x264是一种免费的、具有更优秀算法的符合H.264/MPEG-4 AVC视频压缩编码标准格式的编码库。它同xvid一样都是开源项目,但x264是采用H.264标准的,而xvid是采用MPEG-4早期标准的。由于H.264是2003年正式发布的最新的视频编码标准,因此,在通常情况下,x264压缩出的视频文件在相同质量下要比xvid压缩出的文件要小,或者也可以说,在相同体积下比xvid压缩出的文件质量要好。它符合GPL许可证。
iOS视频编码分为硬编码和软编码:硬编码就是利用手机专用的硬件进行编码,软编码是用CPU进行编码。由于苹果在iOS8开放的硬编码的API,故现在大多数的直播应用都是采用的硬编码。
从iOS8开始,苹果开放了硬解码和硬编码API,框架为 VideoToolbox.framework, 此框架需要在iOS8及以上的系统上才能使用。
此框架中的硬解码API是几个纯C函数,在任何OC或者 C++代码里都可以使用。使用的时候,首先,要把VideoToolbox.framework 添加到工程里,并且在要使用该API的文件中包含头文件#include
直接上代码来说明,首先是定义了编码所需的变量
@interface CLHardwareVideoEncoder (){
VTCompressionSessionRef compressionSession;
NSInteger frameCount;
NSData *sps;
NSData *pps;
FILE *fp;
BOOL enabledWriteVideoFile;
}
@property (nonatomic, strong) CLLiveVideoConfiguration *configuration;
@property (nonatomic,weak) id h264Delegate;
@property (nonatomic) BOOL isBackGround;
@property (nonatomic) NSInteger currentVideoBitRate;
@end
初始化编码session
- (void)initCompressionSession{
if(compressionSession){
VTCompressionSessionCompleteFrames(compressionSession, kCMTimeInvalid);
VTCompressionSessionInvalidate(compressionSession);
CFRelease(compressionSession);
compressionSession = NULL;
}
OSStatus status = VTCompressionSessionCreate(NULL, _configuration.videoSize.width, _configuration.videoSize.height, kCMVideoCodecType_H264, NULL, NULL, NULL, VideoCompressonOutputCallback, (__bridge void *)self, &compressionSession);
if(status != noErr){
return;
}
_currentVideoBitRate = _configuration.videoBitRate;
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_MaxKeyFrameInterval,(__bridge CFTypeRef)@(_configuration.videoMaxKeyframeInterval));
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_MaxKeyFrameIntervalDuration,(__bridge CFTypeRef)@(_configuration.videoMaxKeyframeInterval));
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_ExpectedFrameRate, (__bridge CFTypeRef)@(_configuration.videoFrameRate));
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_AverageBitRate, (__bridge CFTypeRef)@(_configuration.videoBitRate));
NSArray *limit = @[@(_configuration.videoBitRate * 1.5/8),@(1)];
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_DataRateLimits, (__bridge CFArrayRef)limit);
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_RealTime, kCFBooleanFalse);
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_ProfileLevel, kVTProfileLevel_H264_Main_AutoLevel);
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_AllowFrameReordering, kCFBooleanFalse);
VTSessionSetProperty(compressionSession, kVTCompressionPropertyKey_H264EntropyMode, kVTH264EntropyMode_CABAC);
VTCompressionSessionPrepareToEncodeFrames(compressionSession);
}
编码输入
- (void)encodeVideoData:(CVImageBufferRef)pixelBuffer timeStamp:(uint64_t)timeStamp{
if(_isBackGround) return;
frameCount ++;
CMTime presentationTimeStamp = CMTimeMake(frameCount, (int32_t)_configuration.videoFrameRate);
VTEncodeInfoFlags flags;
CMTime duration = CMTimeMake(1, (int32_t)_configuration.videoFrameRate);
NSDictionary *properties = nil;
if(frameCount % (int32_t)_configuration.videoMaxKeyframeInterval == 0){
properties = @{(__bridge NSString *)kVTEncodeFrameOptionKey_ForceKeyFrame: @YES};
}
NSNumber *timeNumber = @(timeStamp);
VTCompressionSessionEncodeFrame(compressionSession, pixelBuffer, presentationTimeStamp, duration, (__bridge CFDictionaryRef)properties, (__bridge_retained void *)timeNumber, &flags);
}
回调
static void VideoCompressonOutputCallback(void *VTref, void *VTFrameRef, OSStatus status, VTEncodeInfoFlags infoFlags, CMSampleBufferRef sampleBuffer)
{
if(!sampleBuffer) return;
CFArrayRef array = CMSampleBufferGetSampleAttachmentsArray(sampleBuffer, true);
if(!array) return;
CFDictionaryRef dic = (CFDictionaryRef)CFArrayGetValueAtIndex(array, 0);
if(!dic) return;
BOOL keyframe = !CFDictionaryContainsKey(dic, kCMSampleAttachmentKey_NotSync);
uint64_t timeStamp = [((__bridge_transfer NSNumber*)VTFrameRef) longLongValue];
CLHardwareVideoEncoder *videoEncoder = (__bridge CLHardwareVideoEncoder *)VTref;
if(status != noErr){
return;
}
if (keyframe && !videoEncoder->sps)
{
CMFormatDescriptionRef format = CMSampleBufferGetFormatDescription(sampleBuffer);
size_t sparameterSetSize, sparameterSetCount;
const uint8_t *sparameterSet;
OSStatus statusCode = CMVideoFormatDescriptionGetH264ParameterSetAtIndex(format, 0, &sparameterSet, &sparameterSetSize, &sparameterSetCount, 0 );
if (statusCode == noErr)
{
size_t pparameterSetSize, pparameterSetCount;
const uint8_t *pparameterSet;
OSStatus statusCode = CMVideoFormatDescriptionGetH264ParameterSetAtIndex(format, 1, &pparameterSet, &pparameterSetSize, &pparameterSetCount, 0 );
if (statusCode == noErr)
{
videoEncoder->sps = [NSData dataWithBytes:sparameterSet length:sparameterSetSize];
videoEncoder->pps = [NSData dataWithBytes:pparameterSet length:pparameterSetSize];
if(videoEncoder->enabledWriteVideoFile){
NSMutableData *data = [[NSMutableData alloc] init];
uint8_t header[] = {0x00,0x00,0x00,0x01};
[data appendBytes:header length:4];
[data appendData:videoEncoder->sps];
[data appendBytes:header length:4];
[data appendData:videoEncoder->pps];
fwrite(data.bytes, 1,data.length,videoEncoder->fp);
}
}
}
}
CMBlockBufferRef dataBuffer = CMSampleBufferGetDataBuffer(sampleBuffer);
size_t length, totalLength;
char *dataPointer;
OSStatus statusCodeRet = CMBlockBufferGetDataPointer(dataBuffer, 0, &length, &totalLength, &dataPointer);
if (statusCodeRet == noErr) {
size_t bufferOffset = 0;
static const int AVCCHeaderLength = 4;
while (bufferOffset < totalLength - AVCCHeaderLength) {
// Read the NAL unit length
uint32_t NALUnitLength = 0;
memcpy(&NALUnitLength, dataPointer + bufferOffset, AVCCHeaderLength);
NALUnitLength = CFSwapInt32BigToHost(NALUnitLength);
CLVideoFrame *videoFrame = [CLVideoFrame new];
videoFrame.timestamp = timeStamp;
videoFrame.data = [[NSData alloc] initWithBytes:(dataPointer + bufferOffset + AVCCHeaderLength) length:NALUnitLength];
videoFrame.isKeyFrame = keyframe;
videoFrame.sps = videoEncoder->sps;
videoFrame.pps = videoEncoder->pps;
if(videoEncoder.h264Delegate && [videoEncoder.h264Delegate respondsToSelector:@selector(videoEncoder:videoFrame:)]){
[videoEncoder.h264Delegate videoEncoder:videoEncoder videoFrame:videoFrame];
}
if(videoEncoder->enabledWriteVideoFile){
NSMutableData *data = [[NSMutableData alloc] init];
if(keyframe){
uint8_t header[] = {0x00,0x00,0x00,0x01};
[data appendBytes:header length:4];
}else{
uint8_t header[] = {0x00,0x00,0x01};
[data appendBytes:header length:3];
}
[data appendData:videoFrame.data];
fwrite(data.bytes, 1,data.length,videoEncoder->fp);
}
bufferOffset += AVCCHeaderLength + NALUnitLength;
}
}
}
软编码主要是利用CPU进行编码的过程, 具体的编码通常会用FFmpeg+x264,需要自己先编译FFmpeg(iOS)和X264。
将编译好的文件夹拖入到工程中添加依赖库:libiconv.dylib/libz.dylib/libbz2.dylib/CoreMedia.framework/AVFoundation.frameworkFFmpeg编码两个重要的类AVFormat
保存的是解码后和原始的音视频信息AVPacket
解码完成的数据及附加信息(解码时间戳、显示时间戳、时长等)
/*
* 设置X264
*/
- (int)setX264ResourceWithVideoWidth:(int)width height:(int)height bitrate:(int)bitrate
{
// 1.默认从第0帧开始(记录当前的帧数)
framecnt = 0;
// 2.记录传入的宽度&高度
encoder_h264_frame_width = width;
encoder_h264_frame_height = height;
// 3.注册FFmpeg所有编解码器(无论编码还是解码都需要该步骤)
av_register_all();
// 4.初始化AVFormatContext: 用作之后写入视频帧并编码成 h264,贯穿整个工程当中(释放资源时需要销毁)
pFormatCtx = avformat_alloc_context();
// 5.设置输出文件的路径
fmt = av_guess_format(NULL, out_file, NULL);
pFormatCtx->oformat = fmt;
// 6.打开文件的缓冲区输入输出,flags 标识为 AVIO_FLAG_READ_WRITE ,可读写
if (avio_open(&pFormatCtx->pb, out_file, AVIO_FLAG_READ_WRITE) < 0){
printf("Failed to open output file! \n");
return -1;
}
// 7.创建新的输出流, 用于写入文件
video_st = avformat_new_stream(pFormatCtx, 0);
// 8.设置 20 帧每秒 ,也就是 fps 为 20
video_st->time_base.num = 1;
video_st->time_base.den = 25;
if (video_st==NULL){
return -1;
}
// 9.pCodecCtx 用户存储编码所需的参数格式等等
// 9.1.从媒体流中获取到编码结构体,他们是一一对应的关系,一个 AVStream 对应一个 AVCodecContext
pCodecCtx = video_st->codec;
// 9.2.设置编码器的编码格式(是一个id),每一个编码器都对应着自己的 id,例如 h264 的编码 id 就是 AV_CODEC_ID_H264
pCodecCtx->codec_id = fmt->video_codec;
// 9.3.设置编码类型为 视频编码
pCodecCtx->codec_type = AVMEDIA_TYPE_VIDEO;
// 9.4.设置像素格式为 yuv 格式
pCodecCtx->pix_fmt = PIX_FMT_YUV420P;
// 9.5.设置视频的宽高
pCodecCtx->width = encoder_h264_frame_width;
pCodecCtx->height = encoder_h264_frame_height;
// 9.6.设置帧率
pCodecCtx->time_base.num = 1;
pCodecCtx->time_base.den = 15;
// 9.7.设置码率(比特率)
pCodecCtx->bit_rate = bitrate;
// 9.8.视频质量度量标准(常见qmin=10, qmax=51)
pCodecCtx->qmin = 10;
pCodecCtx->qmax = 51;
// 9.9.设置图像组层的大小(GOP-->两个I帧之间的间隔)
pCodecCtx->gop_size = 250;
// 9.10.设置 B 帧最大的数量,B帧为视频图片空间的前后预测帧, B 帧相对于 I、P 帧来说,压缩率比较大,也就是说相同码率的情况下,
// 越多 B 帧的视频,越清晰,现在很多打视频网站的高清视频,就是采用多编码 B 帧去提高清晰度,
// 但同时对于编解码的复杂度比较高,比较消耗性能与时间
pCodecCtx->max_b_frames = 5;
// 10.可选设置
AVDictionary *param = 0;
// H.264
if(pCodecCtx->codec_id == AV_CODEC_ID_H264) {
// 通过--preset的参数调节编码速度和质量的平衡。
av_dict_set(¶m, "preset", "slow", 0);
// 通过--tune的参数值指定片子的类型,是和视觉优化的参数,或有特别的情况。
// zerolatency: 零延迟,用在需要非常低的延迟的情况下,比如视频直播的编码
av_dict_set(¶m, "tune", "zerolatency", 0);
}
// 11.输出打印信息,内部是通过printf函数输出(不需要输出可以注释掉该局)
av_dump_format(pFormatCtx, 0, out_file, 1);
// 12.通过 codec_id 找到对应的编码器
pCodec = avcodec_find_encoder(pCodecCtx->codec_id);
if (!pCodec) {
printf("Can not find encoder! \n");
return -1;
}
// 13.打开编码器,并设置参数 param
if (avcodec_open2(pCodecCtx, pCodec,¶m) < 0) {
printf("Failed to open encoder! \n");
return -1;
}
// 13.初始化原始数据对象: AVFrame
pFrame = av_frame_alloc();
// 14.通过像素格式(这里为 YUV)获取图片的真实大小,例如将 480 * 720 转换成 int 类型
avpicture_fill((AVPicture *)pFrame, picture_buf, pCodecCtx->pix_fmt, pCodecCtx->width, pCodecCtx->height);
// 15.h264 封装格式的文件头部,基本上每种编码都有着自己的格式的头部,想看具体实现的同学可以看看 h264 的具体实现
avformat_write_header(pFormatCtx, NULL);
// 16.创建编码后的数据 AVPacket 结构体来存储 AVFrame 编码后生成的数据
av_new_packet(&pkt, picture_size);
// 17.设置 yuv 数据中 y 图的宽高
y_size = pCodecCtx->width * pCodecCtx->height;
return 0;
}
/*
* 将CMSampleBufferRef格式的数据编码成h264并写入文件
*
*/
- (void)encoderToH264:(CMSampleBufferRef)sampleBuffer
{
// 1.通过CMSampleBufferRef对象获取CVPixelBufferRef对象
CVPixelBufferRef imageBuffer = CMSampleBufferGetImageBuffer(sampleBuffer);
// 2.锁定imageBuffer内存地址开始进行编码
if (CVPixelBufferLockBaseAddress(imageBuffer, 0) == kCVReturnSuccess) {
// 3.从CVPixelBufferRef读取YUV的值
// NV12和NV21属于YUV格式,是一种two-plane模式,即Y和UV分为两个Plane,但是UV(CbCr)为交错存储,而不是分为三个plane
// 3.1.获取Y分量的地址
UInt8 *bufferPtr = (UInt8 *)CVPixelBufferGetBaseAddressOfPlane(imageBuffer,0);
// 3.2.获取UV分量的地址
UInt8 *bufferPtr1 = (UInt8 *)CVPixelBufferGetBaseAddressOfPlane(imageBuffer,1);
// 3.3.根据像素获取图片的真实宽度&高度
size_t width = CVPixelBufferGetWidth(imageBuffer);
size_t height = CVPixelBufferGetHeight(imageBuffer);
// 获取Y分量长度
size_t bytesrow0 = CVPixelBufferGetBytesPerRowOfPlane(imageBuffer,0);
size_t bytesrow1 = CVPixelBufferGetBytesPerRowOfPlane(imageBuffer,1);
UInt8 *yuv420_data = (UInt8 *)malloc(width * height *3/2);
/* convert NV12 data to YUV420*/
// 3.4.将NV12数据转成YUV420数据
UInt8 *pY = bufferPtr ;
UInt8 *pUV = bufferPtr1;
UInt8 *pU = yuv420_data + width*height;
UInt8 *pV = pU + width*height/4;
for(int i =0;idata[0] = picture_buf; // Y
pFrame->data[1] = picture_buf+ y_size; // U
pFrame->data[2] = picture_buf+ y_size*5/4; // V
// 4.设置当前帧
pFrame->pts = framecnt;
int got_picture = 0;
// 4.设置宽度高度以及YUV各式
pFrame->width = encoder_h264_frame_width;
pFrame->height = encoder_h264_frame_height;
pFrame->format = PIX_FMT_YUV420P;
// 5.对编码前的原始数据(AVFormat)利用编码器进行编码,将 pFrame 编码后的数据传入pkt 中
int ret = avcodec_encode_video2(pCodecCtx, &pkt, pFrame, &got_picture);
if(ret < 0) {
printf("Failed to encode! \n");
}
// 6.编码成功后写入 AVPacket 到 输入输出数据操作着 pFormatCtx 中,当然,记得释放内存
if (got_picture==1) {
framecnt++;
pkt.stream_index = video_st->index;
ret = av_write_frame(pFormatCtx, &pkt);
av_free_packet(&pkt);
}
// 7.释放yuv数据
free(yuv420_data);
}
CVPixelBufferUnlockBaseAddress(imageBuffer, 0);
}
/*
* 释放资源
*/
- (void)freeX264Resource
{
// 1.释放AVFormatContext
int ret = flush_encoder(pFormatCtx,0);
if (ret < 0) {
printf("Flushing encoder failed\n");
}
// 2.将还未输出的AVPacket输出出来
av_write_trailer(pFormatCtx);
// 3.关闭资源
if (video_st){
avcodec_close(video_st->codec);
av_free(pFrame);
}
avio_close(pFormatCtx->pb);
avformat_free_context(pFormatCtx);
}
int flush_encoder(AVFormatContext *fmt_ctx,unsigned int stream_index)
{
int ret;
int got_frame;
AVPacket enc_pkt;
if (!(fmt_ctx->streams[stream_index]->codec->codec->capabilities &
CODEC_CAP_DELAY))
return 0;
while (1) {
enc_pkt.data = NULL;
enc_pkt.size = 0;
av_init_packet(&enc_pkt);
ret = avcodec_encode_video2 (fmt_ctx->streams[stream_index]->codec, &enc_pkt,
NULL, &got_frame);
av_frame_free(NULL);
if (ret < 0)
break;
if (!got_frame){
ret=0;
break;
}
ret = av_write_frame(fmt_ctx, &enc_pkt);
if (ret < 0)
break;
}
return ret;
}
Clang的技术博客:https://www.clang.asia
欢迎分享,转载请注明来源:内存溢出
微信扫一扫
支付宝扫一扫
评论列表(0条)