Android Camera HAL3中預覽preview模式下的數據流

 

前沿：

為了更好的梳理preview下buffer數據流的操作過程，前一文中對surface下的buffer相關的操作架構進行了描述。本文主要以此為基礎，重點分析再Camera2Client和Camera3Device下是如何維護並讀寫這些視頻幀緩存的。

 

1. Camera3Device::convertMetadataListToRequestListLocked函數

結合上一博文中關於preview的控制流，定位到數據流主要的操作主要是對preview模式下將CameraMetadata mPreviewRequest轉換為CaptureRequest的過程之中，回顧到mPreviewRequest是主要包含了當前preview下所需要Camera3Device來操作的OutputStream的index值。

 

2. Camera3Device::configureStreamsLocked函數

在configureStreamsLocked的函數中，主要關注的是Camera3Device對當前所具有的所有的mInputStreams和mOutputStreams進行Config的操作，分別包括startConfiguration/finishConfiguration兩個狀態。

 

2.1 mOutputStreams.editValueAt(i)->startConfiguration()

這裡的遍歷所有輸出stream即最終調用的函數入口為Camera3Stream::startConfiguration()，這裡需要先看下Camera3OutputStream的整個結構，出現了Camera3Stream和Camera3IOStreamBase，兩者是Input和Output stream所共有的，前者提供的更多的是對buffer的config、get/retrun buffer的操作，後者以維護當前的stream所擁有的buffer數目。另一個支路camera3_stream_t是一個和Camera HAL3底層進行stream信息交互的入口。

startConfiguration函數首先是判斷當前stream的狀態，對於已經config的不作處理，config的主要操作是getEndpointUsage：

status_t Camera3OutputStream::getEndpointUsage(uint32_t *usage) {

    status_t res;
    int32_t u = 0;
    res = mConsumer->query(mConsumer.get(),
            NATIVE_WINDOW_CONSUMER_USAGE_BITS, &u);
    *usage = u;

    return res;
}

這裡的mConsumer其實就是之前創建的Surface的本體，每一個Stream在建立時createStream，都會傳入一個ANativeWIndow類似的Consumer綁定到當前的stream中去。這裡主要是完成當前window所管理的buffer的USAGE值，可參看grallo.h中的定義，由Gralloc模塊負責指定當前buffer操作是由HW還是SW來完成以及不同的應用場合，在Gralloc模塊中不同模塊需求的buffer亦會有不同的分配、定義與處理方式：

 

 

    /* buffer will be used as an OpenGL ES texture */
    GRALLOC_USAGE_HW_TEXTURE            = 0x00000100,
    /* buffer will be used as an OpenGL ES render target */
    GRALLOC_USAGE_HW_RENDER             = 0x00000200,
    /* buffer will be used by the 2D hardware blitter */
    GRALLOC_USAGE_HW_2D                 = 0x00000400,
    /* buffer will be used by the HWComposer HAL module */
    GRALLOC_USAGE_HW_COMPOSER           = 0x00000800,
    /* buffer will be used with the framebuffer device */
    GRALLOC_USAGE_HW_FB                 = 0x00001000,
    /* buffer will be used with the HW video encoder */
    GRALLOC_USAGE_HW_VIDEO_ENCODER      = 0x00010000,
    /* buffer will be written by the HW camera pipeline */
    GRALLOC_USAGE_HW_CAMERA_WRITE       = 0x00020000,
    /* buffer will be read by the HW camera pipeline */
    GRALLOC_USAGE_HW_CAMERA_READ        = 0x00040000,
    /* buffer will be used as part of zero-shutter-lag queue */
    GRALLOC_USAGE_HW_CAMERA_ZSL         = 0x00060000,
    /* mask for the camera access values */
    GRALLOC_USAGE_HW_CAMERA_MASK        = 0x00060000,
    /* mask for the software usage bit-mask */
    GRALLOC_USAGE_HW_MASK               = 0x00071F00,

 

2.2 mHal3Device->ops->configure_streams(mHal3Device, &config);

config是一個camera3_stream_configuration數據結構，他記錄了一次和HAL3交互的stream的數量，已經當前每一個stream的屬性配置相關的信息camer3_stream_t，包括stream中每一個buffer的屬性值，stream的類型值等等，提交這些信息供hal3去分析處理。在高通平台中你可以看到，對於每一個stream在HAL3平台下均以一個Channel的形式存在。

typedef struct camera3_stream_configuration {
    uint32_t num_streams;
    camera3_stream_t **streams;
} camera3_stream_configuration_t;

 

stream_type包括：CAMERA3_STREAM_OUTPUT、CAMERA3_STREAM_INPUT、CAMERA3_STREAM_BIDIRECTIONAL。

format主要是指當前buffer支持的像素點存儲格式，以HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED居多，表明數據格式是由Gralloc模塊來決定的。

對於HAL3中對configureStreams接口的實現會放在後續介紹高通平台的實現機制時再做分析。

 

2.3 Camera3Stream::finishConfiguration

該函數主要執行configureQueueLocked和registerBuffersLocked兩個函數

 

status_t Camera3OutputStream::configureQueueLocked() {
    status_t res;

    mTraceFirstBuffer = true;
    if ((res = Camera3IOStreamBase::configureQueueLocked()) != OK) {
        return res;
    }

    ALOG_ASSERT(mConsumer != 0, mConsumer should never be NULL);

    // Configure consumer-side ANativeWindow interface
    res = native_window_api_connect(mConsumer.get(),
            NATIVE_WINDOW_API_CAMERA);
    if (res != OK) {
        ALOGE(%s: Unable to connect to native window for stream %d,
                __FUNCTION__, mId);
        return res;
    }

    res = native_window_set_usage(mConsumer.get(), camera3_stream::usage);
    if (res != OK) {
        ALOGE(%s: Unable to configure usage %08x for stream %d,
                __FUNCTION__, camera3_stream::usage, mId);
        return res;
    }

    res = native_window_set_scaling_mode(mConsumer.get(),
            NATIVE_WINDOW_SCALING_MODE_SCALE_TO_WINDOW);
    if (res != OK) {
        ALOGE(%s: Unable to configure stream scaling: %s (%d),
                __FUNCTION__, strerror(-res), res);
        return res;
    }

    if (mMaxSize == 0) {
        // For buffers of known size
        res = native_window_set_buffers_dimensions(mConsumer.get(),
                camera3_stream::width, camera3_stream::height);
    } else {
        // For buffers with bounded size
        res = native_window_set_buffers_dimensions(mConsumer.get(),
                mMaxSize, 1);
    }
    if (res != OK) {
        ALOGE(%s: Unable to configure stream buffer dimensions
                 %d x %d (maxSize %zu) for stream %d,
                __FUNCTION__, camera3_stream::width, camera3_stream::height,
                mMaxSize, mId);
        return res;
    }
    res = native_window_set_buffers_format(mConsumer.get(),
            camera3_stream::format);
    if (res != OK) {
        ALOGE(%s: Unable to configure stream buffer format %#x for stream %d,
                __FUNCTION__, camera3_stream::format, mId);
        return res;
    }

    int maxConsumerBuffers;
    res = mConsumer->query(mConsumer.get(),
            NATIVE_WINDOW_MIN_UNDEQUEUED_BUFFERS, &maxConsumerBuffers);//支持的最大buffer數量
    if (res != OK) {
        ALOGE(%s: Unable to query consumer undequeued
                 buffer count for stream %d, __FUNCTION__, mId);
        return res;
    }

    ALOGV(%s: Consumer wants %d buffers, HAL wants %d, __FUNCTION__,
            maxConsumerBuffers, camera3_stream::max_buffers);
    if (camera3_stream::max_buffers == 0) {
        ALOGE(%s: Camera HAL requested max_buffer count: %d, requires at least 1,
                __FUNCTION__, camera3_stream::max_buffers);
        return INVALID_OPERATION;
    }

    mTotalBufferCount = maxConsumerBuffers + camera3_stream::max_buffers;//至少2個buffer
    mHandoutTotalBufferCount = 0;
    mFrameCount = 0;
    mLastTimestamp = 0;

    res = native_window_set_buffer_count(mConsumer.get(),
            mTotalBufferCount);
    if (res != OK) {
        ALOGE(%s: Unable to set buffer count for stream %d,
                __FUNCTION__, mId);
        return res;
    }

    res = native_window_set_buffers_transform(mConsumer.get(),
            mTransform);
    if (res != OK) {
        ALOGE(%s: Unable to configure stream transform to %x: %s (%d),
                __FUNCTION__, mTransform, strerror(-res), res);
    }

    return OK;
}

如果你對SurfaceFlinger的架構熟悉的話，該代碼會相對比較好理解。本質是根據當前stream設置的buffer屬性，將這些屬性值通過ANativeWindow這個接口傳遞給Consumer側去維護：

 

這裡重點關注以下幾個buffer的相關屬性信息：

比如native_window_set_buffer_count是設置當前Window所需要的buffer數目：

總的當前stream下的buffer個數總數為mTotalBufferCount = maxConsumerBuffers + camera3_stream::max_buffers。其中camera3_stream::max_buffer需要的buffer總數由configureStreams時HAL3底層的Device來決定的，高通平台下定義的camera3_stream::max_buffer數為7個，而maxConsumerBuffers指的是在所有buffer被dequeue時還應該保留的處於queue操作的buffer個數，即全dequeue時至少有maxConsumerBuffers個buffer是處於queue狀態在被Consumer使用的。通過query NATIVE_WINDOW_MIN_UNDEQUEUED_BUFFERS來完成，一般默認是1個，即每個stream可以認為需要由8個buffer緩存塊組成，實際可dequeue的為8個。

比如native_window_set_buffers_transform一般是指定buffer的Consumer，即當前buffer顯示的90/180/270°角度。

 

該過程本質是結合HAL3的底層buffer配置需求，反過來請求Buffer的Consumer端BufferQueueConsumer來設置相關的buffer屬性。

 

registerBuffersLocked是一個比較重要的處理過程：

 

status_t Camera3Stream::registerBuffersLocked(camera3_device *hal3Device) {
    ATRACE_CALL();

    /**
     * >= CAMERA_DEVICE_API_VERSION_3_2:
     *
     * camera3_device_t->ops->register_stream_buffers() is not called and must
     * be NULL.
     */
    if (hal3Device->common.version >= CAMERA_DEVICE_API_VERSION_3_2) {
        ALOGV(%s: register_stream_buffers unused as of HAL3.2, __FUNCTION__);

        if (hal3Device->ops->register_stream_buffers != NULL) {
            ALOGE(%s: register_stream_buffers is deprecated in HAL3.2; 
                    must be set to NULL in camera3_device::ops, __FUNCTION__);
            return INVALID_OPERATION;
        } else {
            ALOGD(%s: Skipping NULL check for deprecated register_stream_buffers, __FUNCTION__);
        }

        return OK;
    } else {
        ALOGV(%s: register_stream_buffers using deprecated code path, __FUNCTION__);
    }

    status_t res;

    size_t bufferCount = getBufferCountLocked();//獲取buffer的數量,mTotalBufferCount，最少2個buffer

    Vector buffers;
    buffers.insertAt(/*prototype_item*/NULL, /*index*/0, bufferCount);

    camera3_stream_buffer_set bufferSet = camera3_stream_buffer_set();
    bufferSet.stream = this;//新的bufferset指向camera3_stream_t
    bufferSet.num_buffers = bufferCount;//當前stream下的buffer數
    bufferSet.buffers = buffers.editArray();

    Vector streamBuffers;
    streamBuffers.insertAt(camera3_stream_buffer_t(), /*index*/0, bufferCount);

    // Register all buffers with the HAL. This means getting all the buffers
    // from the stream, providing them to the HAL with the
    // register_stream_buffers() method, and then returning them back to the
    // stream in the error state, since they won't have valid data.
    //
    // Only registered buffers can be sent to the HAL.

    uint32_t bufferIdx = 0;
    for (; bufferIdx < bufferCount; bufferIdx++) {
        res = getBufferLocked( &streamBuffers.editItemAt(bufferIdx) );//返回dequeue buffer出來的所有buffer
        if (res != OK) {
            ALOGE(%s: Unable to get buffer %d for registration with HAL,
                    __FUNCTION__, bufferIdx);
            // Skip registering, go straight to cleanup
            break;
        }

        sp fence = new Fence(streamBuffers[bufferIdx].acquire_fence);
        fence->waitForever(Camera3Stream::registerBuffers);//等待可寫

        buffers.editItemAt(bufferIdx) = streamBuffers[bufferIdx].buffer;//dequeue buffer出來的buffer handle
    }
    if (bufferIdx == bufferCount) {
        // Got all buffers, register with HAL
        ALOGV(%s: Registering %zu buffers with camera HAL,
                __FUNCTION__, bufferCount);
        ATRACE_BEGIN(camera3->register_stream_buffers);
        res = hal3Device->ops->register_stream_buffers(hal3Device,
                &bufferSet);//buffer綁定並register到hal層
        ATRACE_END();
    }

    // Return all valid buffers to stream, in ERROR state to indicate
    // they weren't filled.
    for (size_t i = 0; i < bufferIdx; i++) {
        streamBuffers.editItemAt(i).release_fence = -1;
        streamBuffers.editItemAt(i).status = CAMERA3_BUFFER_STATUS_ERROR;
        returnBufferLocked(streamBuffers[i], 0);//register後進行queue buffer
    }

    return res;
}

 

a 可以明確看到CAMERA_DEVICE_API_VERSION_3_2的版本才支持這個Device ops接口

b getBufferCountLocked

獲取當前stream下的允許的buffer總數

c camera3_stream_buffer_t、camera3_stream_buffer_set和buffer_handle_t

 

首先需要關注的結構是camera3_stream_buffer_t，用於描述每一個stream下的buffer自身的特性值，其中關鍵結構是buffer_handle_t值是每一個buffer在不同進程間共享的handle，此外acquire_fence和release_fence用來不同硬件模塊對buffer讀寫時的同步。

 

camera3_stream_buffer_set是封裝了當前stream下所有的buffer的信息：

 

typedef struct camera3_stream_buffer_set {
    /**
     * The stream handle for the stream these buffers belong to
     */
    camera3_stream_t *stream;
    /**
     * The number of buffers in this stream. It is guaranteed to be at least
     * stream->max_buffers.
     */
    uint32_t num_buffers;
    /**
     * The array of gralloc buffer handles for this stream. If the stream format
     * is set to HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED, the camera HAL device
     * should inspect the passed-in buffers to determine any platform-private
     * pixel format information.
     */
    buffer_handle_t **buffers;

} camera3_stream_buffer_set_t;

三個變量分別保存stream的buffer個數，當前這個set集合所屬的stream，以及他所包含的所有buffer的handle信息列表。

 

 

d getBufferLocked獲取當前buffer

 

status_t Camera3OutputStream::getBufferLocked(camera3_stream_buffer *buffer) {
    ATRACE_CALL();
    status_t res;

    if ((res = getBufferPreconditionCheckLocked()) != OK) {
        return res;
    }

    ANativeWindowBuffer* anb;
    int fenceFd;

    /**
     * Release the lock briefly to avoid deadlock for below scenario:
     * Thread 1: StreamingProcessor::startStream -> Camera3Stream::isConfiguring().
     * This thread acquired StreamingProcessor lock and try to lock Camera3Stream lock.
     * Thread 2: Camera3Stream::returnBuffer->StreamingProcessor::onFrameAvailable().
     * This thread acquired Camera3Stream lock and bufferQueue lock, and try to lock
     * StreamingProcessor lock.
     * Thread 3: Camera3Stream::getBuffer(). This thread acquired Camera3Stream lock
     * and try to lock bufferQueue lock.
     * Then there is circular locking dependency.
     */
    sp currentConsumer = mConsumer;
    mLock.unlock();

    res = currentConsumer->dequeueBuffer(currentConsumer.get(), &anb, &fenceFd);
    mLock.lock();
    if (res != OK) {
        ALOGE(%s: Stream %d: Can't dequeue next output buffer: %s (%d),
                __FUNCTION__, mId, strerror(-res), res);
        return res;
    }

    /**
     * FenceFD now owned by HAL except in case of error,
     * in which case we reassign it to acquire_fence
     */
    handoutBufferLocked(*buffer, &(anb->handle), /*acquireFence*/fenceFd,
                        /*releaseFence*/-1, CAMERA3_BUFFER_STATUS_OK, /*output*/true);

    return OK;
}

該函數主要是從由ANativeWindow從Consumer端dequeue獲取一個buffer，本質上這個過程中首次執行是會有Consumer端去分配一個由實際物理空間的給當前的一個buffer的。

 

接著執行handoutBufferLocked，填充camera3_stream_buffer這個結構體，其中設置的acquireFence為-1值表明hal3的這個buffer可被Framewrok直接使用，而acquireFence表示HAL3如何想使用這個buffer時需要等待其變為1，因為buffer分配和handler返回不一定是一致同步的。還會切換當前buffer的狀態CAMERA3_BUFFER_STATUS_OK。

 

void Camera3IOStreamBase::handoutBufferLocked(camera3_stream_buffer &buffer,
                                              buffer_handle_t *handle,
                                              int acquireFence,
                                              int releaseFence,
                                              camera3_buffer_status_t status,
                                              bool output) {
    /**
     * Note that all fences are now owned by HAL.
     */

    // Handing out a raw pointer to this object. Increment internal refcount.
    incStrong(this);
    buffer.stream = this;
    buffer.buffer = handle;
    buffer.acquire_fence = acquireFence;
    buffer.release_fence = releaseFence;
    buffer.status = status;

    // Inform tracker about becoming busy
    if (mHandoutTotalBufferCount == 0 && mState != STATE_IN_CONFIG &&
            mState != STATE_IN_RECONFIG) {
        /**
         * Avoid a spurious IDLE->ACTIVE->IDLE transition when using buffers
         * before/after register_stream_buffers during initial configuration
         * or re-configuration.
         *
         * TODO: IN_CONFIG and IN_RECONFIG checks only make sense for  statusTracker = mStatusTracker.promote();
        if (statusTracker != 0) {
            statusTracker->markComponentActive(mStatusId);
        }
    }
    mHandoutTotalBufferCount++;//統計dequeuebuffer的數量

    if (output) {
        mHandoutOutputBufferCount++;
    }
}

 

e hal3Device->ops->register_stream_buffers(hal3Device,&bufferSet);//buffer綁定並register到hal層

將所屬的stream下的所有buffer有關的信息，主要是每個buffer的buffer_handle_t值，交給HAL3層去實現。比如高通HAL3平台每一個Channel對應於Camera3Device端的stream，而每一個stream的buffer在不同的Channel下面卻是一個個的stream，這是高通的實現方式。

 

f 在完成register所有buffer後，設置每一個buffer狀態為從CAMERA3_BUFFER_STATUS_OK切換到CAMERA3_BUFFER_STATUS_ERROR表明這個buffer都是可用的，目的在於執行returnBufferLocked是為了將這些因為register而出列的所有buffer再次cancelbuffer操作。

Camera3OutputStream::returnBufferLocked->Camera3IOStreamBase::returnAnyBufferLocked->Camera3OutputStream::returnBufferCheckedLocked

 

status_t Camera3OutputStream::returnBufferCheckedLocked(//result返回時調用
            const camera3_stream_buffer &buffer,
            nsecs_t timestamp,
            bool output,
            /*out*/
            sp *releaseFenceOut) {

    (void)output;
    ALOG_ASSERT(output, Expected output to be true);

    status_t res;
    sp releaseFence;

    /**
     * Fence management - calculate Release Fence
     */
    if (buffer.status == CAMERA3_BUFFER_STATUS_ERROR) {
        if (buffer.release_fence != -1) {
            ALOGE(%s: Stream %d: HAL should not set release_fence(%d) when 
                  there is an error, __FUNCTION__, mId, buffer.release_fence);
            close(buffer.release_fence);
        }

        /**
         * Reassign release fence as the acquire fence in case of error
         */
        releaseFence = new Fence(buffer.acquire_fence);
    } else {
        res = native_window_set_buffers_timestamp(mConsumer.get(), timestamp);
        if (res != OK) {
            ALOGE(%s: Stream %d: Error setting timestamp: %s (%d),
                  __FUNCTION__, mId, strerror(-res), res);
            return res;
        }

        releaseFence = new Fence(buffer.release_fence);
    }

    int anwReleaseFence = releaseFence->dup();

    /**
     * Release the lock briefly to avoid deadlock with
     * StreamingProcessor::startStream -> Camera3Stream::isConfiguring (this
     * thread will go into StreamingProcessor::onFrameAvailable) during
     * queueBuffer
     */
    sp currentConsumer = mConsumer;
    mLock.unlock();

    /**
     * Return buffer back to ANativeWindow
     */
    if (buffer.status == CAMERA3_BUFFER_STATUS_ERROR) {
        // Cancel buffer
        res = currentConsumer->cancelBuffer(currentConsumer.get(),
                container_of(buffer.buffer, ANativeWindowBuffer, handle),
                anwReleaseFence);//Register buffer locked所在的事情，cancelbuffer dequeue的buffer
        if (res != OK) {
            ALOGE(%s: Stream %d: Error cancelling buffer to native window:
                   %s (%d), __FUNCTION__, mId, strerror(-res), res);
        }
    } else {
        if (mTraceFirstBuffer && (stream_type == CAMERA3_STREAM_OUTPUT)) {
            {
                char traceLog[48];
                snprintf(traceLog, sizeof(traceLog), Stream %d: first full buffer
, mId);
                ATRACE_NAME(traceLog);
            }
            mTraceFirstBuffer = false;
        }

        res = currentConsumer->queueBuffer(currentConsumer.get(),
                container_of(buffer.buffer, ANativeWindowBuffer, handle),
                anwReleaseFence);//queuebuffer，送顯ANativeWindowBuffer
        if (res != OK) {
            ALOGE(%s: Stream %d: Error queueing buffer to native window: 
                  %s (%d), __FUNCTION__, mId, strerror(-res), res);
        }
    }
    mLock.lock();
    if (res != OK) {
        close(anwReleaseFence);
    }

    *releaseFenceOut = releaseFence;

    return res;
}

 

該函數對於首次register的處理來說，他處理的buffer均是CAMERA3_BUFFER_STATUS_ERROR，調用了cancelBuffer將所有buffer的狀態都還原為free的狀態，依次說明目前的buffer均是可用的，之前均不涉及到對buffer的數據流的操作。

 

3 buffer數據流的dequeue操作

上述步驟2主要是將每一個Stream下全部的buffer信息全部register到下層的HAL3中，為後續對buffer的數據流讀寫操作奠定基礎。

那麼preview模式下我們又是如何去獲得一幀完成的視頻流的呢？

觸發點就是preview模式下的Request，前面提到過一個mPreviewRequest至少包含一個StreamProcessor和一個CallbackProcessor的兩路stream，每路stream擁有不同的buffer數量。比如要從HAL3獲取一幀圖像數據，最簡單的思路就是從StreamProcessor下的Outputstream流中下發一個可用的buffer地址，然後HAL3填充下數據，Framework就可以擁有一幀數據了。

根據這個思路，回顧到前一博文中每次會不斷的下發一個Request命令包到HAL3中，在這裡我們就可以看到這個buffer地址身影。

Camera3Device::RequestThread::threadLoop() 下的部分代碼：

 

    outputBuffers.insertAt(camera3_stream_buffer_t(), 0,
            nextRequest->mOutputStreams.size());//Streamprocess,Callbackprocessor
    request.output_buffers = outputBuffers.array();//camera3_stream_buffer_t
    for (size_t i = 0; i < nextRequest->mOutputStreams.size(); i++) {
        res = nextRequest->mOutputStreams.editItemAt(i)->
                getBuffer(&outputBuffers.editItemAt(i));//等待獲取buffer,內部是dequeue一根buffer填充到camera3_stream_buffer_t
        if (res != OK) {
            // Can't get output buffer from gralloc queue - this could be due to
            // abandoned queue or other consumer misbehavior, so not a fatal
            // error
            ALOGE(RequestThread: Can't get output buffer, skipping request:
                     %s (%d), strerror(-res), res);
            Mutex::Autolock l(mRequestLock);
            if (mListener != NULL) {
                mListener->notifyError(
                        ICameraDeviceCallbacks::ERROR_CAMERA_REQUEST,
                        nextRequest->mResultExtras);
            }
            cleanUpFailedRequest(request, nextRequest, outputBuffers);
            return true;
        }
        request.num_output_buffers++;//一般一根OutStream對應一個buffer,故總的out_buffer數目
    }

在這個下發到HAL3的camera3_capture_request中，可以看到 const camera3_stream_buffer_t *output_buffers，下面的代碼可以說明這一次的Request的output_buffers是打包了當前Camera3Device所擁有的mOutputStreams。

 

 

    outputBuffers.insertAt(camera3_stream_buffer_t(), 0,
            nextRequest->mOutputStreams.size());//Streamprocess,Callbackprocessor

對於每一個OutputStream他會給她分配一個buffer handle。關注下面的處理代碼：

 

 

nextRequest->mOutputStreams.editItemAt(i)->
                getBuffer(&outputBuffers.editItemAt(i))

nextRequest->mOutputStreams.editItemAt(i)是獲取一個Camera3OutputStream對象，然後對getBuffer而言傳入的是這個Camera3OutputStream所對應的這次buffer的輸入位置，這個camera3_stream_buffer是需要從Camera3OutputStream對象中去獲取的。

 

 

status_t Camera3Stream::getBuffer(camera3_stream_buffer *buffer) {
    ATRACE_CALL();
    Mutex::Autolock l(mLock);
    status_t res = OK;

    // This function should be only called when the stream is configured already.
    if (mState != STATE_CONFIGURED) {
        ALOGE(%s: Stream %d: Can't get buffers if stream is not in CONFIGURED state %d,
                __FUNCTION__, mId, mState);
        return INVALID_OPERATION;
    }

    // Wait for new buffer returned back if we are running into the limit.
    if (getHandoutOutputBufferCountLocked() == camera3_stream::max_buffers) {//dequeue過多時等待queue的釋放
        ALOGV(%s: Already dequeued max output buffers (%d), wait for next returned one.,
                __FUNCTION__, camera3_stream::max_buffers);
        res = mOutputBufferReturnedSignal.waitRelative(mLock, kWaitForBufferDuration);
        if (res != OK) {
            if (res == TIMED_OUT) {
                ALOGE(%s: wait for output buffer return timed out after %lldms, __FUNCTION__,
                        kWaitForBufferDuration / 1000000LL);
            }
            return res;
        }
    }

    res = getBufferLocked(buffer);
    if (res == OK) {
        fireBufferListenersLocked(*buffer, /*acquired*/true, /*output*/true);
    }

    return res;
}

上述的代碼先是檢查dequeue了的buffer是否已經達到本stream申請的buffer數目的最大值，如果已經全部dequeue的話就得wait到當前已經有buffer return並且queue操作後，在處理完成後才允許將從buffer隊列中再次執行dequeue操作。

 

隨後調用getBufferLocked通過2.2(d）小節可以知道是從buffer隊列中獲取一個可用的buffer，並填充這個camera3_stream_buffer值。

這樣處理完的結果是，下發的Request包含所有模塊下的outputstream，同時每個stream都配備了一個camera3_stream_buffer供底層HAL3.0去處理，而這個buffer在Camera3Device模式下，可以是交互的是幀圖像數據，可以是參數控制命令，也可以是其他的3A信息，這些不同的信息一般歸不同的模塊管理，也就是不同的stream來處理。

 

4 buffer數據流的queue操作

dequeue出來的buffer信息已經隨著Request下發到了HAL3層，在Camera3Device架構下，可以使用一個Callback接口將數據從HAL3回傳到Camera所在的Framework層。Camera3Device私有繼承了一個Callback接口camera3_callback_ops數據結構，分別預留了notify和process_capture_result。前者是用於回調一些shutter已經error等信息，後者以Callback數據流為主，這個回調接口通過device->initialize(camera3_device, this)來完成注冊。

 

void Camera3Device::sProcessCaptureResult(const camera3_callback_ops *cb,
        const camera3_capture_result *result) {
    Camera3Device *d =
            const_cast(static_cast(cb));
    d->processCaptureResult(result);
}

返回的buffer所有信息均包含在camera3_capture_result中，該函數的處理過程相對比較復雜，如果只定位queue buffer的入口可直接到returnOutputBuffers中去：

 

 

void Camera3Device::returnOutputBuffers(
        const camera3_stream_buffer_t *outputBuffers, size_t numBuffers,
        nsecs_t timestamp) {
    for (size_t i = 0; i < numBuffers; i++)//對每一個buffer所屬的stream進行分析
    {
        Camera3Stream *stream = Camera3Stream::cast(outputBuffers[i].stream);//該buffer對應的camera3_stream
        status_t res = stream->returnBuffer(outputBuffers[i], timestamp);//Camera3OutPutStream，每一各stream對應的return
        // Note: stream may be deallocated at this point, if this buffer was
        // the last reference to it.
        if (res != OK) {
            ALOGE(Can't return buffer to its stream: %s (%d),
                strerror(-res), res);
        }
    }
}

因為在下發Request時，每一個buffer均包含所述的stream信息，當buffer數據返回到Framework層時，我們又可以轉到Camera3OutPutStream來處理這個return的buffer。

 

 

status_t Camera3Stream::returnBuffer(const camera3_stream_buffer &buffer,
        nsecs_t timestamp) {
    ATRACE_CALL();
    Mutex::Autolock l(mLock);

    /**
     * TODO: Check that the state is valid first.
     *
     * = HAL3.2 CONFIGURED only
     *
     * Do this for getBuffer as well.
     */
    status_t res = returnBufferLocked(buffer, timestamp);//以queue buffer為主
    if (res == OK) {
        fireBufferListenersLocked(buffer, /*acquired*/false, /*output*/true);
        mOutputBufferReturnedSignal.signal();
    }

    return res;
}

在這裡看看registerBuffersLocked，參考前面對這個函數他是register完所有的buffer時被調用，在這裡其本質處理的buffer狀態不在是CAMERA3_BUFFER_STATUS_ERROR，而是CAMERA3_BUFFER_STATUS_OK故執行的是將會queuebuffer的操作。

 

 

5 buffer數據真正的被Consumer處理

在queuebuffer的操作時，參考前一博文Android5.1中surface和CpuConsumer下生產者和消費者間的處理框架簡述很容易知道真正的Consumer需要開始工作了，對於preview模式下的當然是由SurfaceFlinger的那套機制去處理。而在Camera2Client和Camera3Device下你還可以看到CPUConsumer的存在，比如：

 

void CallbackProcessor::onFrameAvailable(const BufferItem& /*item*/) {
    Mutex::Autolock l(mInputMutex);
    if (!mCallbackAvailable) {
        mCallbackAvailable = true;
        mCallbackAvailableSignal.signal();//數據callback線程處理
    }
}

在這裡，你就可以去處理那些處於queue狀態的buffer數據，比如這裡的Callback將這幀數據上傳會APP。

 

 

bool CallbackProcessor::threadLoop() {
    status_t res;

    {
        Mutex::Autolock l(mInputMutex);
        while (!mCallbackAvailable) {
            res = mCallbackAvailableSignal.waitRelative(mInputMutex,
                    kWaitDuration);
            if (res == TIMED_OUT) return true;
        }
        mCallbackAvailable = false;
    }

    do {
        sp client = mClient.promote();
        if (client == 0) {
            res = discardNewCallback();
        } else {
            res = processNewCallback(client);//callback 處理新的一幀
        }
    } while (res == OK);

    return true;
}

         l.mRemoteCallback->dataCallback(CAMERA_MSG_PREVIEW_FRAME,
                    callbackHeap->mBuffers[heapIdx], NULL);//處理成API的需求後，回調Preview frame

 

 

 

6 總結

到這裡，整個preview預覽的視頻流基本介紹完畢了，主要框架雖然負責，但仔細看看也就是buffer的queue與dequeue操作，真正的HAL3的實現才是最為復雜的。後續還會簡單介紹下整個take picture的過程，數據的回調處理在後續中還會繼續分析。

 

下面貼一圖是整個Camera3架構下基於Request和result的處理流序圖：