replicant-frameworks_native/camera/tests/CameraServiceTest/CameraServiceTest.cpp
Chih-Chung Chang 5997faf931 Support multiple cameras in framework.
Change-Id: I081f0fbdca4b633715ea7c3b3d42f8662d27598a
2010-05-10 11:21:14 +08:00

914 lines
25 KiB
C++

#define LOG_TAG "CameraServiceTest"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <unistd.h>
#include <surfaceflinger/ISurface.h>
#include <camera/Camera.h>
#include <camera/CameraParameters.h>
#include <ui/GraphicBuffer.h>
#include <camera/ICamera.h>
#include <camera/ICameraClient.h>
#include <camera/ICameraService.h>
#include <ui/Overlay.h>
#include <binder/IPCThreadState.h>
#include <binder/IServiceManager.h>
#include <binder/ProcessState.h>
#include <utils/KeyedVector.h>
#include <utils/Log.h>
#include <utils/Vector.h>
#include <utils/threads.h>
using namespace android;
//
// Assertion and Logging utilities
//
#define INFO(...) \
do { \
printf(__VA_ARGS__); \
printf("\n"); \
LOGD(__VA_ARGS__); \
} while(0)
void assert_fail(const char *file, int line, const char *func, const char *expr) {
INFO("assertion failed at file %s, line %d, function %s:",
file, line, func);
INFO("%s", expr);
abort();
}
void assert_eq_fail(const char *file, int line, const char *func,
const char *expr, int actual) {
INFO("assertion failed at file %s, line %d, function %s:",
file, line, func);
INFO("(expected) %s != (actual) %d", expr, actual);
abort();
}
#define ASSERT(e) \
do { \
if (!(e)) \
assert_fail(__FILE__, __LINE__, __func__, #e); \
} while(0)
#define ASSERT_EQ(expected, actual) \
do { \
int _x = (actual); \
if (_x != (expected)) \
assert_eq_fail(__FILE__, __LINE__, __func__, #expected, _x); \
} while(0)
//
// Holder service for pass objects between processes.
//
class IHolder : public IInterface {
protected:
enum {
HOLDER_PUT = IBinder::FIRST_CALL_TRANSACTION,
HOLDER_GET,
HOLDER_CLEAR
};
public:
DECLARE_META_INTERFACE(Holder);
virtual void put(sp<IBinder> obj) = 0;
virtual sp<IBinder> get() = 0;
virtual void clear() = 0;
};
class BnHolder : public BnInterface<IHolder> {
virtual status_t onTransact(uint32_t code,
const Parcel& data,
Parcel* reply,
uint32_t flags = 0);
};
class BpHolder : public BpInterface<IHolder> {
public:
BpHolder(const sp<IBinder>& impl)
: BpInterface<IHolder>(impl) {
}
virtual void put(sp<IBinder> obj) {
Parcel data, reply;
data.writeStrongBinder(obj);
remote()->transact(HOLDER_PUT, data, &reply, IBinder::FLAG_ONEWAY);
}
virtual sp<IBinder> get() {
Parcel data, reply;
remote()->transact(HOLDER_GET, data, &reply);
return reply.readStrongBinder();
}
virtual void clear() {
Parcel data, reply;
remote()->transact(HOLDER_CLEAR, data, &reply);
}
};
IMPLEMENT_META_INTERFACE(Holder, "CameraServiceTest.Holder");
status_t BnHolder::onTransact(
uint32_t code, const Parcel& data, Parcel* reply, uint32_t flags) {
switch(code) {
case HOLDER_PUT: {
put(data.readStrongBinder());
return NO_ERROR;
} break;
case HOLDER_GET: {
reply->writeStrongBinder(get());
return NO_ERROR;
} break;
case HOLDER_CLEAR: {
clear();
return NO_ERROR;
} break;
default:
return BBinder::onTransact(code, data, reply, flags);
}
}
class HolderService : public BnHolder {
virtual void put(sp<IBinder> obj) {
mObj = obj;
}
virtual sp<IBinder> get() {
return mObj;
}
virtual void clear() {
mObj.clear();
}
private:
sp<IBinder> mObj;
};
//
// A mock CameraClient
//
class MCameraClient : public BnCameraClient {
public:
virtual void notifyCallback(int32_t msgType, int32_t ext1, int32_t ext2);
virtual void dataCallback(int32_t msgType, const sp<IMemory>& data);
virtual void dataCallbackTimestamp(nsecs_t timestamp,
int32_t msgType, const sp<IMemory>& data);
// new functions
void clearStat();
enum OP { EQ, GE, LE, GT, LT };
void assertNotify(int32_t msgType, OP op, int count);
void assertData(int32_t msgType, OP op, int count);
void waitNotify(int32_t msgType, OP op, int count);
void waitData(int32_t msgType, OP op, int count);
void assertDataSize(int32_t msgType, OP op, int dataSize);
void setReleaser(ICamera *releaser) {
mReleaser = releaser;
}
private:
Mutex mLock;
Condition mCond;
DefaultKeyedVector<int32_t, int> mNotifyCount;
DefaultKeyedVector<int32_t, int> mDataCount;
DefaultKeyedVector<int32_t, int> mDataSize;
bool test(OP op, int v1, int v2);
void assertTest(OP op, int v1, int v2);
ICamera *mReleaser;
};
void MCameraClient::clearStat() {
Mutex::Autolock _l(mLock);
mNotifyCount.clear();
mDataCount.clear();
mDataSize.clear();
}
bool MCameraClient::test(OP op, int v1, int v2) {
switch (op) {
case EQ: return v1 == v2;
case GT: return v1 > v2;
case LT: return v1 < v2;
case GE: return v1 >= v2;
case LE: return v1 <= v2;
default: ASSERT(0); break;
}
return false;
}
void MCameraClient::assertTest(OP op, int v1, int v2) {
if (!test(op, v1, v2)) {
LOGE("assertTest failed: op=%d, v1=%d, v2=%d", op, v1, v2);
ASSERT(0);
}
}
void MCameraClient::assertNotify(int32_t msgType, OP op, int count) {
Mutex::Autolock _l(mLock);
int v = mNotifyCount.valueFor(msgType);
assertTest(op, v, count);
}
void MCameraClient::assertData(int32_t msgType, OP op, int count) {
Mutex::Autolock _l(mLock);
int v = mDataCount.valueFor(msgType);
assertTest(op, v, count);
}
void MCameraClient::assertDataSize(int32_t msgType, OP op, int dataSize) {
Mutex::Autolock _l(mLock);
int v = mDataSize.valueFor(msgType);
assertTest(op, v, dataSize);
}
void MCameraClient::notifyCallback(int32_t msgType, int32_t ext1, int32_t ext2) {
INFO(__func__);
Mutex::Autolock _l(mLock);
ssize_t i = mNotifyCount.indexOfKey(msgType);
if (i < 0) {
mNotifyCount.add(msgType, 1);
} else {
++mNotifyCount.editValueAt(i);
}
mCond.signal();
}
void MCameraClient::dataCallback(int32_t msgType, const sp<IMemory>& data) {
INFO(__func__);
int dataSize = data->size();
INFO("data type = %d, size = %d", msgType, dataSize);
Mutex::Autolock _l(mLock);
ssize_t i = mDataCount.indexOfKey(msgType);
if (i < 0) {
mDataCount.add(msgType, 1);
mDataSize.add(msgType, dataSize);
} else {
++mDataCount.editValueAt(i);
mDataSize.editValueAt(i) = dataSize;
}
mCond.signal();
if (msgType == CAMERA_MSG_VIDEO_FRAME) {
ASSERT(mReleaser != NULL);
mReleaser->releaseRecordingFrame(data);
}
}
void MCameraClient::dataCallbackTimestamp(nsecs_t timestamp, int32_t msgType,
const sp<IMemory>& data) {
dataCallback(msgType, data);
}
void MCameraClient::waitNotify(int32_t msgType, OP op, int count) {
INFO("waitNotify: %d, %d, %d", msgType, op, count);
Mutex::Autolock _l(mLock);
while (true) {
int v = mNotifyCount.valueFor(msgType);
if (test(op, v, count)) {
break;
}
mCond.wait(mLock);
}
}
void MCameraClient::waitData(int32_t msgType, OP op, int count) {
INFO("waitData: %d, %d, %d", msgType, op, count);
Mutex::Autolock _l(mLock);
while (true) {
int v = mDataCount.valueFor(msgType);
if (test(op, v, count)) {
break;
}
mCond.wait(mLock);
}
}
//
// A mock Surface
//
class MSurface : public BnSurface {
public:
virtual status_t registerBuffers(const BufferHeap& buffers);
virtual void postBuffer(ssize_t offset);
virtual void unregisterBuffers();
virtual sp<OverlayRef> createOverlay(
uint32_t w, uint32_t h, int32_t format, int32_t orientation);
virtual sp<GraphicBuffer> requestBuffer(int bufferIdx, int usage);
// new functions
void clearStat();
void waitUntil(int c0, int c1, int c2);
private:
// check callback count
Condition mCond;
Mutex mLock;
int registerBuffersCount;
int postBufferCount;
int unregisterBuffersCount;
};
status_t MSurface::registerBuffers(const BufferHeap& buffers) {
INFO(__func__);
Mutex::Autolock _l(mLock);
++registerBuffersCount;
mCond.signal();
return NO_ERROR;
}
void MSurface::postBuffer(ssize_t offset) {
// INFO(__func__);
Mutex::Autolock _l(mLock);
++postBufferCount;
mCond.signal();
}
void MSurface::unregisterBuffers() {
INFO(__func__);
Mutex::Autolock _l(mLock);
++unregisterBuffersCount;
mCond.signal();
}
sp<GraphicBuffer> MSurface::requestBuffer(int bufferIdx, int usage) {
INFO(__func__);
return NULL;
}
void MSurface::clearStat() {
Mutex::Autolock _l(mLock);
registerBuffersCount = 0;
postBufferCount = 0;
unregisterBuffersCount = 0;
}
void MSurface::waitUntil(int c0, int c1, int c2) {
INFO("waitUntil: %d %d %d", c0, c1, c2);
Mutex::Autolock _l(mLock);
while (true) {
if (registerBuffersCount >= c0 &&
postBufferCount >= c1 &&
unregisterBuffersCount >= c2) {
break;
}
mCond.wait(mLock);
}
}
sp<OverlayRef> MSurface::createOverlay(uint32_t w, uint32_t h, int32_t format,
int32_t orientation) {
// Not implemented.
ASSERT(0);
return NULL;
}
//
// Utilities to use the Holder service
//
sp<IHolder> getHolder() {
sp<IServiceManager> sm = defaultServiceManager();
ASSERT(sm != 0);
sp<IBinder> binder = sm->getService(String16("CameraServiceTest.Holder"));
ASSERT(binder != 0);
sp<IHolder> holder = interface_cast<IHolder>(binder);
ASSERT(holder != 0);
return holder;
}
void putTempObject(sp<IBinder> obj) {
INFO(__func__);
getHolder()->put(obj);
}
sp<IBinder> getTempObject() {
INFO(__func__);
return getHolder()->get();
}
void clearTempObject() {
INFO(__func__);
getHolder()->clear();
}
//
// Get a Camera Service
//
sp<ICameraService> getCameraService() {
sp<IServiceManager> sm = defaultServiceManager();
ASSERT(sm != 0);
sp<IBinder> binder = sm->getService(String16("media.camera"));
ASSERT(binder != 0);
sp<ICameraService> cs = interface_cast<ICameraService>(binder);
ASSERT(cs != 0);
return cs;
}
int getNumberOfCameras() {
sp<ICameraService> cs = getCameraService();
return cs->getNumberOfCameras();
}
//
// Various Connect Tests
//
void testConnect(int cameraId) {
INFO(__func__);
sp<ICameraService> cs = getCameraService();
sp<MCameraClient> cc = new MCameraClient();
sp<ICamera> c = cs->connect(cc, cameraId);
ASSERT(c != 0);
c->disconnect();
}
void testAllowConnectOnceOnly(int cameraId) {
INFO(__func__);
sp<ICameraService> cs = getCameraService();
// Connect the first client.
sp<MCameraClient> cc = new MCameraClient();
sp<ICamera> c = cs->connect(cc, cameraId);
ASSERT(c != 0);
// Same client -- ok.
ASSERT(cs->connect(cc, cameraId) != 0);
// Different client -- not ok.
sp<MCameraClient> cc2 = new MCameraClient();
ASSERT(cs->connect(cc2, cameraId) == 0);
c->disconnect();
}
void testReconnectFailed() {
INFO(__func__);
sp<ICamera> c = interface_cast<ICamera>(getTempObject());
sp<MCameraClient> cc = new MCameraClient();
ASSERT(c->connect(cc) != NO_ERROR);
}
void testReconnectSuccess() {
INFO(__func__);
sp<ICamera> c = interface_cast<ICamera>(getTempObject());
sp<MCameraClient> cc = new MCameraClient();
ASSERT(c->connect(cc) == NO_ERROR);
c->disconnect();
}
void testLockFailed() {
INFO(__func__);
sp<ICamera> c = interface_cast<ICamera>(getTempObject());
ASSERT(c->lock() != NO_ERROR);
}
void testLockUnlockSuccess() {
INFO(__func__);
sp<ICamera> c = interface_cast<ICamera>(getTempObject());
ASSERT(c->lock() == NO_ERROR);
ASSERT(c->unlock() == NO_ERROR);
}
void testLockSuccess() {
INFO(__func__);
sp<ICamera> c = interface_cast<ICamera>(getTempObject());
ASSERT(c->lock() == NO_ERROR);
c->disconnect();
}
//
// Run the connect tests in another process.
//
const char *gExecutable;
struct FunctionTableEntry {
const char *name;
void (*func)();
};
FunctionTableEntry function_table[] = {
#define ENTRY(x) {#x, &x}
ENTRY(testReconnectFailed),
ENTRY(testReconnectSuccess),
ENTRY(testLockUnlockSuccess),
ENTRY(testLockFailed),
ENTRY(testLockSuccess),
#undef ENTRY
};
void runFunction(const char *tag) {
INFO("runFunction: %s", tag);
int entries = sizeof(function_table) / sizeof(function_table[0]);
for (int i = 0; i < entries; i++) {
if (strcmp(function_table[i].name, tag) == 0) {
(*function_table[i].func)();
return;
}
}
ASSERT(0);
}
void runInAnotherProcess(const char *tag) {
pid_t pid = fork();
if (pid == 0) {
execlp(gExecutable, gExecutable, tag, NULL);
ASSERT(0);
} else {
int status;
ASSERT_EQ(pid, wait(&status));
ASSERT_EQ(0, status);
}
}
void testReconnect(int cameraId) {
INFO(__func__);
sp<ICameraService> cs = getCameraService();
sp<MCameraClient> cc = new MCameraClient();
sp<ICamera> c = cs->connect(cc, cameraId);
ASSERT(c != 0);
// Reconnect to the same client -- ok.
ASSERT(c->connect(cc) == NO_ERROR);
// Reconnect to a different client (but the same pid) -- ok.
sp<MCameraClient> cc2 = new MCameraClient();
ASSERT(c->connect(cc2) == NO_ERROR);
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
void testLockUnlock(int cameraId) {
sp<ICameraService> cs = getCameraService();
sp<MCameraClient> cc = new MCameraClient();
sp<ICamera> c = cs->connect(cc, cameraId);
ASSERT(c != 0);
// We can lock as many times as we want.
ASSERT(c->lock() == NO_ERROR);
ASSERT(c->lock() == NO_ERROR);
// Lock from a different process -- not ok.
putTempObject(c->asBinder());
runInAnotherProcess("testLockFailed");
// Unlock then lock from a different process -- ok.
ASSERT(c->unlock() == NO_ERROR);
runInAnotherProcess("testLockUnlockSuccess");
// Unlock then lock from a different process -- ok.
runInAnotherProcess("testLockSuccess");
clearTempObject();
}
void testReconnectFromAnotherProcess(int cameraId) {
INFO(__func__);
sp<ICameraService> cs = getCameraService();
sp<MCameraClient> cc = new MCameraClient();
sp<ICamera> c = cs->connect(cc, cameraId);
ASSERT(c != 0);
// Reconnect from a different process -- not ok.
putTempObject(c->asBinder());
runInAnotherProcess("testReconnectFailed");
// Unlock then reconnect from a different process -- ok.
ASSERT(c->unlock() == NO_ERROR);
runInAnotherProcess("testReconnectSuccess");
clearTempObject();
}
// We need to flush the command buffer after the reference
// to ICamera is gone. The sleep is for the server to run
// the destructor for it.
static void flushCommands() {
IPCThreadState::self()->flushCommands();
usleep(200000); // 200ms
}
// Run a test case
#define RUN(class_name, cameraId) do { \
{ \
INFO(#class_name); \
class_name instance; \
instance.init(cameraId); \
instance.run(); \
} \
flushCommands(); \
} while(0)
// Base test case after the the camera is connected.
class AfterConnect {
public:
void init(int cameraId) {
cs = getCameraService();
cc = new MCameraClient();
c = cs->connect(cc, cameraId);
ASSERT(c != 0);
}
protected:
sp<ICameraService> cs;
sp<MCameraClient> cc;
sp<ICamera> c;
~AfterConnect() {
c->disconnect();
c.clear();
cc.clear();
cs.clear();
}
};
class TestSetPreviewDisplay : public AfterConnect {
public:
void run() {
sp<MSurface> surface = new MSurface();
ASSERT(c->setPreviewDisplay(surface) == NO_ERROR);
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestStartPreview : public AfterConnect {
public:
void run() {
sp<MSurface> surface = new MSurface();
ASSERT(c->setPreviewDisplay(surface) == NO_ERROR);
ASSERT(c->startPreview() == NO_ERROR);
ASSERT(c->previewEnabled() == true);
surface->waitUntil(1, 10, 0); // needs 1 registerBuffers and 10 postBuffer
surface->clearStat();
sp<MSurface> another_surface = new MSurface();
c->setPreviewDisplay(another_surface); // just to make sure unregisterBuffers
// is called.
surface->waitUntil(0, 0, 1); // needs unregisterBuffers
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestStartPreviewWithoutDisplay : public AfterConnect {
public:
void run() {
ASSERT(c->startPreview() == NO_ERROR);
ASSERT(c->previewEnabled() == true);
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
// Base test case after the the camera is connected and the preview is started.
class AfterStartPreview : public AfterConnect {
public:
void init(int cameraId) {
AfterConnect::init(cameraId);
surface = new MSurface();
ASSERT(c->setPreviewDisplay(surface) == NO_ERROR);
ASSERT(c->startPreview() == NO_ERROR);
}
protected:
sp<MSurface> surface;
~AfterStartPreview() {
surface.clear();
}
};
class TestAutoFocus : public AfterStartPreview {
public:
void run() {
cc->assertNotify(CAMERA_MSG_FOCUS, MCameraClient::EQ, 0);
c->autoFocus();
cc->waitNotify(CAMERA_MSG_FOCUS, MCameraClient::EQ, 1);
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestStopPreview : public AfterStartPreview {
public:
void run() {
ASSERT(c->previewEnabled() == true);
c->stopPreview();
ASSERT(c->previewEnabled() == false);
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestTakePicture: public AfterStartPreview {
public:
void run() {
ASSERT(c->takePicture() == NO_ERROR);
cc->waitNotify(CAMERA_MSG_SHUTTER, MCameraClient::EQ, 1);
cc->waitData(CAMERA_MSG_RAW_IMAGE, MCameraClient::EQ, 1);
cc->waitData(CAMERA_MSG_COMPRESSED_IMAGE, MCameraClient::EQ, 1);
c->stopPreview();
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestTakeMultiplePictures: public AfterStartPreview {
public:
void run() {
for (int i = 0; i < 10; i++) {
cc->clearStat();
ASSERT(c->takePicture() == NO_ERROR);
cc->waitNotify(CAMERA_MSG_SHUTTER, MCameraClient::EQ, 1);
cc->waitData(CAMERA_MSG_RAW_IMAGE, MCameraClient::EQ, 1);
cc->waitData(CAMERA_MSG_COMPRESSED_IMAGE, MCameraClient::EQ, 1);
}
c->disconnect();
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
};
class TestGetParameters: public AfterStartPreview {
public:
void run() {
String8 param_str = c->getParameters();
INFO(param_str);
}
};
static bool getNextSize(const char **ptrS, int *w, int *h) {
const char *s = *ptrS;
// skip over ','
if (*s == ',') s++;
// remember start position in p
const char *p = s;
while (*s != '\0' && *s != 'x') {
s++;
}
if (*s == '\0') return false;
// get the width
*w = atoi(p);
// skip over 'x'
ASSERT(*s == 'x');
p = s + 1;
while (*s != '\0' && *s != ',') {
s++;
}
// get the height
*h = atoi(p);
*ptrS = s;
return true;
}
class TestPictureSize : public AfterStartPreview {
public:
void checkOnePicture(int w, int h) {
const float rate = 0.9; // byte per pixel limit
int pixels = w * h;
CameraParameters param(c->getParameters());
param.setPictureSize(w, h);
// disable thumbnail to get more accurate size.
param.set(CameraParameters::KEY_JPEG_THUMBNAIL_WIDTH, 0);
param.set(CameraParameters::KEY_JPEG_THUMBNAIL_HEIGHT, 0);
c->setParameters(param.flatten());
cc->clearStat();
ASSERT(c->takePicture() == NO_ERROR);
cc->waitData(CAMERA_MSG_RAW_IMAGE, MCameraClient::EQ, 1);
//cc->assertDataSize(CAMERA_MSG_RAW_IMAGE, MCameraClient::EQ, pixels*3/2);
cc->waitData(CAMERA_MSG_COMPRESSED_IMAGE, MCameraClient::EQ, 1);
cc->assertDataSize(CAMERA_MSG_COMPRESSED_IMAGE, MCameraClient::LT,
int(pixels * rate));
cc->assertDataSize(CAMERA_MSG_COMPRESSED_IMAGE, MCameraClient::GT, 0);
cc->assertNotify(CAMERA_MSG_ERROR, MCameraClient::EQ, 0);
}
void run() {
CameraParameters param(c->getParameters());
int w, h;
const char *s = param.get(CameraParameters::KEY_SUPPORTED_PICTURE_SIZES);
while (getNextSize(&s, &w, &h)) {
LOGD("checking picture size %dx%d", w, h);
checkOnePicture(w, h);
}
}
};
class TestPreviewCallbackFlag : public AfterConnect {
public:
void run() {
sp<MSurface> surface = new MSurface();
ASSERT(c->setPreviewDisplay(surface) == NO_ERROR);
// Try all flag combinations.
for (int v = 0; v < 8; v++) {
LOGD("TestPreviewCallbackFlag: flag=%d", v);
usleep(100000); // sleep a while to clear the in-flight callbacks.
cc->clearStat();
c->setPreviewCallbackFlag(v);
ASSERT(c->previewEnabled() == false);
ASSERT(c->startPreview() == NO_ERROR);
ASSERT(c->previewEnabled() == true);
sleep(2);
c->stopPreview();
if ((v & FRAME_CALLBACK_FLAG_ENABLE_MASK) == 0) {
cc->assertData(CAMERA_MSG_PREVIEW_FRAME, MCameraClient::EQ, 0);
} else {
if ((v & FRAME_CALLBACK_FLAG_ONE_SHOT_MASK) == 0) {
cc->assertData(CAMERA_MSG_PREVIEW_FRAME, MCameraClient::GE, 10);
} else {
cc->assertData(CAMERA_MSG_PREVIEW_FRAME, MCameraClient::EQ, 1);
}
}
}
}
};
class TestRecording : public AfterConnect {
public:
void run() {
ASSERT(c->recordingEnabled() == false);
sp<MSurface> surface = new MSurface();
ASSERT(c->setPreviewDisplay(surface) == NO_ERROR);
c->setPreviewCallbackFlag(FRAME_CALLBACK_FLAG_ENABLE_MASK);
cc->setReleaser(c.get());
c->startRecording();
ASSERT(c->recordingEnabled() == true);
sleep(2);
c->stopRecording();
usleep(100000); // sleep a while to clear the in-flight callbacks.
cc->setReleaser(NULL);
cc->assertData(CAMERA_MSG_VIDEO_FRAME, MCameraClient::GE, 10);
}
};
class TestPreviewSize : public AfterStartPreview {
public:
void checkOnePicture(int w, int h) {
int size = w*h*3/2; // should read from parameters
c->stopPreview();
CameraParameters param(c->getParameters());
param.setPreviewSize(w, h);
c->setPreviewCallbackFlag(FRAME_CALLBACK_FLAG_ENABLE_MASK);
c->setParameters(param.flatten());
c->startPreview();
cc->clearStat();
cc->waitData(CAMERA_MSG_PREVIEW_FRAME, MCameraClient::GE, 1);
cc->assertDataSize(CAMERA_MSG_PREVIEW_FRAME, MCameraClient::EQ, size);
}
void run() {
CameraParameters param(c->getParameters());
int w, h;
const char *s = param.get(CameraParameters::KEY_SUPPORTED_PREVIEW_SIZES);
while (getNextSize(&s, &w, &h)) {
LOGD("checking preview size %dx%d", w, h);
checkOnePicture(w, h);
}
}
};
void runHolderService() {
defaultServiceManager()->addService(
String16("CameraServiceTest.Holder"), new HolderService());
ProcessState::self()->startThreadPool();
}
int main(int argc, char **argv)
{
if (argc != 1) {
runFunction(argv[1]);
return 0;
}
INFO("CameraServiceTest start");
gExecutable = argv[0];
runHolderService();
int n = getNumberOfCameras();
INFO("%d Cameras available", n);
for (int id = 0; id < n; id++) {
INFO("Testing camera %d", id);
testConnect(id); flushCommands();
testAllowConnectOnceOnly(id); flushCommands();
testReconnect(id); flushCommands();
testLockUnlock(id); flushCommands();
testReconnectFromAnotherProcess(id); flushCommands();
RUN(TestSetPreviewDisplay, id);
RUN(TestStartPreview, id);
RUN(TestStartPreviewWithoutDisplay, id);
RUN(TestAutoFocus, id);
RUN(TestStopPreview, id);
RUN(TestTakePicture, id);
RUN(TestTakeMultiplePictures, id);
RUN(TestGetParameters, id);
RUN(TestPictureSize, id);
RUN(TestPreviewCallbackFlag, id);
RUN(TestRecording, id);
RUN(TestPreviewSize, id);
}
INFO("CameraServiceTest finished");
}