/* * Copyright (C) 2011 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include "gralloc_cb.h" #include "HostConnection.h" #include "glUtils.h" #include #include /* Set to 1 or 2 to enable debug traces */ #define DEBUG 0 #if DEBUG >= 1 # define D(...) ALOGD(__VA_ARGS__) #else # define D(...) ((void)0) #endif #if DEBUG >= 2 # define DD(...) ALOGD(__VA_ARGS__) #else # define DD(...) ((void)0) #endif #define DBG_FUNC DBG("%s\n", __FUNCTION__) // // our private gralloc module structure // struct private_module_t { gralloc_module_t base; }; /* If not NULL, this is a pointer to the fallback module. * This really is gralloc.default, which we'll use if we detect * that the emulator we're running in does not support GPU emulation. */ static gralloc_module_t* sFallback; static pthread_once_t sFallbackOnce = PTHREAD_ONCE_INIT; static void fallback_init(void); // forward typedef struct _alloc_list_node { buffer_handle_t handle; _alloc_list_node *next; _alloc_list_node *prev; } AllocListNode; // // Our gralloc device structure (alloc interface) // struct gralloc_device_t { alloc_device_t device; AllocListNode *allocListHead; // double linked list of allocated buffers pthread_mutex_t lock; }; // // Our framebuffer device structure // struct fb_device_t { framebuffer_device_t device; }; static int map_buffer(cb_handle_t *cb, void **vaddr) { if (cb->fd < 0 || cb->ashmemSize <= 0) { return -EINVAL; } void *addr = mmap(0, cb->ashmemSize, PROT_READ | PROT_WRITE, MAP_SHARED, cb->fd, 0); if (addr == MAP_FAILED) { return -errno; } cb->ashmemBase = intptr_t(addr); cb->ashmemBasePid = getpid(); *vaddr = addr; return 0; } #define DEFINE_HOST_CONNECTION \ HostConnection *hostCon = HostConnection::get(); \ renderControl_encoder_context_t *rcEnc = (hostCon ? hostCon->rcEncoder() : NULL) #define DEFINE_AND_VALIDATE_HOST_CONNECTION \ HostConnection *hostCon = HostConnection::get(); \ if (!hostCon) { \ ALOGE("gralloc: Failed to get host connection\n"); \ return -EIO; \ } \ renderControl_encoder_context_t *rcEnc = hostCon->rcEncoder(); \ if (!rcEnc) { \ ALOGE("gralloc: Failed to get renderControl encoder context\n"); \ return -EIO; \ } // // gralloc device functions (alloc interface) // static int gralloc_alloc(alloc_device_t* dev, int w, int h, int format, int usage, buffer_handle_t* pHandle, int* pStride) { D("gralloc_alloc w=%d h=%d usage=0x%x\n", w, h, usage); gralloc_device_t *grdev = (gralloc_device_t *)dev; if (!grdev || !pHandle || !pStride) { ALOGE("gralloc_alloc: Bad inputs (grdev: %p, pHandle: %p, pStride: %p", grdev, pHandle, pStride); return -EINVAL; } // // Note: in screen capture mode, both sw_write and hw_write will be on // and this is a valid usage // bool sw_write = (0 != (usage & GRALLOC_USAGE_SW_WRITE_MASK)); bool hw_write = (usage & GRALLOC_USAGE_HW_RENDER); bool sw_read = (0 != (usage & GRALLOC_USAGE_SW_READ_MASK)); bool hw_cam_write = usage & GRALLOC_USAGE_HW_CAMERA_WRITE; bool hw_cam_read = usage & GRALLOC_USAGE_HW_CAMERA_READ; bool hw_vid_enc_read = usage & GRALLOC_USAGE_HW_VIDEO_ENCODER; // Keep around original requested format for later validation int frameworkFormat = format; // Pick the right concrete pixel format given the endpoints as encoded in // the usage bits. Every end-point pair needs explicit listing here. if (format == HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED) { // Camera as producer if (usage & GRALLOC_USAGE_HW_CAMERA_WRITE) { if (usage & GRALLOC_USAGE_HW_TEXTURE) { // Camera-to-display is RGBA format = HAL_PIXEL_FORMAT_RGBA_8888; } else if (usage & GRALLOC_USAGE_HW_VIDEO_ENCODER) { // Camera-to-encoder is NV21 format = HAL_PIXEL_FORMAT_YCrCb_420_SP; } else if ((usage & GRALLOC_USAGE_HW_CAMERA_MASK) == GRALLOC_USAGE_HW_CAMERA_ZSL) { // Camera-to-ZSL-queue is RGB_888 format = HAL_PIXEL_FORMAT_RGB_888; } } if (format == HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED) { ALOGE("gralloc_alloc: Requested auto format selection, " "but no known format for this usage: %d x %d, usage %x", w, h, usage); return -EINVAL; } } else if (format == HAL_PIXEL_FORMAT_YCbCr_420_888) { // Flexible framework-accessible YUV format; map to NV21 for now if (usage & GRALLOC_USAGE_HW_CAMERA_WRITE) { format = HAL_PIXEL_FORMAT_YCrCb_420_SP; } if (format == HAL_PIXEL_FORMAT_YCbCr_420_888) { ALOGE("gralloc_alloc: Requested YCbCr_420_888, but no known " "specific format for this usage: %d x %d, usage %x", w, h, usage); } } bool yuv_format = false; int ashmem_size = 0; int stride = w; GLenum glFormat = 0; GLenum glType = 0; int bpp = 0; int align = 1; switch (format) { case HAL_PIXEL_FORMAT_RGBA_8888: case HAL_PIXEL_FORMAT_RGBX_8888: case HAL_PIXEL_FORMAT_BGRA_8888: bpp = 4; glFormat = GL_RGBA; glType = GL_UNSIGNED_BYTE; break; case HAL_PIXEL_FORMAT_RGB_888: bpp = 3; glFormat = GL_RGB; glType = GL_UNSIGNED_BYTE; break; case HAL_PIXEL_FORMAT_RGB_565: bpp = 2; glFormat = GL_RGB; glType = GL_UNSIGNED_SHORT_5_6_5; break; case HAL_PIXEL_FORMAT_RAW16: case HAL_PIXEL_FORMAT_Y16: bpp = 2; align = 16*bpp; if (! ((sw_read || hw_cam_read) && (sw_write || hw_cam_write) ) ) { // Raw sensor data or Y16 only goes between camera and CPU return -EINVAL; } // Not expecting to actually create any GL surfaces for this glFormat = GL_LUMINANCE; glType = GL_UNSIGNED_SHORT; break; case HAL_PIXEL_FORMAT_BLOB: bpp = 1; if (! (sw_read && hw_cam_write) ) { // Blob data cannot be used by HW other than camera emulator return -EINVAL; } // Not expecting to actually create any GL surfaces for this glFormat = GL_LUMINANCE; glType = GL_UNSIGNED_BYTE; break; case HAL_PIXEL_FORMAT_YCrCb_420_SP: align = 1; bpp = 1; // per-channel bpp yuv_format = true; // Not expecting to actually create any GL surfaces for this break; case HAL_PIXEL_FORMAT_YV12: align = 16; bpp = 1; // per-channel bpp yuv_format = true; // Not expecting to actually create any GL surfaces for this break; default: ALOGE("gralloc_alloc: Unknown format %d", format); return -EINVAL; } if (usage & GRALLOC_USAGE_HW_FB) { // keep space for postCounter ashmem_size += sizeof(uint32_t); } if (sw_read || sw_write || hw_cam_write || hw_vid_enc_read) { // keep space for image on guest memory if SW access is needed // or if the camera is doing writing if (yuv_format) { size_t yStride = (w*bpp + (align - 1)) & ~(align-1); size_t uvStride = (yStride / 2 + (align - 1)) & ~(align-1); size_t uvHeight = h / 2; ashmem_size += yStride * h + 2 * (uvHeight * uvStride); stride = yStride / bpp; } else { size_t bpr = (w*bpp + (align-1)) & ~(align-1); ashmem_size += (bpr * h); stride = bpr / bpp; } } D("gralloc_alloc format=%d, ashmem_size=%d, stride=%d, tid %d\n", format, ashmem_size, stride, gettid()); // // Allocate space in ashmem if needed // int fd = -1; if (ashmem_size > 0) { // round to page size; ashmem_size = (ashmem_size + (PAGE_SIZE-1)) & ~(PAGE_SIZE-1); fd = ashmem_create_region("gralloc-buffer", ashmem_size); if (fd < 0) { ALOGE("gralloc_alloc failed to create ashmem region: %s\n", strerror(errno)); return -errno; } } cb_handle_t *cb = new cb_handle_t(fd, ashmem_size, usage, w, h, frameworkFormat, format, glFormat, glType); if (ashmem_size > 0) { // // map ashmem region if exist // void *vaddr; int err = map_buffer(cb, &vaddr); if (err) { close(fd); delete cb; return err; } cb->setFd(fd); } // // Allocate ColorBuffer handle on the host (only if h/w access is allowed) // Only do this for some h/w usages, not all. // Also do this if we need to read from the surface, in this case the // rendering will still happen on the host but we also need to be able to // read back from the color buffer, which requires that there is a buffer // if (usage & (GRALLOC_USAGE_HW_TEXTURE | GRALLOC_USAGE_HW_RENDER | GRALLOC_USAGE_HW_2D | GRALLOC_USAGE_HW_COMPOSER | GRALLOC_USAGE_HW_FB | GRALLOC_USAGE_SW_READ_MASK) ) { DEFINE_HOST_CONNECTION; if (hostCon && rcEnc) { cb->hostHandle = rcEnc->rcCreateColorBuffer(rcEnc, w, h, glFormat); D("Created host ColorBuffer 0x%x\n", cb->hostHandle); } if (!cb->hostHandle) { // Could not create colorbuffer on host !!! close(fd); delete cb; return -EIO; } } // // alloc succeeded - insert the allocated handle to the allocated list // AllocListNode *node = new AllocListNode(); pthread_mutex_lock(&grdev->lock); node->handle = cb; node->next = grdev->allocListHead; node->prev = NULL; if (grdev->allocListHead) { grdev->allocListHead->prev = node; } grdev->allocListHead = node; pthread_mutex_unlock(&grdev->lock); *pHandle = cb; if (frameworkFormat == HAL_PIXEL_FORMAT_YCbCr_420_888) { *pStride = 0; } else { *pStride = stride; } return 0; } static int gralloc_free(alloc_device_t* dev, buffer_handle_t handle) { const cb_handle_t *cb = (const cb_handle_t *)handle; if (!cb_handle_t::validate((cb_handle_t*)cb)) { ERR("gralloc_free: invalid handle"); return -EINVAL; } if (cb->hostHandle != 0) { DEFINE_AND_VALIDATE_HOST_CONNECTION; D("Closing host ColorBuffer 0x%x\n", cb->hostHandle); rcEnc->rcCloseColorBuffer(rcEnc, cb->hostHandle); } // // detach and unmap ashmem area if present // if (cb->fd > 0) { if (cb->ashmemSize > 0 && cb->ashmemBase) { munmap((void *)cb->ashmemBase, cb->ashmemSize); } close(cb->fd); } // remove it from the allocated list gralloc_device_t *grdev = (gralloc_device_t *)dev; pthread_mutex_lock(&grdev->lock); AllocListNode *n = grdev->allocListHead; while( n && n->handle != cb ) { n = n->next; } if (n) { // buffer found on list - remove it from list if (n->next) { n->next->prev = n->prev; } if (n->prev) { n->prev->next = n->next; } else { grdev->allocListHead = n->next; } delete n; } pthread_mutex_unlock(&grdev->lock); delete cb; return 0; } static int gralloc_device_close(struct hw_device_t *dev) { gralloc_device_t* d = reinterpret_cast(dev); if (d) { // free still allocated buffers while( d->allocListHead != NULL ) { gralloc_free(&d->device, d->allocListHead->handle); } // free device free(d); } return 0; } static int fb_compositionComplete(struct framebuffer_device_t* dev) { (void)dev; return 0; } // // Framebuffer device functions // static int fb_post(struct framebuffer_device_t* dev, buffer_handle_t buffer) { fb_device_t *fbdev = (fb_device_t *)dev; cb_handle_t *cb = (cb_handle_t *)buffer; if (!fbdev || !cb_handle_t::validate(cb) || !cb->canBePosted()) { return -EINVAL; } // Make sure we have host connection DEFINE_AND_VALIDATE_HOST_CONNECTION; // increment the post count of the buffer intptr_t *postCountPtr = (intptr_t *)cb->ashmemBase; if (!postCountPtr) { // This should not happen return -EINVAL; } (*postCountPtr)++; // send post request to host rcEnc->rcFBPost(rcEnc, cb->hostHandle); hostCon->flush(); return 0; } static int fb_setUpdateRect(struct framebuffer_device_t* dev, int l, int t, int w, int h) { fb_device_t *fbdev = (fb_device_t *)dev; (void)l; (void)t; (void)w; (void)h; if (!fbdev) { return -EINVAL; } // Make sure we have host connection DEFINE_AND_VALIDATE_HOST_CONNECTION; // send request to host // TODO: XXX - should be implemented //rcEnc->rc_XXX return 0; } static int fb_setSwapInterval(struct framebuffer_device_t* dev, int interval) { fb_device_t *fbdev = (fb_device_t *)dev; if (!fbdev) { return -EINVAL; } // Make sure we have host connection DEFINE_AND_VALIDATE_HOST_CONNECTION; // send request to host rcEnc->rcFBSetSwapInterval(rcEnc, interval); hostCon->flush(); return 0; } static int fb_close(struct hw_device_t *dev) { fb_device_t *fbdev = (fb_device_t *)dev; delete fbdev; return 0; } // // gralloc module functions - refcount + locking interface // static int gralloc_register_buffer(gralloc_module_t const* module, buffer_handle_t handle) { pthread_once(&sFallbackOnce, fallback_init); if (sFallback != NULL) { return sFallback->registerBuffer(sFallback, handle); } D("gralloc_register_buffer(%p) called", handle); private_module_t *gr = (private_module_t *)module; cb_handle_t *cb = (cb_handle_t *)handle; if (!gr || !cb_handle_t::validate(cb)) { ERR("gralloc_register_buffer(%p): invalid buffer", cb); return -EINVAL; } if (cb->hostHandle != 0) { DEFINE_AND_VALIDATE_HOST_CONNECTION; D("Opening host ColorBuffer 0x%x\n", cb->hostHandle); rcEnc->rcOpenColorBuffer2(rcEnc, cb->hostHandle); } // // if the color buffer has ashmem region and it is not mapped in this // process map it now. // if (cb->ashmemSize > 0 && cb->mappedPid != getpid()) { void *vaddr; int err = map_buffer(cb, &vaddr); if (err) { ERR("gralloc_register_buffer(%p): map failed: %s", cb, strerror(-err)); return -err; } cb->mappedPid = getpid(); } return 0; } static int gralloc_unregister_buffer(gralloc_module_t const* module, buffer_handle_t handle) { if (sFallback != NULL) { return sFallback->unregisterBuffer(sFallback, handle); } private_module_t *gr = (private_module_t *)module; cb_handle_t *cb = (cb_handle_t *)handle; if (!gr || !cb_handle_t::validate(cb)) { ERR("gralloc_unregister_buffer(%p): invalid buffer", cb); return -EINVAL; } if (cb->hostHandle != 0) { DEFINE_AND_VALIDATE_HOST_CONNECTION; D("Closing host ColorBuffer 0x%x\n", cb->hostHandle); rcEnc->rcCloseColorBuffer(rcEnc, cb->hostHandle); } // // unmap ashmem region if it was previously mapped in this process // (through register_buffer) // if (cb->ashmemSize > 0 && cb->mappedPid == getpid()) { void *vaddr; int err = munmap((void *)cb->ashmemBase, cb->ashmemSize); if (err) { ERR("gralloc_unregister_buffer(%p): unmap failed", cb); return -EINVAL; } cb->ashmemBase = 0; cb->mappedPid = 0; } D("gralloc_unregister_buffer(%p) done\n", cb); return 0; } static int gralloc_lock(gralloc_module_t const* module, buffer_handle_t handle, int usage, int l, int t, int w, int h, void** vaddr) { if (sFallback != NULL) { return sFallback->lock(sFallback, handle, usage, l, t, w, h, vaddr); } private_module_t *gr = (private_module_t *)module; cb_handle_t *cb = (cb_handle_t *)handle; if (!gr || !cb_handle_t::validate(cb)) { ALOGE("gralloc_lock bad handle\n"); return -EINVAL; } // validate format if (cb->frameworkFormat == HAL_PIXEL_FORMAT_YCbCr_420_888) { ALOGE("gralloc_lock can't be used with YCbCr_420_888 format"); return -EINVAL; } // Validate usage, // 1. cannot be locked for hw access // 2. lock for either sw read or write. // 3. locked sw access must match usage during alloc time. bool sw_read = (0 != (usage & GRALLOC_USAGE_SW_READ_MASK)); bool sw_write = (0 != (usage & GRALLOC_USAGE_SW_WRITE_MASK)); bool hw_read = (usage & GRALLOC_USAGE_HW_TEXTURE); bool hw_write = (usage & GRALLOC_USAGE_HW_RENDER); bool hw_vid_enc_read = (usage & GRALLOC_USAGE_HW_VIDEO_ENCODER); bool hw_cam_write = (usage & GRALLOC_USAGE_HW_CAMERA_WRITE); bool hw_cam_read = (usage & GRALLOC_USAGE_HW_CAMERA_READ); bool sw_read_allowed = (0 != (cb->usage & GRALLOC_USAGE_SW_READ_MASK)); bool sw_write_allowed = (0 != (cb->usage & GRALLOC_USAGE_SW_WRITE_MASK)); if ( (hw_read || hw_write) || (!sw_read && !sw_write && !hw_cam_write && !hw_cam_read && !hw_vid_enc_read) || (sw_read && !sw_read_allowed) || (sw_write && !sw_write_allowed) ) { ALOGE("gralloc_lock usage mismatch usage=0x%x cb->usage=0x%x\n", usage, cb->usage); return -EINVAL; } intptr_t postCount = 0; void *cpu_addr = NULL; // // make sure ashmem area is mapped if needed // if (cb->canBePosted() || sw_read || sw_write || hw_cam_write || hw_cam_read || hw_vid_enc_read) { if (cb->ashmemBasePid != getpid() || !cb->ashmemBase) { return -EACCES; } if (cb->canBePosted()) { postCount = *((intptr_t *)cb->ashmemBase); cpu_addr = (void *)(cb->ashmemBase + sizeof(intptr_t)); } else { cpu_addr = (void *)(cb->ashmemBase); } } if (cb->hostHandle) { // Make sure we have host connection DEFINE_AND_VALIDATE_HOST_CONNECTION; // // flush color buffer write cache on host and get its sync status. // int hostSyncStatus = rcEnc->rcColorBufferCacheFlush(rcEnc, cb->hostHandle, postCount, sw_read); if (hostSyncStatus < 0) { // host failed the color buffer sync - probably since it was already // locked for write access. fail the lock. ALOGE("gralloc_lock cacheFlush failed postCount=%d sw_read=%d\n", postCount, sw_read); return -EBUSY; } if (sw_read) { D("gralloc_lock read back color buffer %d %d\n", cb->width, cb->height); rcEnc->rcReadColorBuffer(rcEnc, cb->hostHandle, 0, 0, cb->width, cb->height, cb->glFormat, cb->glType, cpu_addr); } } // // is virtual address required ? // if (sw_read || sw_write || hw_cam_write || hw_cam_read || hw_vid_enc_read) { *vaddr = cpu_addr; } if (sw_write || hw_cam_write) { // // Keep locked region if locked for s/w write access. // cb->lockedLeft = l; cb->lockedTop = t; cb->lockedWidth = w; cb->lockedHeight = h; } DD("gralloc_lock success. vaddr: %p, *vaddr: %p, usage: %x, cpu_addr: %p", vaddr, vaddr ? *vaddr : 0, usage, cpu_addr); return 0; } static int gralloc_unlock(gralloc_module_t const* module, buffer_handle_t handle) { if (sFallback != NULL) { return sFallback->unlock(sFallback, handle); } private_module_t *gr = (private_module_t *)module; cb_handle_t *cb = (cb_handle_t *)handle; if (!gr || !cb_handle_t::validate(cb)) { return -EINVAL; } // // if buffer was locked for s/w write, we need to update the host with // the updated data // if (cb->hostHandle) { // Make sure we have host connection DEFINE_AND_VALIDATE_HOST_CONNECTION; void *cpu_addr; if (cb->canBePosted()) { cpu_addr = (void *)(cb->ashmemBase + sizeof(int)); } else { cpu_addr = (void *)(cb->ashmemBase); } if (cb->lockedWidth < cb->width || cb->lockedHeight < cb->height) { int bpp = glUtilsPixelBitSize(cb->glFormat, cb->glType) >> 3; char *tmpBuf = new char[cb->lockedWidth * cb->lockedHeight * bpp]; int dst_line_len = cb->lockedWidth * bpp; int src_line_len = cb->width * bpp; char *src = (char *)cpu_addr + cb->lockedTop*src_line_len + cb->lockedLeft*bpp; char *dst = tmpBuf; for (int y=0; ylockedHeight; y++) { memcpy(dst, src, dst_line_len); src += src_line_len; dst += dst_line_len; } rcEnc->rcUpdateColorBuffer(rcEnc, cb->hostHandle, cb->lockedLeft, cb->lockedTop, cb->lockedWidth, cb->lockedHeight, cb->glFormat, cb->glType, tmpBuf); delete [] tmpBuf; } else { rcEnc->rcUpdateColorBuffer(rcEnc, cb->hostHandle, 0, 0, cb->width, cb->height, cb->glFormat, cb->glType, cpu_addr); } } cb->lockedWidth = cb->lockedHeight = 0; return 0; } static int gralloc_lock_ycbcr(gralloc_module_t const* module, buffer_handle_t handle, int usage, int l, int t, int w, int h, android_ycbcr *ycbcr) { // Not supporting fallback module for YCbCr if (sFallback != NULL) { return -EINVAL; } if (!ycbcr) { ALOGE("gralloc_lock_ycbcr got NULL ycbcr struct"); return -EINVAL; } private_module_t *gr = (private_module_t *)module; cb_handle_t *cb = (cb_handle_t *)handle; if (!gr || !cb_handle_t::validate(cb)) { ALOGE("gralloc_lock_ycbcr bad handle\n"); return -EINVAL; } if (cb->frameworkFormat != HAL_PIXEL_FORMAT_YCbCr_420_888) { ALOGE("gralloc_lock_ycbcr can only be used with " "HAL_PIXEL_FORMAT_YCbCr_420_888, got %x instead", cb->frameworkFormat); return -EINVAL; } // Validate usage // For now, only allow camera write, software read. bool sw_read = (0 != (usage & GRALLOC_USAGE_SW_READ_MASK)); bool hw_cam_write = (usage & GRALLOC_USAGE_HW_CAMERA_WRITE); bool sw_read_allowed = (0 != (cb->usage & GRALLOC_USAGE_SW_READ_MASK)); if ( (!hw_cam_write && !sw_read) || (sw_read && !sw_read_allowed) ) { ALOGE("gralloc_lock_ycbcr usage mismatch usage:0x%x cb->usage:0x%x\n", usage, cb->usage); return -EINVAL; } // Make sure memory is mapped, get address if (cb->ashmemBasePid != getpid() || !cb->ashmemBase) { return -EACCES; } uint8_t *cpu_addr = NULL; if (cb->canBePosted()) { cpu_addr = (uint8_t *)(cb->ashmemBase + sizeof(int)); } else { cpu_addr = (uint8_t *)(cb->ashmemBase); } // Calculate offsets to underlying YUV data size_t yStride; size_t cStride; size_t yOffset; size_t uOffset; size_t vOffset; size_t cStep; switch (cb->format) { case HAL_PIXEL_FORMAT_YCrCb_420_SP: yStride = cb->width; cStride = cb->width; yOffset = 0; vOffset = yStride * cb->height; uOffset = vOffset + 1; cStep = 2; break; default: ALOGE("gralloc_lock_ycbcr unexpected internal format %x", cb->format); return -EINVAL; } ycbcr->y = cpu_addr + yOffset; ycbcr->cb = cpu_addr + uOffset; ycbcr->cr = cpu_addr + vOffset; ycbcr->ystride = yStride; ycbcr->cstride = cStride; ycbcr->chroma_step = cStep; // Zero out reserved fields memset(ycbcr->reserved, 0, sizeof(ycbcr->reserved)); // // Keep locked region if locked for s/w write access. // cb->lockedLeft = l; cb->lockedTop = t; cb->lockedWidth = w; cb->lockedHeight = h; DD("gralloc_lock_ycbcr success. usage: %x, ycbcr.y: %p, .cb: %p, .cr: %p, " ".ystride: %d , .cstride: %d, .chroma_step: %d", usage, ycbcr->y, ycbcr->cb, ycbcr->cr, ycbcr->ystride, ycbcr->cstride, ycbcr->chroma_step); return 0; } static int gralloc_device_open(const hw_module_t* module, const char* name, hw_device_t** device) { int status = -EINVAL; D("gralloc_device_open %s\n", name); pthread_once( &sFallbackOnce, fallback_init ); if (sFallback != NULL) { return sFallback->common.methods->open(&sFallback->common, name, device); } if (!strcmp(name, GRALLOC_HARDWARE_GPU0)) { // Create host connection and keep it in the TLS. // return error if connection with host can not be established HostConnection *hostCon = HostConnection::get(); if (!hostCon) { ALOGE("gralloc: failed to get host connection while opening %s\n", name); return -EIO; } // // Allocate memory for the gralloc device (alloc interface) // gralloc_device_t *dev; dev = (gralloc_device_t*)malloc(sizeof(gralloc_device_t)); if (NULL == dev) { return -ENOMEM; } // Initialize our device structure // dev->device.common.tag = HARDWARE_DEVICE_TAG; dev->device.common.version = 0; dev->device.common.module = const_cast(module); dev->device.common.close = gralloc_device_close; dev->device.alloc = gralloc_alloc; dev->device.free = gralloc_free; dev->allocListHead = NULL; pthread_mutex_init(&dev->lock, NULL); *device = &dev->device.common; status = 0; } else if (!strcmp(name, GRALLOC_HARDWARE_FB0)) { // return error if connection with host can not be established DEFINE_AND_VALIDATE_HOST_CONNECTION; // // Query the host for Framebuffer attributes // D("gralloc: query Frabuffer attribs\n"); EGLint width = rcEnc->rcGetFBParam(rcEnc, FB_WIDTH); D("gralloc: width=%d\n", width); EGLint height = rcEnc->rcGetFBParam(rcEnc, FB_HEIGHT); D("gralloc: height=%d\n", height); EGLint xdpi = rcEnc->rcGetFBParam(rcEnc, FB_XDPI); D("gralloc: xdpi=%d\n", xdpi); EGLint ydpi = rcEnc->rcGetFBParam(rcEnc, FB_YDPI); D("gralloc: ydpi=%d\n", ydpi); EGLint fps = rcEnc->rcGetFBParam(rcEnc, FB_FPS); D("gralloc: fps=%d\n", fps); EGLint min_si = rcEnc->rcGetFBParam(rcEnc, FB_MIN_SWAP_INTERVAL); D("gralloc: min_swap=%d\n", min_si); EGLint max_si = rcEnc->rcGetFBParam(rcEnc, FB_MAX_SWAP_INTERVAL); D("gralloc: max_swap=%d\n", max_si); // // Allocate memory for the framebuffer device // fb_device_t *dev; dev = (fb_device_t*)malloc(sizeof(fb_device_t)); if (NULL == dev) { return -ENOMEM; } memset(dev, 0, sizeof(fb_device_t)); // Initialize our device structure // dev->device.common.tag = HARDWARE_DEVICE_TAG; dev->device.common.version = 0; dev->device.common.module = const_cast(module); dev->device.common.close = fb_close; dev->device.setSwapInterval = fb_setSwapInterval; dev->device.post = fb_post; dev->device.setUpdateRect = 0; //fb_setUpdateRect; dev->device.compositionComplete = fb_compositionComplete; //XXX: this is a dummy const_cast(dev->device.flags) = 0; const_cast(dev->device.width) = width; const_cast(dev->device.height) = height; const_cast(dev->device.stride) = width; const_cast(dev->device.format) = HAL_PIXEL_FORMAT_RGBA_8888; const_cast(dev->device.xdpi) = xdpi; const_cast(dev->device.ydpi) = ydpi; const_cast(dev->device.fps) = fps; const_cast(dev->device.minSwapInterval) = min_si; const_cast(dev->device.maxSwapInterval) = max_si; *device = &dev->device.common; status = 0; } return status; } // // define the HMI symbol - our module interface // static struct hw_module_methods_t gralloc_module_methods = { open: gralloc_device_open }; struct private_module_t HAL_MODULE_INFO_SYM = { base: { common: { tag: HARDWARE_MODULE_TAG, module_api_version: GRALLOC_MODULE_API_VERSION_0_2, hal_api_version: 0, id: GRALLOC_HARDWARE_MODULE_ID, name: "Graphics Memory Allocator Module", author: "The Android Open Source Project", methods: &gralloc_module_methods, dso: NULL, reserved: {0, } }, registerBuffer: gralloc_register_buffer, unregisterBuffer: gralloc_unregister_buffer, lock: gralloc_lock, unlock: gralloc_unlock, perform: NULL, lock_ycbcr: gralloc_lock_ycbcr, } }; /* This function is called once to detect whether the emulator supports * GPU emulation (this is done by looking at the qemu.gles kernel * parameter, which must be == 1 if this is the case). * * If not, then load gralloc.default instead as a fallback. */ static void fallback_init(void) { char prop[PROPERTY_VALUE_MAX]; void* module; // qemu.gles=0 -> no GLES 2.x support (only 1.x through software). // qemu.gles=1 -> host-side GPU emulation through EmuGL // qemu.gles=2 -> guest-side GPU emulation. property_get("ro.kernel.qemu.gles", prop, "0"); if (atoi(prop) == 1) { return; } ALOGD("Emulator without host-side GPU emulation detected."); #if __LP64__ module = dlopen("/system/lib64/hw/gralloc.default.so", RTLD_LAZY|RTLD_LOCAL); #else module = dlopen("/system/lib/hw/gralloc.default.so", RTLD_LAZY|RTLD_LOCAL); #endif if (module != NULL) { sFallback = reinterpret_cast(dlsym(module, HAL_MODULE_INFO_SYM_AS_STR)); if (sFallback == NULL) { dlclose(module); } } if (sFallback == NULL) { ALOGE("Could not find software fallback module!?"); } }