上篇文章介绍了,Camera初始化的过程,完成初始化之后就可以使用Camera提供的以下功能了
1.预览preview
2.视频录制
3.拍照和参数设置
打开Camera第一键事情就是预览取景preview的动作,我们先从Camera app分析起 。所有拥有拍照功能的应用,它在预览时候都要实现SurfaceHolder.Callback接口,并实现其surfaceCreated、surfaceChanged、surfaceDestroyed三个函数,同时声明一个用于预览的窗口SurfaceView ,以下是系统自带ap的源代码
SurfaceView preview = (SurfaceView) findViewById(R.id.camera_preview);
SurfaceHolder holder = preview.getHolder();
holder.addCallback(this);
还要设置camera预览的surface缓存区 ,系统自带app实在surfaceChange()方法里面设置Camera的预览区,以供底层获取的preview数据不断投递到这个surface缓存区内。
public void surfaceChanged(SurfaceHolder holder, int format, int w, int h) {
mSurfaceHolder = holder;
// The mCameraDevice will be null if it fails to connect to the camera
// hardware. In this case we will show a dialog and then finish the
// activity, so it's OK to ignore it.
if (mCameraDevice == null) return;
// Sometimes surfaceChanged is called after onPause or before onResume.
// Ignore it.
if (mPausing || isFinishing()) return;
// Set preview display if the surface is being created. Preview was
// already started. Also restart the preview if display rotation has
// changed. Sometimes this happens when the device is held in portrait
// and camera app is opened. Rotation animation takes some time and
// display rotation in onCreate may not be what we want.
if (mCameraState == PREVIEW_STOPPED) {
startPreview();
startFaceDetection();
} else {
if (Util.getDisplayRotation(this) != mDisplayRotation) {
setDisplayOrientation();
}
if (holder.isCreating()) {
// Set preview display if the surface is being created and preview
// was already started. That means preview display was set to null
// and we need to set it now.
setPreviewDisplay(holder);
}
}
设置好以上参数后,就可以调用startPreview()进行取景预览
startPreview()也是一层层往下调用,最后到Camera的服务端CameraService,我们看下它的过程
Camera.java(应用)-------------> Camera.java(框架)-------------->android_hardware_camera.cpp(JNI)-------------------->Camera.cpp(客户端)------------------->CameraService.cpp(服务端)--------------------->CameraHarwareInterface(HAL接口)
在CameraService端将处理preview的请求并进入HAL层
status_t CameraService::Client::startPreview() {
enableMsgType(CAMERA_MSG_PREVIEW_METADATA);
return startCameraMode(CAMERA_PREVIEW_MODE);
}
先是传递preview的消息到HAL层,然后执行preview
status_t CameraService::Client::startCameraMode(camera_mode mode) {
switch(mode) {
case CAMERA_PREVIEW_MODE:
if (mSurface == 0 && mPreviewWindow == 0) {
LOG1("mSurface is not set yet.");
// still able to start preview in this case.
}
return startPreviewMode();
}
}
status_t CameraService::Client::startPreviewMode() {
LOG1("startPreviewMode");
status_t result = NO_ERROR;
// if preview has been enabled, nothing needs to be done
if (mHardware->previewEnabled()) {
return NO_ERROR;
}
if (mPreviewWindow != 0) {
native_window_set_scaling_mode(mPreviewWindow.get(),
NATIVE_WINDOW_SCALING_MODE_SCALE_TO_WINDOW);
native_window_set_buffers_transform(mPreviewWindow.get(),
mOrientation);
}
mHardware->setPreviewWindow(mPreviewWindow);
result = mHardware->startPreview();
return result;
}
然后就近去HAL层调用,并通过回调函数源源不断的将数据投递到surfaceview的缓存去,因为preview的数据是比较大的,所以数据不会携带着传上上层,而是直接在两个缓存区之间copy,一个是底层采集数据的缓存区,另一个是用于显示的surfaceview缓存区
我们看看preview的回调函数是怎么处理的
首先在Camera客户端与服务端连接成功的时候就会设置一个回调函数dataCallBack
CameraService::Client::Client(const sp
const sp
const sp
int cameraId, int cameraFacing, int clientPid) {
......
dataCallback,
dataCallbackTimestamp,
(void *)cameraId);
}
在上篇有介绍到,client与server连接成功后就会new 一个client返回,在client的构造函数中,就对camera设置了notifyCallback、dataCallback、dataCallbackTimestamp三个回调函数,用于返回底层数据用于处理,看下它的处理方法
void CameraService::Client::dataCallback(int32_t msgType,
const sp
switch (msgType & ~CAMERA_MSG_PREVIEW_METADATA) {
client->handlePreviewData(msgType, dataPtr, metadata);
break;
.......
}
继续看handlePreviewData()
void CameraService::Client::handlePreviewData(int32_t msgType,
const sp
camera_frame_metadata_t *metadata) {
sp
.......
if (c != 0) {
// Is the received frame copied out or not?
if (flags & CAMERA_FRAME_CALLBACK_FLAG_COPY_OUT_MASK) {
LOG2("frame is copied");
} else {
LOG2("frame is forwarded");
mLock.unlock();
c->dataCallback(msgType, mem, metadata);
}
} else {
mLock.unlock();
}
}
copyFrameAndPostCopiedFrame就是这个函数执行两个buff区preview数据的投递
void CameraService::Client::copyFrameAndPostCopiedFrame(
int32_t msgType, const sp
const sp
camera_frame_metadata_t *metadata) {
......
previewBuffer = mPreviewBuffer;
memcpy(previewBuffer->base(), (uint8_t *)heap->base() + offset, size);
sp
if (frame == 0) {
LOGE("failed to allocate space for frame callback");
mLock.unlock();
return;
}
mLock.unlock();
client->dataCallback(msgType, frame, metadata);
}
将数据处理成frame,继续调用客户端client的回调函数 client->dataCallback(msgType, frame, metadata);
// callback from camera service when frame or image is ready
void Camera::dataCallback(int32_t msgType, const sp
camera_frame_metadata_t *metadata)
{
sp
{
Mutex::Autolock _l(mLock);
listener = mListener;
}
if (listener != NULL) {
}
}
还记得初始化的时候,在jni里面有设置listener吗?
static void android_hardware_Camera_native_setup(JNIEnv *env, jobject thiz,
jobject weak_this, jint cameraId)
{
sp
context->incStrong(thiz);
camera->setListener(context);
}
继续 listener->postData(msgType, dataPtr, metadata);
void JNICameraContext::postData(int32_t msgType, const sp
camera_frame_metadata_t *metadata)
{
......
switch (dataMsgType) {
case CAMERA_MSG_VIDEO_FRAME:
// should never happen
break;
default:
LOGV("dataCallback(%d, %p)", dataMsgType, dataPtr.get());
break;
}
}
继续copyAndPost(env, dataPtr, dataMsgType);
void JNICameraContext::copyAndPost(JNIEnv* env, const sp
{
jbyteArray obj = NULL;
// allocate Java byte array and copy data
if (dataPtr != NULL) {
.......
} else {
LOGV("Allocating callback buffer");
.......
env->SetByteArrayRegion(obj, 0, size, data);
}
} else {
LOGE("image heap is NULL");
}
}
// post image data to Java
env->CallStaticVoidMethod(mCameraJClass, fields.post_event,
mCameraJObjectWeak, msgType, 0, 0, obj);
if (obj) {
env->DeleteLocalRef(obj);
}
}
解释一下标红的部分,先建立一个byte数组obj,将data缓存数据存储进obj数组,CallStaticVoidMethod是C调用java函数,最后执行实在Camera.java(框架)的postEventFromNative()
private static void postEventFromNative(Object camera_ref,
int what, int arg1, int arg2, Object obj)
{
Camera c = (Camera)((WeakReference)camera_ref).get();
if (c == null)
return;
if (c.mEventHandler != null) {
Message m = c.mEventHandler.obtainMessage(what, arg1, arg2, obj);
c.mEventHandler.sendMessage(m);
}
}
还是handler处理地
public void handleMessage(Message msg) {
switch(msg.what) {
case CAMERA_MSG_SHUTTER:
if (mShutterCallback != null) {
mShutterCallback.onShutter();
}
return;
case CAMERA_MSG_RAW_IMAGE:
if (mRawImageCallback != null) {
mRawImageCallback.onPictureTaken((byte[])msg.obj, mCamera);
}
return;
case CAMERA_MSG_COMPRESSED_IMAGE:
if (mJpegCallback != null) {
mJpegCallback.onPictureTaken((byte[])msg.obj, mCamera);
}
return;
case CAMERA_MSG_PREVIEW_FRAME:
if (mPreviewCallback != null) {
PreviewCallback cb = mPreviewCallback;
if (mOneShot) {
// Clear the callback variable before the callback
// in case the app calls setPreviewCallback from
// the callback function
mPreviewCallback = null;
} else if (!mWithBuffer) {
// We're faking the camera preview mode to prevent
// the app from being flooded with preview frames.
// Set to oneshot mode again.
setHasPreviewCallback(true, false);
}
cb.onPreviewFrame((byte[])msg.obj, mCamera);
}
return;
}
}
}
上面可以看出,这里处理了所有的回调,快门回调mShutterCallback.onShutter(),RawImageCallback.onPictureTaken()拍照数据回调,自动对焦回调等。。默认是没有previewcallback这个回调的,除非你的app设置了setPreviewCallback,可以看出preview的数据还是可以向上层回调,只是系统默认不回调,另数据采集区与显示区两个缓存区buffer preview数据的投递,以完成preview实时显示是在HAL层完成的。
takePicture()处理过程跟preview差不多,只是增加了回调函数返回时候存储图像的动作
public JpegPictureCallback(Location loc) {
mLocation = loc;
}
public void onPictureTaken(
final byte [] jpegData, final android.hardware.Camera camera) {
.........................
if (!mIsImageCaptureIntent) {
Size s = mParameters.getPictureSize();
mImageSaver.addImage(jpegData, mLocation, s.width, s.height);
} else {
mJpegImageData = jpegData;
if (!mQuickCapture) {
showPostCaptureAlert();
} else {
doAttach();
}
}
}
}
}