tests/media/jni/NativeCodecEncoderSurfaceTest.cpp - platform/cts - Gitiles

 /*
  * Copyright (C) 2020 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.
  */

 //#define LOG_NDEBUG 0
 #define LOG_TAG "NativeCodecEncoderSurfaceTest"
 #include <log/log.h>
 #include <android/native_window_jni.h>
 #include <NdkMediaExtractor.h>
 #include <NdkMediaMuxer.h>
 #include <jni.h>
 #include <sys/stat.h>

 #include "NativeCodecTestBase.h"
 #include "NativeMediaCommon.h"

 class CodecEncoderSurfaceTest {
   private:
     const long kQDeQTimeOutUs = 5000;
     const char* mMime;
     ANativeWindow* mWindow;
     AMediaExtractor* mExtractor;
     AMediaFormat* mDecFormat;
     AMediaFormat* mEncFormat;
     AMediaMuxer* mMuxer;
     AMediaCodec* mDecoder;
     AMediaCodec* mEncoder;
     CodecAsyncHandler mAsyncHandleDecoder;
     CodecAsyncHandler mAsyncHandleEncoder;
     bool mIsCodecInAsyncMode;
     bool mSawDecInputEOS;
     bool mSawDecOutputEOS;
     bool mSawEncOutputEOS;
     bool mSignalEOSWithLastFrame;
     int mDecInputCount;
     int mDecOutputCount;
     int mEncOutputCount;
     int mEncBitrate;
     int mEncFramerate;
     int mMaxBFrames;
     int mMuxTrackID;

     OutputManager* mOutputBuff;
     OutputManager mRefBuff;
     OutputManager mTestBuff;
     bool mSaveToMem;

     bool setUpExtractor(const char* srcPath);
     void deleteExtractor();
     bool configureCodec(bool isAsync, bool signalEOSWithLastFrame);
     void resetContext(bool isAsync, bool signalEOSWithLastFrame);
     void setUpEncoderFormat();
     bool enqueueDecoderInput(size_t bufferIndex);
     bool dequeueDecoderOutput(size_t bufferIndex, AMediaCodecBufferInfo* bufferInfo);
     bool dequeueEncoderOutput(size_t bufferIndex, AMediaCodecBufferInfo* info);
     bool tryEncoderOutput(long timeOutUs);
     bool waitForAllEncoderOutputs();
     bool queueEOS();
     bool enqueueDecoderEOS(size_t bufferIndex);
     bool doWork(int frameLimit);
     bool hasSeenError() { return mAsyncHandleDecoder.getError() || mAsyncHandleEncoder.getError(); }

   public:
     CodecEncoderSurfaceTest(const char* mime, int bitrate, int framerate);
     ~CodecEncoderSurfaceTest();

     bool testSimpleEncode(const char* encoder, const char* decoder, const char* srcPath,
                           const char* muxOutPath);
 };

 CodecEncoderSurfaceTest::CodecEncoderSurfaceTest(const char* mime, int bitrate, int framerate)
     : mMime{mime}, mEncBitrate{bitrate}, mEncFramerate{framerate} {
     mWindow = nullptr;
     mExtractor = nullptr;
     mDecFormat = nullptr;
     mEncFormat = nullptr;
     mMuxer = nullptr;
     mDecoder = nullptr;
     mEncoder = nullptr;
     resetContext(false, false);
     mMaxBFrames = 0;
     mMuxTrackID = -1;
 }

 CodecEncoderSurfaceTest::~CodecEncoderSurfaceTest() {
     deleteExtractor();
     if (mWindow) {
         ANativeWindow_release(mWindow);
         mWindow = nullptr;
     }
     if (mEncFormat) {
         AMediaFormat_delete(mEncFormat);
         mEncFormat = nullptr;
     }
     if (mMuxer) {
         AMediaMuxer_delete(mMuxer);
         mMuxer = nullptr;
     }
     if (mDecoder) {
         AMediaCodec_delete(mDecoder);
         mDecoder = nullptr;
     }
     if (mEncoder) {
         AMediaCodec_delete(mEncoder);
         mEncoder = nullptr;
     }
 }

 bool CodecEncoderSurfaceTest::setUpExtractor(const char* srcFile) {
     FILE* fp = fopen(srcFile, "rbe");
     struct stat buf {};
     if (fp && !fstat(fileno(fp), &buf)) {
         deleteExtractor();
         mExtractor = AMediaExtractor_new();
         media_status_t res =
                 AMediaExtractor_setDataSourceFd(mExtractor, fileno(fp), 0, buf.st_size);
         if (res != AMEDIA_OK) {
             deleteExtractor();
         } else {
             for (size_t trackID = 0; trackID < AMediaExtractor_getTrackCount(mExtractor);
                  trackID++) {
                 AMediaFormat* currFormat = AMediaExtractor_getTrackFormat(mExtractor, trackID);
                 const char* mime = nullptr;
                 AMediaFormat_getString(currFormat, AMEDIAFORMAT_KEY_MIME, &mime);
                 if (mime && strncmp(mime, "video/", strlen("video/")) == 0) {
                     AMediaExtractor_selectTrack(mExtractor, trackID);
                     AMediaFormat_setInt32(currFormat, AMEDIAFORMAT_KEY_COLOR_FORMAT,
                                           COLOR_FormatYUV420Flexible);
                     mDecFormat = currFormat;
                     break;
                 }
                 AMediaFormat_delete(currFormat);
             }
         }
     }
     if (fp) fclose(fp);
     return mDecFormat != nullptr;
 }

 void CodecEncoderSurfaceTest::deleteExtractor() {
     if (mExtractor) {
         AMediaExtractor_delete(mExtractor);
         mExtractor = nullptr;
     }
     if (mDecFormat) {
         AMediaFormat_delete(mDecFormat);
         mDecFormat = nullptr;
     }
 }

 bool CodecEncoderSurfaceTest::configureCodec(bool isAsync, bool signalEOSWithLastFrame) {
     resetContext(isAsync, signalEOSWithLastFrame);
     CHECK_STATUS(mAsyncHandleEncoder.setCallBack(mEncoder, isAsync),
                  "AMediaCodec_setAsyncNotifyCallback failed");
     CHECK_STATUS(AMediaCodec_configure(mEncoder, mEncFormat, nullptr, nullptr,
                                        AMEDIACODEC_CONFIGURE_FLAG_ENCODE),
                  "AMediaCodec_configure failed");
     CHECK_STATUS(AMediaCodec_createInputSurface(mEncoder, &mWindow),
                  "AMediaCodec_createInputSurface failed");
     CHECK_STATUS(mAsyncHandleDecoder.setCallBack(mDecoder, isAsync),
                  "AMediaCodec_setAsyncNotifyCallback failed");
     CHECK_STATUS(AMediaCodec_configure(mDecoder, mDecFormat, mWindow, nullptr, 0),
                  "AMediaCodec_configure failed");
     return !hasSeenError();
 }

 void CodecEncoderSurfaceTest::resetContext(bool isAsync, bool signalEOSWithLastFrame) {
     mAsyncHandleDecoder.resetContext();
     mAsyncHandleEncoder.resetContext();
     mIsCodecInAsyncMode = isAsync;
     mSawDecInputEOS = false;
     mSawDecOutputEOS = false;
     mSawEncOutputEOS = false;
     mSignalEOSWithLastFrame = signalEOSWithLastFrame;
     mDecInputCount = 0;
     mDecOutputCount = 0;
     mEncOutputCount = 0;
 }

 void CodecEncoderSurfaceTest::setUpEncoderFormat() {
     if (mEncFormat) AMediaFormat_delete(mEncFormat);
     mEncFormat = AMediaFormat_new();
     int width, height;
     AMediaFormat_getInt32(mDecFormat, AMEDIAFORMAT_KEY_WIDTH, &width);
     AMediaFormat_getInt32(mDecFormat, AMEDIAFORMAT_KEY_HEIGHT, &height);
     AMediaFormat_setString(mEncFormat, AMEDIAFORMAT_KEY_MIME, mMime);
     AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_WIDTH, width);
     AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_HEIGHT, height);
     AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_BIT_RATE, mEncBitrate);
     AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_FRAME_RATE, mEncFramerate);
     AMediaFormat_setInt32(mEncFormat, TBD_AMEDIACODEC_PARAMETER_KEY_MAX_B_FRAMES, mMaxBFrames);
     AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_COLOR_FORMAT, COLOR_FormatSurface);
     AMediaFormat_setFloat(mEncFormat, AMEDIAFORMAT_KEY_I_FRAME_INTERVAL, 1.0F);
 }

 bool CodecEncoderSurfaceTest::enqueueDecoderEOS(size_t bufferIndex) {
     if (!hasSeenError() && !mSawDecInputEOS) {
         CHECK_STATUS(AMediaCodec_queueInputBuffer(mDecoder, bufferIndex, 0, 0, 0,
                                                   AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM),
                      "Queued Decoder End of Stream Failed");
         mSawDecInputEOS = true;
         ALOGV("Queued Decoder End of Stream");
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::enqueueDecoderInput(size_t bufferIndex) {
     if (AMediaExtractor_getSampleSize(mExtractor) < 0) {
         return enqueueDecoderEOS(bufferIndex);
     } else {
         uint32_t flags = 0;
         size_t bufSize = 0;
         uint8_t* buf = AMediaCodec_getInputBuffer(mDecoder, bufferIndex, &bufSize);
         if (buf == nullptr) {
             ALOGE("AMediaCodec_getInputBuffer failed");
             return false;
         }
         ssize_t size = AMediaExtractor_getSampleSize(mExtractor);
         int64_t pts = AMediaExtractor_getSampleTime(mExtractor);
         if (size > bufSize) {
             ALOGE("extractor sample size exceeds codec input buffer size %zu %zu", size, bufSize);
             return false;
         }
         if (size != AMediaExtractor_readSampleData(mExtractor, buf, bufSize)) {
             ALOGE("AMediaExtractor_readSampleData failed");
             return false;
         }
         if (!AMediaExtractor_advance(mExtractor) && mSignalEOSWithLastFrame) {
             flags |= AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM;
             mSawDecInputEOS = true;
         }
         CHECK_STATUS(AMediaCodec_queueInputBuffer(mDecoder, bufferIndex, 0, size, pts, flags),
                      "AMediaCodec_queueInputBuffer failed");
         ALOGV("input: id: %zu  size: %zu  pts: %d  flags: %d", bufferIndex, size, (int)pts, flags);
         if (size > 0) {
             mOutputBuff->saveInPTS(pts);
             mDecInputCount++;
         }
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::dequeueDecoderOutput(size_t bufferIndex,
                                                    AMediaCodecBufferInfo* bufferInfo) {
     if ((bufferInfo->flags & AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM) != 0) {
         mSawDecOutputEOS = true;
     }
     if (bufferInfo->size > 0 && (bufferInfo->flags & AMEDIACODEC_BUFFER_FLAG_CODEC_CONFIG) == 0) {
         mDecOutputCount++;
     }
     ALOGV("output: id: %zu  size: %d  pts: %d  flags: %d", bufferIndex, bufferInfo->size,
           (int)bufferInfo->presentationTimeUs, bufferInfo->flags);
     CHECK_STATUS(AMediaCodec_releaseOutputBuffer(mDecoder, bufferIndex, mWindow != nullptr),
                  "AMediaCodec_releaseOutputBuffer failed");
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::dequeueEncoderOutput(size_t bufferIndex,
                                                    AMediaCodecBufferInfo* info) {
     if ((info->flags & AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM) != 0) {
         mSawEncOutputEOS = true;
     }
     if (info->size > 0) {
         size_t buffSize;
         uint8_t* buf = AMediaCodec_getOutputBuffer(mEncoder, bufferIndex, &buffSize);
         if (mSaveToMem) {
             mOutputBuff->saveToMemory(buf, info);
         }
         if (mMuxer != nullptr) {
             if (mMuxTrackID == -1) {
                 mMuxTrackID = AMediaMuxer_addTrack(mMuxer, AMediaCodec_getOutputFormat(mEncoder));
                 CHECK_STATUS(AMediaMuxer_start(mMuxer), "AMediaMuxer_start failed");
             }
             CHECK_STATUS(AMediaMuxer_writeSampleData(mMuxer, mMuxTrackID, buf, info),
                          "AMediaMuxer_writeSampleData failed");
         }
         if ((info->flags & AMEDIACODEC_BUFFER_FLAG_CODEC_CONFIG) == 0) {
             mOutputBuff->saveOutPTS(info->presentationTimeUs);
             mEncOutputCount++;
         }
     }
     ALOGV("output: id: %zu  size: %d  pts: %d  flags: %d", bufferIndex, info->size,
           (int)info->presentationTimeUs, info->flags);
     CHECK_STATUS(AMediaCodec_releaseOutputBuffer(mEncoder, bufferIndex, false),
                  "AMediaCodec_releaseOutputBuffer failed");
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::tryEncoderOutput(long timeOutUs) {
     if (mIsCodecInAsyncMode) {
         if (!hasSeenError() && !mSawEncOutputEOS) {
             callbackObject element = mAsyncHandleEncoder.getOutput();
             if (element.bufferIndex >= 0) {
                 if (!dequeueEncoderOutput(element.bufferIndex, &element.bufferInfo)) return false;
             }
         }
     } else {
         AMediaCodecBufferInfo outInfo;
         if (!mSawEncOutputEOS) {
             int bufferID = AMediaCodec_dequeueOutputBuffer(mEncoder, &outInfo, timeOutUs);
             if (bufferID >= 0) {
                 if (!dequeueEncoderOutput(bufferID, &outInfo)) return false;
             } else if (bufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
             } else if (bufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
             } else if (bufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
             } else {
                 ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)bufferID);
                 return false;
             }
         }
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::waitForAllEncoderOutputs() {
     if (mIsCodecInAsyncMode) {
         while (!hasSeenError() && !mSawEncOutputEOS) {
             if (!tryEncoderOutput(kQDeQTimeOutUs)) return false;
         }
     } else {
         while (!mSawEncOutputEOS) {
             if (!tryEncoderOutput(kQDeQTimeOutUs)) return false;
         }
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::queueEOS() {
     if (mIsCodecInAsyncMode) {
         if (!hasSeenError() && !mSawDecInputEOS) {
             callbackObject element = mAsyncHandleDecoder.getInput();
             if (element.bufferIndex >= 0) {
                 if (!enqueueDecoderEOS(element.bufferIndex)) return false;
             }
         }
     } else {
         if (!mSawDecInputEOS) {
             int bufferIndex = AMediaCodec_dequeueInputBuffer(mDecoder, -1);
             if (bufferIndex >= 0) {
                 if (!enqueueDecoderEOS(bufferIndex)) return false;
             } else {
                 ALOGE("unexpected return value from *_dequeueInputBufferBuffer: %d",
                       (int)bufferIndex);
                 return false;
             }
         }
     }

     if (mIsCodecInAsyncMode) {
         // output processing after queuing EOS is done in waitForAllOutputs()
         while (!hasSeenError() && !mSawDecOutputEOS) {
             callbackObject element = mAsyncHandleDecoder.getOutput();
             if (element.bufferIndex >= 0) {
                 if (!dequeueDecoderOutput(element.bufferIndex, &element.bufferInfo)) return false;
             }
             if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
             if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
                 if (!tryEncoderOutput(-1)) return false;
             }
         }
     } else {
         AMediaCodecBufferInfo outInfo;
         // output processing after queuing EOS is done in waitForAllOutputs()
         while (!mSawDecOutputEOS) {
             if (!mSawDecOutputEOS) {
                 ssize_t oBufferID =
                         AMediaCodec_dequeueOutputBuffer(mDecoder, &outInfo, kQDeQTimeOutUs);
                 if (oBufferID >= 0) {
                     if (!dequeueDecoderOutput(oBufferID, &outInfo)) return false;
                 } else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
                 } else if (oBufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
                 } else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
                 } else {
                     ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)oBufferID);
                     return false;
                 }
             }
             if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
             if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
                 if (!tryEncoderOutput(-1)) return false;
             }
         }
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::doWork(int frameLimit) {
     int frameCnt = 0;
     if (mIsCodecInAsyncMode) {
         // output processing after queuing EOS is done in waitForAllOutputs()
         while (!hasSeenError() && !mSawDecInputEOS && frameCnt < frameLimit) {
             callbackObject element = mAsyncHandleDecoder.getWork();
             if (element.bufferIndex >= 0) {
                 if (element.isInput) {
                     if (!enqueueDecoderInput(element.bufferIndex)) return false;
                     frameCnt++;
                 } else {
                     if (!dequeueDecoderOutput(element.bufferIndex, &element.bufferInfo)) {
                         return false;
                     }
                 }
             }
             // check decoder EOS
             if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
             // encoder output
             // TODO: remove fixed constant and change it according to encoder latency
             if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
                 if (!tryEncoderOutput(-1)) return false;
             }
         }
     } else {
         AMediaCodecBufferInfo outInfo;
         // output processing after queuing EOS is done in waitForAllOutputs()
         while (!mSawDecInputEOS && frameCnt < frameLimit) {
             ssize_t oBufferID = AMediaCodec_dequeueOutputBuffer(mDecoder, &outInfo, kQDeQTimeOutUs);
             if (oBufferID >= 0) {
                 if (!dequeueDecoderOutput(oBufferID, &outInfo)) return false;
             } else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
             } else if (oBufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
             } else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
             } else {
                 ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)oBufferID);
                 return false;
             }
             ssize_t iBufferId = AMediaCodec_dequeueInputBuffer(mDecoder, kQDeQTimeOutUs);
             if (iBufferId >= 0) {
                 if (!enqueueDecoderInput(iBufferId)) return false;
                 frameCnt++;
             } else if (iBufferId == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
             } else {
                 ALOGE("unexpected return value from *_dequeueInputBuffer: %d", (int)iBufferId);
                 return false;
             }
             if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
             // TODO: remove fixed constant and change it according to encoder latency
             if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
                 if (!tryEncoderOutput(-1)) return false;
             }
         }
     }
     return !hasSeenError();
 }

 bool CodecEncoderSurfaceTest::testSimpleEncode(const char* encoder, const char* decoder,
                                                const char* srcPath, const char* muxOutPath) {
     bool isPass = true;
     if (!setUpExtractor(srcPath)) {
         ALOGE("setUpExtractor failed");
         return false;
     }
     setUpEncoderFormat();
     bool muxOutput = true;

     /* TODO(b/149027258) */
     if (true) mSaveToMem = false;
     else mSaveToMem = true;
     auto ref = &mRefBuff;
     auto test = &mTestBuff;
     int loopCounter = 0;
     const bool boolStates[]{true, false};
     for (bool isAsync : boolStates) {
         if (!isPass) break;
         AMediaExtractor_seekTo(mExtractor, 0, AMEDIAEXTRACTOR_SEEK_CLOSEST_SYNC);
         mOutputBuff = loopCounter == 0 ? ref : test;
         mOutputBuff->reset();

         /* TODO(b/147348711) */
         /* Instead of create and delete codec at every iteration, we would like to create
          * once and use it for all iterations and delete before exiting */
         mEncoder = AMediaCodec_createCodecByName(encoder);
         mDecoder = AMediaCodec_createCodecByName(decoder);
         if (!mDecoder || !mEncoder) {
             ALOGE("unable to create media codec by name %s or %s", encoder, decoder);
             isPass = false;
             continue;
         }

         FILE* ofp = nullptr;
         if (muxOutput && loopCounter == 0) {
             int muxerFormat = 0;
             if (!strcmp(mMime, AMEDIA_MIMETYPE_VIDEO_VP8) ||
                 !strcmp(mMime, AMEDIA_MIMETYPE_VIDEO_VP9)) {
                 muxerFormat = OUTPUT_FORMAT_WEBM;
             } else {
                 muxerFormat = OUTPUT_FORMAT_MPEG_4;
             }
             ofp = fopen(muxOutPath, "wbe+");
             if (ofp) {
                 mMuxer = AMediaMuxer_new(fileno(ofp), (OutputFormat)muxerFormat);
             }
         }
         if (!configureCodec(mIsCodecInAsyncMode, mSignalEOSWithLastFrame)) return false;
         CHECK_STATUS(AMediaCodec_start(mEncoder), "AMediaCodec_start failed");
         CHECK_STATUS(AMediaCodec_start(mDecoder), "AMediaCodec_start failed");
         if (!doWork(INT32_MAX)) return false;
         if (!queueEOS()) return false;
         if (!waitForAllEncoderOutputs()) return false;
         if (muxOutput) {
             if (mMuxer != nullptr) {
                 CHECK_STATUS(AMediaMuxer_stop(mMuxer), "AMediaMuxer_stop failed");
                 mMuxTrackID = -1;
                 CHECK_STATUS(AMediaMuxer_delete(mMuxer), "AMediaMuxer_delete failed");
                 mMuxer = nullptr;
             }
             if (ofp) fclose(ofp);
         }
         CHECK_STATUS(AMediaCodec_stop(mDecoder), "AMediaCodec_stop failed");
         CHECK_STATUS(AMediaCodec_stop(mEncoder), "AMediaCodec_stop failed");
         char log[1000];
         snprintf(log, sizeof(log), "format: %s \n codec: %s, file: %s, mode: %s:: ",
                  AMediaFormat_toString(mEncFormat), encoder, srcPath, (isAsync ? "async" : "sync"));
         CHECK_ERR((hasSeenError()), log, "has seen error", isPass);
         CHECK_ERR((0 == mDecInputCount), log, "no input sent", isPass);
         CHECK_ERR((0 == mDecOutputCount), log, "no decoder output received", isPass);
         CHECK_ERR((0 == mEncOutputCount), log, "no encoder output received", isPass);
         CHECK_ERR((mDecInputCount != mDecOutputCount), log, "decoder input count != output count",
                   isPass);
         /* TODO(b/153127506)
          *  Currently disabling all encoder output checks. Added checks only for encoder timeStamp
          *  is in increasing order or not.
          *  Once issue is fixed remove increasing timestamp check and enable encoder checks.
          */
         /*CHECK_ERR((mEncOutputCount != mDecOutputCount), log,
                   "encoder output count != decoder output count", isPass);
         CHECK_ERR((loopCounter != 0 && !ref->equals(test)), log, "output is flaky", isPass);
         CHECK_ERR((loopCounter == 0 && !ref->isOutPtsListIdenticalToInpPtsList(mMaxBFrames != 0)),
                   log, "input pts list and output pts list are not identical", isPass);*/
         CHECK_ERR(loopCounter == 0 && (!ref->isPtsStrictlyIncreasing(INT32_MIN)), log,
                   "Ref pts is not strictly increasing", isPass);
         CHECK_ERR(loopCounter != 0 && (!test->isPtsStrictlyIncreasing(INT32_MIN)), log,
                   "Test pts is not strictly increasing", isPass);

         loopCounter++;
         ANativeWindow_release(mWindow);
         mWindow = nullptr;
         CHECK_STATUS(AMediaCodec_delete(mEncoder), "AMediaCodec_delete failed");
         mEncoder = nullptr;
         CHECK_STATUS(AMediaCodec_delete(mDecoder), "AMediaCodec_delete failed");
         mDecoder = nullptr;
     }
     return isPass;
 }

 static jboolean nativeTestSimpleEncode(JNIEnv* env, jobject, jstring jEncoder, jstring jDecoder,
                                        jstring jMime, jstring jtestFile, jstring jmuxFile,
                                        jint jBitrate, jint jFramerate) {
     const char* cEncoder = env->GetStringUTFChars(jEncoder, nullptr);
     const char* cDecoder = env->GetStringUTFChars(jDecoder, nullptr);
     const char* cMime = env->GetStringUTFChars(jMime, nullptr);
     const char* cTestFile = env->GetStringUTFChars(jtestFile, nullptr);
     const char* cMuxFile = env->GetStringUTFChars(jmuxFile, nullptr);
     auto codecEncoderSurfaceTest =
             new CodecEncoderSurfaceTest(cMime, (int)jBitrate, (int)jFramerate);
     bool isPass =
             codecEncoderSurfaceTest->testSimpleEncode(cEncoder, cDecoder, cTestFile, cMuxFile);
     delete codecEncoderSurfaceTest;
     env->ReleaseStringUTFChars(jEncoder, cEncoder);
     env->ReleaseStringUTFChars(jDecoder, cDecoder);
     env->ReleaseStringUTFChars(jMime, cMime);
     env->ReleaseStringUTFChars(jtestFile, cTestFile);
     env->ReleaseStringUTFChars(jmuxFile, cMuxFile);
     return static_cast<jboolean>(isPass);
 }

 int registerAndroidMediaV2CtsEncoderSurfaceTest(JNIEnv* env) {
     const JNINativeMethod methodTable[] = {
             {"nativeTestSimpleEncode",
              "(Ljava/lang/String;Ljava/lang/String;Ljava/lang/String;Ljava/lang/String;Ljava/lang/"
              "String;II)Z",
              (void*)nativeTestSimpleEncode},
     };
     jclass c = env->FindClass("android/mediav2/cts/CodecEncoderSurfaceTest");
     return env->RegisterNatives(c, methodTable, sizeof(methodTable) / sizeof(JNINativeMethod));
 }
	/*
	* Copyright (C) 2020 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.
	*/

	//#define LOG_NDEBUG 0
	#define LOG_TAG "NativeCodecEncoderSurfaceTest"
	#include <log/log.h>
	#include <android/native_window_jni.h>
	#include <NdkMediaExtractor.h>
	#include <NdkMediaMuxer.h>
	#include <jni.h>
	#include <sys/stat.h>

	#include "NativeCodecTestBase.h"
	#include "NativeMediaCommon.h"

	class CodecEncoderSurfaceTest {
	private:
	const long kQDeQTimeOutUs = 5000;
	const char* mMime;
	ANativeWindow* mWindow;
	AMediaExtractor* mExtractor;
	AMediaFormat* mDecFormat;
	AMediaFormat* mEncFormat;
	AMediaMuxer* mMuxer;
	AMediaCodec* mDecoder;
	AMediaCodec* mEncoder;
	CodecAsyncHandler mAsyncHandleDecoder;
	CodecAsyncHandler mAsyncHandleEncoder;
	bool mIsCodecInAsyncMode;
	bool mSawDecInputEOS;
	bool mSawDecOutputEOS;
	bool mSawEncOutputEOS;
	bool mSignalEOSWithLastFrame;
	int mDecInputCount;
	int mDecOutputCount;
	int mEncOutputCount;
	int mEncBitrate;
	int mEncFramerate;
	int mMaxBFrames;
	int mMuxTrackID;

	OutputManager* mOutputBuff;
	OutputManager mRefBuff;
	OutputManager mTestBuff;
	bool mSaveToMem;

	bool setUpExtractor(const char* srcPath);
	void deleteExtractor();
	bool configureCodec(bool isAsync, bool signalEOSWithLastFrame);
	void resetContext(bool isAsync, bool signalEOSWithLastFrame);
	void setUpEncoderFormat();
	bool enqueueDecoderInput(size_t bufferIndex);
	bool dequeueDecoderOutput(size_t bufferIndex, AMediaCodecBufferInfo* bufferInfo);
	bool dequeueEncoderOutput(size_t bufferIndex, AMediaCodecBufferInfo* info);
	bool tryEncoderOutput(long timeOutUs);
	bool waitForAllEncoderOutputs();
	bool queueEOS();
	bool enqueueDecoderEOS(size_t bufferIndex);
	bool doWork(int frameLimit);
	bool hasSeenError() { return mAsyncHandleDecoder.getError() \|\| mAsyncHandleEncoder.getError(); }

	public:
	CodecEncoderSurfaceTest(const char* mime, int bitrate, int framerate);
	~CodecEncoderSurfaceTest();

	bool testSimpleEncode(const char* encoder, const char* decoder, const char* srcPath,
	const char* muxOutPath);
	};

	CodecEncoderSurfaceTest::CodecEncoderSurfaceTest(const char* mime, int bitrate, int framerate)
	: mMime{mime}, mEncBitrate{bitrate}, mEncFramerate{framerate} {
	mWindow = nullptr;
	mExtractor = nullptr;
	mDecFormat = nullptr;
	mEncFormat = nullptr;
	mMuxer = nullptr;
	mDecoder = nullptr;
	mEncoder = nullptr;
	resetContext(false, false);
	mMaxBFrames = 0;
	mMuxTrackID = -1;
	}

	CodecEncoderSurfaceTest::~CodecEncoderSurfaceTest() {
	deleteExtractor();
	if (mWindow) {
	ANativeWindow_release(mWindow);
	mWindow = nullptr;
	}
	if (mEncFormat) {
	AMediaFormat_delete(mEncFormat);
	mEncFormat = nullptr;
	}
	if (mMuxer) {
	AMediaMuxer_delete(mMuxer);
	mMuxer = nullptr;
	}
	if (mDecoder) {
	AMediaCodec_delete(mDecoder);
	mDecoder = nullptr;
	}
	if (mEncoder) {
	AMediaCodec_delete(mEncoder);
	mEncoder = nullptr;
	}
	}

	bool CodecEncoderSurfaceTest::setUpExtractor(const char* srcFile) {
	FILE* fp = fopen(srcFile, "rbe");
	struct stat buf {};
	if (fp && !fstat(fileno(fp), &buf)) {
	deleteExtractor();
	mExtractor = AMediaExtractor_new();
	media_status_t res =
	AMediaExtractor_setDataSourceFd(mExtractor, fileno(fp), 0, buf.st_size);
	if (res != AMEDIA_OK) {
	deleteExtractor();
	} else {
	for (size_t trackID = 0; trackID < AMediaExtractor_getTrackCount(mExtractor);
	trackID++) {
	AMediaFormat* currFormat = AMediaExtractor_getTrackFormat(mExtractor, trackID);
	const char* mime = nullptr;
	AMediaFormat_getString(currFormat, AMEDIAFORMAT_KEY_MIME, &mime);
	if (mime && strncmp(mime, "video/", strlen("video/")) == 0) {
	AMediaExtractor_selectTrack(mExtractor, trackID);
	AMediaFormat_setInt32(currFormat, AMEDIAFORMAT_KEY_COLOR_FORMAT,
	COLOR_FormatYUV420Flexible);
	mDecFormat = currFormat;
	break;
	}
	AMediaFormat_delete(currFormat);
	}
	}
	}
	if (fp) fclose(fp);
	return mDecFormat != nullptr;
	}

	void CodecEncoderSurfaceTest::deleteExtractor() {
	if (mExtractor) {
	AMediaExtractor_delete(mExtractor);
	mExtractor = nullptr;
	}
	if (mDecFormat) {
	AMediaFormat_delete(mDecFormat);
	mDecFormat = nullptr;
	}
	}

	bool CodecEncoderSurfaceTest::configureCodec(bool isAsync, bool signalEOSWithLastFrame) {
	resetContext(isAsync, signalEOSWithLastFrame);
	CHECK_STATUS(mAsyncHandleEncoder.setCallBack(mEncoder, isAsync),
	"AMediaCodec_setAsyncNotifyCallback failed");
	CHECK_STATUS(AMediaCodec_configure(mEncoder, mEncFormat, nullptr, nullptr,
	AMEDIACODEC_CONFIGURE_FLAG_ENCODE),
	"AMediaCodec_configure failed");
	CHECK_STATUS(AMediaCodec_createInputSurface(mEncoder, &mWindow),
	"AMediaCodec_createInputSurface failed");
	CHECK_STATUS(mAsyncHandleDecoder.setCallBack(mDecoder, isAsync),
	"AMediaCodec_setAsyncNotifyCallback failed");
	CHECK_STATUS(AMediaCodec_configure(mDecoder, mDecFormat, mWindow, nullptr, 0),
	"AMediaCodec_configure failed");
	return !hasSeenError();
	}

	void CodecEncoderSurfaceTest::resetContext(bool isAsync, bool signalEOSWithLastFrame) {
	mAsyncHandleDecoder.resetContext();
	mAsyncHandleEncoder.resetContext();
	mIsCodecInAsyncMode = isAsync;
	mSawDecInputEOS = false;
	mSawDecOutputEOS = false;
	mSawEncOutputEOS = false;
	mSignalEOSWithLastFrame = signalEOSWithLastFrame;
	mDecInputCount = 0;
	mDecOutputCount = 0;
	mEncOutputCount = 0;
	}

	void CodecEncoderSurfaceTest::setUpEncoderFormat() {
	if (mEncFormat) AMediaFormat_delete(mEncFormat);
	mEncFormat = AMediaFormat_new();
	int width, height;
	AMediaFormat_getInt32(mDecFormat, AMEDIAFORMAT_KEY_WIDTH, &width);
	AMediaFormat_getInt32(mDecFormat, AMEDIAFORMAT_KEY_HEIGHT, &height);
	AMediaFormat_setString(mEncFormat, AMEDIAFORMAT_KEY_MIME, mMime);
	AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_WIDTH, width);
	AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_HEIGHT, height);
	AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_BIT_RATE, mEncBitrate);
	AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_FRAME_RATE, mEncFramerate);
	AMediaFormat_setInt32(mEncFormat, TBD_AMEDIACODEC_PARAMETER_KEY_MAX_B_FRAMES, mMaxBFrames);
	AMediaFormat_setInt32(mEncFormat, AMEDIAFORMAT_KEY_COLOR_FORMAT, COLOR_FormatSurface);
	AMediaFormat_setFloat(mEncFormat, AMEDIAFORMAT_KEY_I_FRAME_INTERVAL, 1.0F);
	}

	bool CodecEncoderSurfaceTest::enqueueDecoderEOS(size_t bufferIndex) {
	if (!hasSeenError() && !mSawDecInputEOS) {
	CHECK_STATUS(AMediaCodec_queueInputBuffer(mDecoder, bufferIndex, 0, 0, 0,
	AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM),
	"Queued Decoder End of Stream Failed");
	mSawDecInputEOS = true;
	ALOGV("Queued Decoder End of Stream");
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::enqueueDecoderInput(size_t bufferIndex) {
	if (AMediaExtractor_getSampleSize(mExtractor) < 0) {
	return enqueueDecoderEOS(bufferIndex);
	} else {
	uint32_t flags = 0;
	size_t bufSize = 0;
	uint8_t* buf = AMediaCodec_getInputBuffer(mDecoder, bufferIndex, &bufSize);
	if (buf == nullptr) {
	ALOGE("AMediaCodec_getInputBuffer failed");
	return false;
	}
	ssize_t size = AMediaExtractor_getSampleSize(mExtractor);
	int64_t pts = AMediaExtractor_getSampleTime(mExtractor);
	if (size > bufSize) {
	ALOGE("extractor sample size exceeds codec input buffer size %zu %zu", size, bufSize);
	return false;
	}
	if (size != AMediaExtractor_readSampleData(mExtractor, buf, bufSize)) {
	ALOGE("AMediaExtractor_readSampleData failed");
	return false;
	}
	if (!AMediaExtractor_advance(mExtractor) && mSignalEOSWithLastFrame) {
	flags \|= AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM;
	mSawDecInputEOS = true;
	}
	CHECK_STATUS(AMediaCodec_queueInputBuffer(mDecoder, bufferIndex, 0, size, pts, flags),
	"AMediaCodec_queueInputBuffer failed");
	ALOGV("input: id: %zu size: %zu pts: %d flags: %d", bufferIndex, size, (int)pts, flags);
	if (size > 0) {
	mOutputBuff->saveInPTS(pts);
	mDecInputCount++;
	}
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::dequeueDecoderOutput(size_t bufferIndex,
	AMediaCodecBufferInfo* bufferInfo) {
	if ((bufferInfo->flags & AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM) != 0) {
	mSawDecOutputEOS = true;
	}
	if (bufferInfo->size > 0 && (bufferInfo->flags & AMEDIACODEC_BUFFER_FLAG_CODEC_CONFIG) == 0) {
	mDecOutputCount++;
	}
	ALOGV("output: id: %zu size: %d pts: %d flags: %d", bufferIndex, bufferInfo->size,
	(int)bufferInfo->presentationTimeUs, bufferInfo->flags);
	CHECK_STATUS(AMediaCodec_releaseOutputBuffer(mDecoder, bufferIndex, mWindow != nullptr),
	"AMediaCodec_releaseOutputBuffer failed");
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::dequeueEncoderOutput(size_t bufferIndex,
	AMediaCodecBufferInfo* info) {
	if ((info->flags & AMEDIACODEC_BUFFER_FLAG_END_OF_STREAM) != 0) {
	mSawEncOutputEOS = true;
	}
	if (info->size > 0) {
	size_t buffSize;
	uint8_t* buf = AMediaCodec_getOutputBuffer(mEncoder, bufferIndex, &buffSize);
	if (mSaveToMem) {
	mOutputBuff->saveToMemory(buf, info);
	}
	if (mMuxer != nullptr) {
	if (mMuxTrackID == -1) {
	mMuxTrackID = AMediaMuxer_addTrack(mMuxer, AMediaCodec_getOutputFormat(mEncoder));
	CHECK_STATUS(AMediaMuxer_start(mMuxer), "AMediaMuxer_start failed");
	}
	CHECK_STATUS(AMediaMuxer_writeSampleData(mMuxer, mMuxTrackID, buf, info),
	"AMediaMuxer_writeSampleData failed");
	}
	if ((info->flags & AMEDIACODEC_BUFFER_FLAG_CODEC_CONFIG) == 0) {
	mOutputBuff->saveOutPTS(info->presentationTimeUs);
	mEncOutputCount++;
	}
	}
	ALOGV("output: id: %zu size: %d pts: %d flags: %d", bufferIndex, info->size,
	(int)info->presentationTimeUs, info->flags);
	CHECK_STATUS(AMediaCodec_releaseOutputBuffer(mEncoder, bufferIndex, false),
	"AMediaCodec_releaseOutputBuffer failed");
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::tryEncoderOutput(long timeOutUs) {
	if (mIsCodecInAsyncMode) {
	if (!hasSeenError() && !mSawEncOutputEOS) {
	callbackObject element = mAsyncHandleEncoder.getOutput();
	if (element.bufferIndex >= 0) {
	if (!dequeueEncoderOutput(element.bufferIndex, &element.bufferInfo)) return false;
	}
	}
	} else {
	AMediaCodecBufferInfo outInfo;
	if (!mSawEncOutputEOS) {
	int bufferID = AMediaCodec_dequeueOutputBuffer(mEncoder, &outInfo, timeOutUs);
	if (bufferID >= 0) {
	if (!dequeueEncoderOutput(bufferID, &outInfo)) return false;
	} else if (bufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
	} else if (bufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
	} else if (bufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
	} else {
	ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)bufferID);
	return false;
	}
	}
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::waitForAllEncoderOutputs() {
	if (mIsCodecInAsyncMode) {
	while (!hasSeenError() && !mSawEncOutputEOS) {
	if (!tryEncoderOutput(kQDeQTimeOutUs)) return false;
	}
	} else {
	while (!mSawEncOutputEOS) {
	if (!tryEncoderOutput(kQDeQTimeOutUs)) return false;
	}
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::queueEOS() {
	if (mIsCodecInAsyncMode) {
	if (!hasSeenError() && !mSawDecInputEOS) {
	callbackObject element = mAsyncHandleDecoder.getInput();
	if (element.bufferIndex >= 0) {
	if (!enqueueDecoderEOS(element.bufferIndex)) return false;
	}
	}
	} else {
	if (!mSawDecInputEOS) {
	int bufferIndex = AMediaCodec_dequeueInputBuffer(mDecoder, -1);
	if (bufferIndex >= 0) {
	if (!enqueueDecoderEOS(bufferIndex)) return false;
	} else {
	ALOGE("unexpected return value from *_dequeueInputBufferBuffer: %d",
	(int)bufferIndex);
	return false;
	}
	}
	}

	if (mIsCodecInAsyncMode) {
	// output processing after queuing EOS is done in waitForAllOutputs()
	while (!hasSeenError() && !mSawDecOutputEOS) {
	callbackObject element = mAsyncHandleDecoder.getOutput();
	if (element.bufferIndex >= 0) {
	if (!dequeueDecoderOutput(element.bufferIndex, &element.bufferInfo)) return false;
	}
	if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
	if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
	if (!tryEncoderOutput(-1)) return false;
	}
	}
	} else {
	AMediaCodecBufferInfo outInfo;
	// output processing after queuing EOS is done in waitForAllOutputs()
	while (!mSawDecOutputEOS) {
	if (!mSawDecOutputEOS) {
	ssize_t oBufferID =
	AMediaCodec_dequeueOutputBuffer(mDecoder, &outInfo, kQDeQTimeOutUs);
	if (oBufferID >= 0) {
	if (!dequeueDecoderOutput(oBufferID, &outInfo)) return false;
	} else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
	} else if (oBufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
	} else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
	} else {
	ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)oBufferID);
	return false;
	}
	}
	if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
	if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
	if (!tryEncoderOutput(-1)) return false;
	}
	}
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::doWork(int frameLimit) {
	int frameCnt = 0;
	if (mIsCodecInAsyncMode) {
	// output processing after queuing EOS is done in waitForAllOutputs()
	while (!hasSeenError() && !mSawDecInputEOS && frameCnt < frameLimit) {
	callbackObject element = mAsyncHandleDecoder.getWork();
	if (element.bufferIndex >= 0) {
	if (element.isInput) {
	if (!enqueueDecoderInput(element.bufferIndex)) return false;
	frameCnt++;
	} else {
	if (!dequeueDecoderOutput(element.bufferIndex, &element.bufferInfo)) {
	return false;
	}
	}
	}
	// check decoder EOS
	if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
	// encoder output
	// TODO: remove fixed constant and change it according to encoder latency
	if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
	if (!tryEncoderOutput(-1)) return false;
	}
	}
	} else {
	AMediaCodecBufferInfo outInfo;
	// output processing after queuing EOS is done in waitForAllOutputs()
	while (!mSawDecInputEOS && frameCnt < frameLimit) {
	ssize_t oBufferID = AMediaCodec_dequeueOutputBuffer(mDecoder, &outInfo, kQDeQTimeOutUs);
	if (oBufferID >= 0) {
	if (!dequeueDecoderOutput(oBufferID, &outInfo)) return false;
	} else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_FORMAT_CHANGED) {
	} else if (oBufferID == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
	} else if (oBufferID == AMEDIACODEC_INFO_OUTPUT_BUFFERS_CHANGED) {
	} else {
	ALOGE("unexpected return value from *_dequeueOutputBuffer: %d", (int)oBufferID);
	return false;
	}
	ssize_t iBufferId = AMediaCodec_dequeueInputBuffer(mDecoder, kQDeQTimeOutUs);
	if (iBufferId >= 0) {
	if (!enqueueDecoderInput(iBufferId)) return false;
	frameCnt++;
	} else if (iBufferId == AMEDIACODEC_INFO_TRY_AGAIN_LATER) {
	} else {
	ALOGE("unexpected return value from *_dequeueInputBuffer: %d", (int)iBufferId);
	return false;
	}
	if (mSawDecOutputEOS) AMediaCodec_signalEndOfInputStream(mEncoder);
	// TODO: remove fixed constant and change it according to encoder latency
	if (mDecOutputCount - mEncOutputCount > mMaxBFrames) {
	if (!tryEncoderOutput(-1)) return false;
	}
	}
	}
	return !hasSeenError();
	}

	bool CodecEncoderSurfaceTest::testSimpleEncode(const char* encoder, const char* decoder,
	const char* srcPath, const char* muxOutPath) {
	bool isPass = true;
	if (!setUpExtractor(srcPath)) {
	ALOGE("setUpExtractor failed");
	return false;
	}
	setUpEncoderFormat();
	bool muxOutput = true;

	/* TODO(b/149027258) */
	if (true) mSaveToMem = false;
	else mSaveToMem = true;
	auto ref = &mRefBuff;
	auto test = &mTestBuff;
	int loopCounter = 0;
	const bool boolStates[]{true, false};
	for (bool isAsync : boolStates) {
	if (!isPass) break;
	AMediaExtractor_seekTo(mExtractor, 0, AMEDIAEXTRACTOR_SEEK_CLOSEST_SYNC);
	mOutputBuff = loopCounter == 0 ? ref : test;
	mOutputBuff->reset();

	/* TODO(b/147348711) */
	/* Instead of create and delete codec at every iteration, we would like to create
	* once and use it for all iterations and delete before exiting */
	mEncoder = AMediaCodec_createCodecByName(encoder);
	mDecoder = AMediaCodec_createCodecByName(decoder);
	if (!mDecoder \|\| !mEncoder) {
	ALOGE("unable to create media codec by name %s or %s", encoder, decoder);
	isPass = false;
	continue;
	}

	FILE* ofp = nullptr;
	if (muxOutput && loopCounter == 0) {
	int muxerFormat = 0;
	if (!strcmp(mMime, AMEDIA_MIMETYPE_VIDEO_VP8) \|\|
	!strcmp(mMime, AMEDIA_MIMETYPE_VIDEO_VP9)) {
	muxerFormat = OUTPUT_FORMAT_WEBM;
	} else {
	muxerFormat = OUTPUT_FORMAT_MPEG_4;
	}
	ofp = fopen(muxOutPath, "wbe+");
	if (ofp) {
	mMuxer = AMediaMuxer_new(fileno(ofp), (OutputFormat)muxerFormat);
	}
	}
	if (!configureCodec(mIsCodecInAsyncMode, mSignalEOSWithLastFrame)) return false;
	CHECK_STATUS(AMediaCodec_start(mEncoder), "AMediaCodec_start failed");
	CHECK_STATUS(AMediaCodec_start(mDecoder), "AMediaCodec_start failed");
	if (!doWork(INT32_MAX)) return false;
	if (!queueEOS()) return false;
	if (!waitForAllEncoderOutputs()) return false;
	if (muxOutput) {
	if (mMuxer != nullptr) {
	CHECK_STATUS(AMediaMuxer_stop(mMuxer), "AMediaMuxer_stop failed");
	mMuxTrackID = -1;
	CHECK_STATUS(AMediaMuxer_delete(mMuxer), "AMediaMuxer_delete failed");
	mMuxer = nullptr;
	}
	if (ofp) fclose(ofp);
	}
	CHECK_STATUS(AMediaCodec_stop(mDecoder), "AMediaCodec_stop failed");
	CHECK_STATUS(AMediaCodec_stop(mEncoder), "AMediaCodec_stop failed");
	char log[1000];
	snprintf(log, sizeof(log), "format: %s \n codec: %s, file: %s, mode: %s:: ",
	AMediaFormat_toString(mEncFormat), encoder, srcPath, (isAsync ? "async" : "sync"));
	CHECK_ERR((hasSeenError()), log, "has seen error", isPass);
	CHECK_ERR((0 == mDecInputCount), log, "no input sent", isPass);
	CHECK_ERR((0 == mDecOutputCount), log, "no decoder output received", isPass);
	CHECK_ERR((0 == mEncOutputCount), log, "no encoder output received", isPass);
	CHECK_ERR((mDecInputCount != mDecOutputCount), log, "decoder input count != output count",
	isPass);
	/* TODO(b/153127506)
	* Currently disabling all encoder output checks. Added checks only for encoder timeStamp
	* is in increasing order or not.
	* Once issue is fixed remove increasing timestamp check and enable encoder checks.
	*/
	/*CHECK_ERR((mEncOutputCount != mDecOutputCount), log,
	"encoder output count != decoder output count", isPass);
	CHECK_ERR((loopCounter != 0 && !ref->equals(test)), log, "output is flaky", isPass);
	CHECK_ERR((loopCounter == 0 && !ref->isOutPtsListIdenticalToInpPtsList(mMaxBFrames != 0)),
	log, "input pts list and output pts list are not identical", isPass);*/
	CHECK_ERR(loopCounter == 0 && (!ref->isPtsStrictlyIncreasing(INT32_MIN)), log,
	"Ref pts is not strictly increasing", isPass);
	CHECK_ERR(loopCounter != 0 && (!test->isPtsStrictlyIncreasing(INT32_MIN)), log,
	"Test pts is not strictly increasing", isPass);

	loopCounter++;
	ANativeWindow_release(mWindow);
	mWindow = nullptr;
	CHECK_STATUS(AMediaCodec_delete(mEncoder), "AMediaCodec_delete failed");
	mEncoder = nullptr;
	CHECK_STATUS(AMediaCodec_delete(mDecoder), "AMediaCodec_delete failed");
	mDecoder = nullptr;
	}
	return isPass;
	}

	static jboolean nativeTestSimpleEncode(JNIEnv* env, jobject, jstring jEncoder, jstring jDecoder,
	jstring jMime, jstring jtestFile, jstring jmuxFile,
	jint jBitrate, jint jFramerate) {
	const char* cEncoder = env->GetStringUTFChars(jEncoder, nullptr);
	const char* cDecoder = env->GetStringUTFChars(jDecoder, nullptr);
	const char* cMime = env->GetStringUTFChars(jMime, nullptr);
	const char* cTestFile = env->GetStringUTFChars(jtestFile, nullptr);
	const char* cMuxFile = env->GetStringUTFChars(jmuxFile, nullptr);
	auto codecEncoderSurfaceTest =
	new CodecEncoderSurfaceTest(cMime, (int)jBitrate, (int)jFramerate);
	bool isPass =
	codecEncoderSurfaceTest->testSimpleEncode(cEncoder, cDecoder, cTestFile, cMuxFile);
	delete codecEncoderSurfaceTest;
	env->ReleaseStringUTFChars(jEncoder, cEncoder);
	env->ReleaseStringUTFChars(jDecoder, cDecoder);
	env->ReleaseStringUTFChars(jMime, cMime);
	env->ReleaseStringUTFChars(jtestFile, cTestFile);
	env->ReleaseStringUTFChars(jmuxFile, cMuxFile);
	return static_cast<jboolean>(isPass);
	}

	int registerAndroidMediaV2CtsEncoderSurfaceTest(JNIEnv* env) {
	const JNINativeMethod methodTable[] = {
	{"nativeTestSimpleEncode",
	"(Ljava/lang/String;Ljava/lang/String;Ljava/lang/String;Ljava/lang/String;Ljava/lang/"
	"String;II)Z",
	(void*)nativeTestSimpleEncode},
	};
	jclass c = env->FindClass("android/mediav2/cts/CodecEncoderSurfaceTest");
	return env->RegisterNatives(c, methodTable, sizeof(methodTable) / sizeof(JNINativeMethod));
	}