_STATE_GPU; 2466 } 2467 } else { 2468 EGLint attr_list[] = {EGL_GPU_HINT_1, 2469 EGL_GPU_LEVEL_0, 2470 EGL_NONE }; 2471 if((gpuHint->mCurrGPUPerfMode != EGL_GPU_LEVEL_0) && 2472 !eglGpuPerfHintQCOM(gpuHint->mEGLDisplay, 2473 gpuHint->mEGLContext, attr_list)) { 2474 ALOGW("eglGpuPerfHintQCOM failed for Built in display"); 2475 } else { 2476 gpuHint->mCurrGPUPerfMode = EGL_GPU_LEVEL_0; 2477 } 2478 if(MDPComp::isIdleFallback()) { 2479 gpuHint->mCompositionState = COMPOSITION_STATE_IDLE_FALLBACK; 2480 } 2481 } 2482 } else { 2483 /* set the GPU hint flag to default for MDP composition */ 2484 EGLint attr_list[] = {EGL_GPU_HINT_1, 2485 EGL_GPU_LEVEL_0, 2486 EGL_NONE }; 2487 if((gpuHint->mCurrGPUPerfMode != EGL_GPU_LEVEL_0) && 2488 !eglGpuPerfHintQCOM(gpuHint->mEGLDisplay, 2489 gpuHint->mEGLContext, attr_list)) { 2490 ALOGW("eglGpuPerfHintQCOM failed for Built in display"); 2491 } else { 2492 gpuHint->mCurrGPUPerfMode = EGL_GPU_LEVEL_0; 2493 } 2494 gpuHint->mCompositionState = COMPOSITION_STATE_MDP; 2495 } 2496 #endif 2497 } 2498 2499 bool isPeripheral(const hwc_rect_t& rect1, const hwc_rect_t& rect2) { 2500 // To be peripheral, 3 boundaries should match. 2501 uint8_t eqBounds = 0; 2502 if (rect1.left == rect2.left) 2503 eqBounds++; 2504 if (rect1.top == rect2.top) 2505 eqBounds++; 2506 if (rect1.right == rect2.right) 2507 eqBounds++; 2508 if (rect1.bottom == rect2.bottom) 2509 eqBounds++; 2510 return (eqBounds == 3); 2511 } 2512 2513 void applyDefaultMode(hwc_context_t *ctx) { 2514 char value[PROPERTY_VALUE_MAX]; 2515 int boot_finished = 0; 2516 static int ret = ctx->mColorMode->applyDefaultMode(); 2517 if(!ret) { 2518 ctx->mDefaultModeApplied = true; 2519 return; 2520 } 2521 2522 // Reading property set on boot finish in SF 2523 property_get("service.bootanim.exit", value, "0"); 2524 boot_finished = atoi(value); 2525 if (!boot_finished) 2526 return; 2527 2528 ret = ctx->mColorMode->applyDefaultMode(); 2529 if (ret) 2530 ALOGD("%s: Not able to apply default mode", __FUNCTION__); 2531 ctx->mDefaultModeApplied = true; 2532 } 2533 2534 void BwcPM::setBwc(const hwc_context_t *ctx, const int& dpy, 2535 const private_handle_t *hnd, 2536 const hwc_rect_t& crop, const hwc_rect_t& dst, 2537 const int& transform,const int& downscale, 2538 ovutils::eMdpFlags& mdpFlags) { 2539 //Target doesnt support Bwc 2540 qdutils::MDPVersion& mdpHw = qdutils::MDPVersion::getInstance(); 2541 if(not mdpHw.supportsBWC()) { 2542 return; 2543 } 2544 //Disabled at runtime 2545 if(not ctx->mBWCEnabled) return; 2546 //BWC not supported with rot-downscale 2547 if(downscale) return; 2548 //Not enabled for secondary displays 2549 if(dpy) return; 2550 //Not enabled for non-video buffers 2551 if(not isYuvBuffer(hnd)) return; 2552 2553 int src_w = crop.right - crop.left; 2554 int src_h = crop.bottom - crop.top; 2555 int dst_w = dst.right - dst.left; 2556 int dst_h = dst.bottom - dst.top; 2557 if(transform & HAL_TRANSFORM_ROT_90) { 2558 swap(src_w, src_h); 2559 } 2560 //src width > MAX mixer supported dim 2561 if(src_w > (int) qdutils::MDPVersion::getInstance().getMaxPipeWidth()) { 2562 return; 2563 } 2564 //H/w requirement for BWC only. Pipe can still support 4096 2565 if(src_h > 4092) { 2566 return; 2567 } 2568 //Decimation necessary, cannot use BWC. H/W requirement. 2569 if(qdutils::MDPVersion::getInstance().supportsDecimation()) { 2570 uint8_t horzDeci = 0; 2571 uint8_t vertDeci = 0; 2572 ovutils::getDecimationFactor(src_w, src_h, dst_w, dst_h, horzDeci, 2573 vertDeci); 2574 if(horzDeci || vertDeci) return; 2575 } 2576 2577 ovutils::setMdpFlags(mdpFlags, ovutils::OV_MDSS_MDP_BWC_EN); 2578 } 2579 2580 void LayerRotMap::add(hwc_layer_1_t* layer, Rotator *rot) { 2581 if(mCount >= RotMgr::MAX_ROT_SESS) return; 2582 mLayer[mCount] = layer; 2583 mRot[mCount] = rot; 2584 mCount++; 2585 } 2586 2587 void LayerRotMap::reset() { 2588 for (int i = 0; i < RotMgr::MAX_ROT_SESS; i++) { 2589 mLayer[i] = 0; 2590 mRot[i] = 0; 2591 } 2592 mCount = 0; 2593 } 2594 2595 void LayerRotMap::clear() { 2596 RotMgr::getInstance()->markUnusedTop(mCount); 2597 reset(); 2598 } 2599 2600 bool LayerRotMap::isRotCached(uint32_t index) const { 2601 overlay::Rotator* rot = getRot(index); 2602 hwc_layer_1_t* layer = getLayer(index); 2603 2604 if(rot and layer and layer->handle) { 2605 private_handle_t *hnd = (private_handle_t *)(layer->handle); 2606 return (rot->isRotCached(hnd->fd,(uint32_t)(hnd->offset))); 2607 } 2608 return false; 2609 } 2610 2611 void LayerRotMap::setReleaseFd(const int& fence) { 2612 for(uint32_t i = 0; i < mCount; i++) { 2613 if(mRot[i] and mLayer[i] and mLayer[i]->handle) { 2614 /* Ensure that none of the above (Rotator-instance, 2615 * layer and layer-handle) are NULL*/ 2616 if(isRotCached(i)) 2617 mRot[i]->setPrevBufReleaseFd(dup(fence)); 2618 else 2619 mRot[i]->setCurrBufReleaseFd(dup(fence)); 2620 } 2621 } 2622 } 2623 2624 hwc_rect expandROIFromMidPoint(hwc_rect roi, hwc_rect fullFrame) { 2625 int lRoiWidth = 0, rRoiWidth = 0; 2626 int half_frame_width = fullFrame.right/2; 2627 2628 hwc_rect lFrame = fullFrame; 2629 hwc_rect rFrame = fullFrame; 2630 lFrame.right = (lFrame.right - lFrame.left)/2; 2631 rFrame.left = lFrame.right; 2632 2633 hwc_rect lRoi = getIntersection(roi, lFrame); 2634 hwc_rect rRoi = getIntersection(roi, rFrame); 2635 2636 lRoiWidth = lRoi.right - lRoi.left; 2637 rRoiWidth = rRoi.right - rRoi.left; 2638 2639 if(lRoiWidth && rRoiWidth) { 2640 if(lRoiWidth < rRoiWidth) 2641 roi.left = half_frame_width - rRoiWidth; 2642 else 2643 roi.right = half_frame_width + lRoiWidth; 2644 } 2645 return roi; 2646 } 2647 2648 void resetROI(hwc_context_t *ctx, const int dpy) { 2649 const int fbXRes = (int)ctx->dpyAttr[dpy].xres; 2650 const int fbYRes = (int)ctx->dpyAttr[dpy].yres; 2651 2652 /* When source split is enabled, both the panels are calibrated 2653 * in a single coordinate system. So only one ROI is generated 2654 * for the whole panel extending equally from the midpoint and 2655 * populated for the left side. */ 2656 if(!qdutils::MDPVersion::getInstance().isSrcSplit() && 2657 isDisplaySplit(ctx, dpy)) { 2658 const int lSplit = getLeftSplit(ctx, dpy); 2659 ctx->listStats[dpy].lRoi = (struct hwc_rect){0, 0, lSplit, fbYRes}; 2660 ctx->listStats[dpy].rRoi = (struct hwc_rect){lSplit, 0, fbXRes, fbYRes}; 2661 } else { 2662 ctx->listStats[dpy].lRoi = (struct hwc_rect){0, 0,fbXRes, fbYRes}; 2663 ctx->listStats[dpy].rRoi = (struct hwc_rect){0, 0, 0, 0}; 2664 } 2665 } 2666 2667 hwc_rect_t getSanitizeROI(struct hwc_rect roi, hwc_rect boundary) 2668 { 2669 if(!isValidRect(roi)) 2670 return roi; 2671 2672 struct hwc_rect t_roi = roi; 2673 2674 const int LEFT_ALIGN = qdutils::MDPVersion::getInstance().getLeftAlign(); 2675 const int WIDTH_ALIGN = qdutils::MDPVersion::getInstance().getWidthAlign(); 2676 const int TOP_ALIGN = qdutils::MDPVersion::getInstance().getTopAlign(); 2677 const int HEIGHT_ALIGN = qdutils::MDPVersion::getInstance().getHeightAlign(); 2678 const int MIN_WIDTH = qdutils::MDPVersion::getInstance().getMinROIWidth(); 2679 const int MIN_HEIGHT = qdutils::MDPVersion::getInstance().getMinROIHeight(); 2680 2681 /* Align to minimum width recommended by the panel */ 2682 if((t_roi.right - t_roi.left) < MIN_WIDTH) { 2683 if(MIN_WIDTH == boundary.right - boundary.left) { 2684 t_roi.left = 0; 2685 t_roi.right = MIN_WIDTH; 2686 } else { 2687 if((t_roi.left + MIN_WIDTH) > boundary.right) 2688 t_roi.left = t_roi.right - MIN_WIDTH; 2689 else 2690 t_roi.right = t_roi.left + MIN_WIDTH; 2691 } 2692 } 2693 2694 /* Align to minimum height recommended by the panel */ 2695 if((t_roi.bottom - t_roi.top) < MIN_HEIGHT) { 2696 if(MIN_HEIGHT == boundary.bottom - boundary.top) { 2697 t_roi.top = 0; 2698 t_roi.bottom = MIN_HEIGHT; 2699 } else { 2700 if((t_roi.top + MIN_HEIGHT) > boundary.bottom) 2701 t_roi.top = t_roi.bottom - MIN_HEIGHT; 2702 else 2703 t_roi.bottom = t_roi.top + MIN_HEIGHT; 2704 } 2705 } 2706 2707 /* Align left and width to meet panel restrictions */ 2708 if(LEFT_ALIGN) 2709 t_roi.left = t_roi.left - (t_roi.left % LEFT_ALIGN); 2710 2711 if(WIDTH_ALIGN) { 2712 int width = t_roi.right - t_roi.left; 2713 width = WIDTH_ALIGN * ((width + (WIDTH_ALIGN - 1)) / WIDTH_ALIGN); 2714 t_roi.right = t_roi.left + width; 2715 2716 if(t_roi.right > boundary.right) { 2717 t_roi.right = boundary.right; 2718 t_roi.left = t_roi.right - width; 2719 2720 if(LEFT_ALIGN) 2721 t_roi.left = t_roi.left - (t_roi.left % LEFT_ALIGN); 2722 } 2723 } 2724 2725 /* Align top and height to meet panel restrictions */ 2726 if(TOP_ALIGN) 2727 t_roi.top = t_roi.top - (t_roi.top % TOP_ALIGN); 2728 2729 if(HEIGHT_ALIGN) { 2730 int height = t_roi.bottom - t_roi.top; 2731 height = HEIGHT_ALIGN * ((height + (HEIGHT_ALIGN - 1)) / HEIGHT_ALIGN); 2732 t_roi.bottom = t_roi.top + height; 2733 2734 if(t_roi.bottom > boundary.bottom) { 2735 t_roi.bottom = boundary.bottom; 2736 t_roi.top = t_roi.bottom - height; 2737 2738 if(TOP_ALIGN) 2739 t_roi.top = t_roi.top - (t_roi.top % TOP_ALIGN); 2740 } 2741 } 2742 2743 return t_roi; 2744 } 2745 2746 void handle_pause(hwc_context_t* ctx, int dpy) { 2747 if(ctx->dpyAttr[dpy].connected) { 2748 ctx->mDrawLock.lock(); 2749 ctx->dpyAttr[dpy].isActive = true; 2750 ctx->dpyAttr[dpy].isPause = true; 2751 ctx->mDrawLock.unlock(); 2752 ctx->proc->invalidate(ctx->proc); 2753 2754 usleep(ctx->dpyAttr[HWC_DISPLAY_PRIMARY].vsync_period 2755 * 2 / 1000); 2756 2757 // At this point all the pipes used by External have been 2758 // marked as UNSET. 2759 ctx->mDrawLock.lock(); 2760 // Perform commit to unstage the pipes. 2761 if (!Overlay::displayCommit(ctx->dpyAttr[dpy].fd)) { 2762 ALOGE("%s: display commit fail! for %d dpy", 2763 __FUNCTION__, dpy); 2764 } 2765 ctx->mDrawLock.unlock(); 2766 ctx->proc->invalidate(ctx->proc); 2767 } 2768 return; 2769 } 2770 2771 void handle_resume(hwc_context_t* ctx, int dpy) { 2772 if(ctx->dpyAttr[dpy].connected) { 2773 ctx->mDrawLock.lock(); 2774 ctx->dpyAttr[dpy].isConfiguring = true; 2775 ctx->dpyAttr[dpy].isActive = true; 2776 ctx->mDrawLock.unlock(); 2777 ctx->proc->invalidate(ctx->proc); 2778 2779 usleep(ctx->dpyAttr[HWC_DISPLAY_PRIMARY].vsync_period 2780 * 2 / 1000); 2781 2782 //At this point external has all the pipes it would need. 2783 ctx->mDrawLock.lock(); 2784 ctx->dpyAttr[dpy].isPause = false; 2785 ctx->mDrawLock.unlock(); 2786 ctx->proc->invalidate(ctx->proc); 2787 } 2788 return; 2789 } 2790 2791 void clearPipeResources(hwc_context_t* ctx, int dpy) { 2792 if(ctx->mOverlay) { 2793 ctx->mOverlay->configBegin(); 2794 ctx->mOverlay->configDone(); 2795 } 2796 if(ctx->mRotMgr) { 2797 ctx->mRotMgr->clear(); 2798 } 2799 // Call a display commit to ensure that pipes and associated 2800 // fd's are cleaned up. 2801 if(!Overlay::displayCommit(ctx->dpyAttr[dpy].fd)) { 2802 ALOGE("%s: display commit failed for %d", __FUNCTION__, dpy); 2803 } 2804 } 2805 2806 // Handles online events when HDMI is the primary display. In particular, 2807 // online events for hdmi connected before AND after boot up and HWC init. 2808 void handle_online(hwc_context_t* ctx, int dpy) { 2809 //On 8994 due to hardware limitations, we disable bwc completely when HDMI 2810 //intf is active 2811 if(qdutils::MDPVersion::getInstance().is8994() and 2812 qdutils::MDPVersion::getInstance().supportsBWC()) { 2813 ctx->mBWCEnabled = false; 2814 } 2815 // Close the current fd if it was opened earlier on when HWC 2816 // was initialized. 2817 if (ctx->dpyAttr[dpy].fd >= 0) { 2818 close(ctx->dpyAttr[dpy].fd); 2819 ctx->dpyAttr[dpy].fd = -1; 2820 } 2821 // TODO: If HDMI is connected after the display has booted up, 2822 // and the best configuration is different from the default 2823 // then we need to deal with this appropriately. 2824 ctx->mHDMIDisplay->configure(); 2825 updateDisplayInfo(ctx, dpy); 2826 initCompositionResources(ctx, dpy); 2827 ctx->dpyAttr[dpy].connected = true; 2828 } 2829 2830 // Handles offline events for HDMI. This can be used for offline events 2831 // initiated by the HDMI driver and the CEC framework. 2832 void handle_offline(hwc_context_t* ctx, int dpy) { 2833 destroyCompositionResources(ctx, dpy); 2834 // Clear all pipe resources and call a display commit to ensure 2835 // that all the fd's are closed. This will ensure that the HDMI 2836 // core turns off and that we receive an event the next time the 2837 // cable is connected. 2838 if (ctx->mHDMIDisplay->isHDMIPrimaryDisplay()) { 2839 clearPipeResources(ctx, dpy); 2840 } 2841 ctx->mHDMIDisplay->teardown(); 2842 resetDisplayInfo(ctx, dpy); 2843 ctx->dpyAttr[dpy].connected = false; 2844 ctx->dpyAttr[dpy].isActive = false; 2845 //On 8994 due to hardware limitations, we enable bwc only when HDMI 2846 //intf is inactive 2847 if(qdutils::MDPVersion::getInstance().is8994() and 2848 qdutils::MDPVersion::getInstance().supportsBWC()) { 2849 ctx->mBWCEnabled = true; 2850 } 2851 } 2852 2853 void ColorMode::init() { 2854 //Map symbols from libmm-qdcm and get list of modes 2855 mModeHandle = dlopen("libmm-qdcm.so", RTLD_NOW); 2856 if (mModeHandle) { 2857 *(void **)& fnApplyDefaultMode = dlsym(mModeHandle, "applyDefaults"); 2858 *(void **)& fnApplyModeById = dlsym(mModeHandle, "applyModeById"); 2859 *(void **)& fnGetNumModes = dlsym(mModeHandle, "getNumDisplayModes"); 2860 *(void **)& fnGetCurrentMode = dlsym(mModeHandle, "getCurrentMode"); 2861 *(void **)& fnGetModeList = dlsym(mModeHandle, "getDisplayModeIdList"); 2862 *(void **)& fnSetDefaultMode = dlsym(mModeHandle, "setDefaultMode"); 2863 *(void **)& fnDeleteInstance = dlsym(mModeHandle, "deleteInstance"); 2864 } else { 2865 ALOGW("Unable to load libmm-qdcm"); 2866 } 2867 2868 if(fnGetNumModes) { 2869 mNumModes = fnGetNumModes(HWC_DISPLAY_PRIMARY); 2870 if(mNumModes > MAX_NUM_COLOR_MODES) { 2871 ALOGE("Number of modes is above the limit: %d", mNumModes); 2872 mNumModes = 0; 2873 return; 2874 } 2875 if(fnGetModeList) { 2876 fnGetModeList(mModeList, &mCurMode, HWC_DISPLAY_PRIMARY); 2877 mCurModeIndex = getIndexForMode(mCurMode); 2878 ALOGI("ColorMode: current mode: %d current mode index: %d number of modes: %d", 2879 mCurMode, mCurModeIndex, mNumModes); 2880 } 2881 } 2882 } 2883 2884 //Legacy API 2885 int ColorMode::applyDefaultMode() { 2886 int ret = 0; 2887 if(fnApplyDefaultMode) { 2888 ret = fnApplyDefaultMode(HWC_DISPLAY_PRIMARY); 2889 if(!ret) { 2890 mCurModeIndex = getIndexForMode(fnGetCurrentMode(HWC_DISPLAY_PRIMARY)); 2891 } 2892 return ret; 2893 } else { 2894 return -EINVAL; 2895 } 2896 } 2897 2898 int ColorMode::applyModeByID(int modeID) { 2899 if(fnApplyModeById) { 2900 int ret = fnApplyModeById(modeID, HWC_DISPLAY_PRIMARY); 2901 if (!ret) 2902 ret = setDefaultMode(modeID); 2903 return ret; 2904 } else { 2905 return -EINVAL; 2906 } 2907 } 2908 2909 //This API is called from setActiveConfig 2910 //The value here must be set as default 2911 int ColorMode::applyModeByIndex(int index) { 2912 int ret = 0; 2913 int mode = getModeForIndex(index); 2914 if(mode < 0) { 2915 ALOGE("Invalid mode for index: %d", index); 2916 return -EINVAL; 2917 } 2918 ALOGD("%s: Applying mode index: %d modeID: %d", __FUNCTION__, index, mode); 2919 ret = applyModeByID(mode); 2920 if(!ret) { 2921 mCurModeIndex = index; 2922 } 2923 return ret; 2924 } 2925 2926 int ColorMode::setDefaultMode(int modeID) { 2927 if(fnSetDefaultMode) { 2928 ALOGD("Setting default color mode to %d", modeID); 2929 return fnSetDefaultMode(modeID, HWC_DISPLAY_PRIMARY); 2930 } else { 2931 return -EINVAL; 2932 } 2933 } 2934 2935 int ColorMode::getModeForIndex(int index) { 2936 if(index < mNumModes) { 2937 return mModeList[index]; 2938 } else { 2939 return -EINVAL; 2940 } 2941 } 2942 2943 int ColorMode::getIndexForMode(int mode) { 2944 if(mModeList) { 2945 for(int32_t i = 0; i < mNumModes; i++) 2946 if(mModeList[i] == mode) 2947 return i; 2948 } 2949 return -EINVAL; 2950 } 2951 2952 void ColorMode::destroy() { 2953 if(mModeHandle) { 2954 if (fnDeleteInstance) { 2955 fnDeleteInstance(); 2956 } 2957 dlclose(mModeHandle); 2958 mModeHandle = NULL; 2959 } 2960 } 2961 2962 };//namespace qhwc 2963
