int SrsHandshakeBytes::create_s0s1s2(const char* c1)
{
int ret = ERROR_SUCCESS;
if (s0s1s2) {
return ret;
}
s0s1s2 = new char[3073];
srs_random_generate(s0s1s2, 3073);
// plain text required.
SrsStream stream;
if ((ret = stream.initialize(s0s1s2, 9)) != ERROR_SUCCESS) {
return ret;
}
stream.write_1bytes(0x03);
stream.write_4bytes(::time(NULL));
// s2 time2 copy from c1
if (c0c1) {
stream.write_bytes(c0c1 + 1, 4);
}
// if c1 specified, copy c1 to s2.
// @see: https://github.com/winlinvip/simple-rtmp-server/issues/46
if (c1) {
memcpy(s0s1s2 + 1537, c1, 1536);
}
return ret;
}
srs_amf0_t srs_amf0_parse(char* data, int size, int* nparsed)
{
int ret = ERROR_SUCCESS;
srs_amf0_t amf0 = NULL;
SrsStream stream;
if ((ret = stream.initialize(data, size)) != ERROR_SUCCESS) {
return amf0;
}
SrsAmf0Any* any = NULL;
if ((ret = SrsAmf0Any::discovery(&stream, &any)) != ERROR_SUCCESS) {
return amf0;
}
stream.reset();
if ((ret = any->read(&stream)) != ERROR_SUCCESS) {
srs_freep(any);
return amf0;
}
*nparsed = stream.pos();
amf0 = (srs_amf0_t)any;
return amf0;
}
// read/write stream using SrsStream.
void __srs_stream_write_4bytes(char* pp, int32_t value)
{
static SrsStream stream;
int ret = stream.initialize(pp, 4);
srs_assert(ret == ERROR_SUCCESS);
stream.write_4bytes(value);
}
/**
* test the stream utility, access size
*/
VOID TEST(KernelStreamTest, StreamSize)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(s.size() == 0);
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_TRUE(s.size() == 1024);
}
int32_t __srs_stream_read_4bytes(char* pp)
{
static SrsStream stream;
int ret = stream.initialize(pp, 4);
srs_assert(ret == ERROR_SUCCESS);
return stream.read_4bytes();
}
/**
* test the stream utility, access data
*/
VOID TEST(KernelStreamTest, StreamData)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(s.data() == NULL);
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_TRUE(s.data() == data);
}
int SrsRtpConn::on_udp_packet(sockaddr_in* from, char* buf, int nb_buf)
{
int ret = ERROR_SUCCESS;
pprint->elapse();
if (true) {
SrsStream stream;
if ((ret = stream.initialize(buf, nb_buf)) != ERROR_SUCCESS) {
return ret;
}
SrsRtpPacket pkt;
if ((ret = pkt.decode(&stream)) != ERROR_SUCCESS) {
srs_error("rtsp: decode rtp packet failed. ret=%d", ret);
return ret;
}
if (pkt.chunked) {
if (!cache) {
cache = new SrsRtpPacket();
}
cache->copy(&pkt);
cache->payload->append(pkt.payload->bytes(), pkt.payload->length());
if (!cache->completed && pprint->can_print()) {
srs_trace("<- "SRS_CONSTS_LOG_STREAM_CASTER" rtsp: rtp chunked %dB, age=%d, vt=%d/%u, sts=%u/%#x/%#x, paylod=%dB",
nb_buf, pprint->age(), cache->version, cache->payload_type, cache->sequence_number, cache->timestamp, cache->ssrc,
cache->payload->length()
);
return ret;
}
} else {
srs_freep(cache);
cache = new SrsRtpPacket();
cache->reap(&pkt);
}
}
if (pprint->can_print()) {
srs_trace("<- "SRS_CONSTS_LOG_STREAM_CASTER" rtsp: rtp #%d %dB, age=%d, vt=%d/%u, sts=%u/%u/%#x, paylod=%dB, chunked=%d",
stream_id, nb_buf, pprint->age(), cache->version, cache->payload_type, cache->sequence_number, cache->timestamp, cache->ssrc,
cache->payload->length(), cache->chunked
);
}
// always free it.
SrsAutoFree(SrsRtpPacket, cache);
if ((ret = rtsp->on_rtp_packet(cache, stream_id)) != ERROR_SUCCESS) {
srs_error("rtsp: process rtp packet failed. ret=%d", ret);
return ret;
}
return ret;
}
/**
* test the stream utility, bytes from/to basic types.
*/
VOID TEST(KernelStreamTest, StreamInitialize)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_TRUE(ERROR_SUCCESS != s.initialize(NULL, 1024));
EXPECT_TRUE(ERROR_SUCCESS != s.initialize(data, 0));
EXPECT_TRUE(ERROR_SUCCESS != s.initialize(data, -1));
}
int srs_amf0_serialize(srs_amf0_t amf0, char* data, int size)
{
int ret = ERROR_SUCCESS;
SrsAmf0Any* any = (SrsAmf0Any*)amf0;
SrsStream stream;
if ((ret = stream.initialize(data, size)) != ERROR_SUCCESS) {
return ret;
}
if ((ret = any->write(&stream)) != ERROR_SUCCESS) {
return ret;
}
return ret;
}
/**
* test the stream utility, write 8bytes
*/
VOID TEST(KernelStreamTest, StreamWrite8Bytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
s.write_8bytes(0x1011121314151617);
s.write_8bytes(0x1819202122232425);
s.skip(-1 * s.pos());
EXPECT_EQ(0x10, s.read_1bytes());
s.skip(2);
EXPECT_EQ(0x13, s.read_1bytes());
s.skip(5);
EXPECT_EQ(0x19, s.read_1bytes());
}
/**
* test the stream utility, read 8bytes
*/
VOID TEST(KernelStreamTest, StreamRead8Bytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
data[0] = 0x01;
data[1] = 0x02;
data[2] = 0x03;
data[3] = 0x04;
data[4] = 0x05;
data[5] = 0x06;
data[6] = 0x07;
data[7] = 0x08;
data[8] = 0x09;
data[9] = 0x0a;
data[10] = 0x0b;
data[11] = 0x0c;
data[12] = 0x0d;
data[13] = 0x0e;
data[14] = 0x0f;
data[15] = 0x10;
data[16] = 0x11;
data[17] = 0x12;
data[18] = 0x13;
data[19] = 0x14;
EXPECT_EQ(0x0102030405060708, s.read_8bytes());
EXPECT_EQ(0x090a0b0c0d0e0f10, s.read_8bytes());
s.skip(-1 * s.pos());
s.skip(5);
EXPECT_EQ(0x060708090a0b0c0d, s.read_8bytes());
}
/**
* test the stream utility, read 4bytes
*/
VOID TEST(KernelStreamTest, StreamRead4Bytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
data[0] = 0x01;
data[1] = 0x02;
data[2] = 0x03;
data[3] = 0x04;
data[4] = 0x05;
data[5] = 0x06;
data[6] = 0x07;
data[7] = 0x08;
data[8] = 0x09;
data[9] = 0x0a;
EXPECT_EQ(0x01020304, s.read_4bytes());
EXPECT_EQ(0x05060708, s.read_4bytes());
s.skip(-1 * s.pos());
s.skip(5);
EXPECT_EQ(0x06070809, s.read_4bytes());
}
/**
* test the stream utility, access require
*/
VOID TEST(KernelStreamTest, StreamRequire)
{
SrsStream s;
char data[1024];
EXPECT_FALSE(s.require(1));
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_TRUE(s.require(1));
EXPECT_TRUE(s.require(1024));
s.read_bytes(data, 1000);
EXPECT_TRUE(s.require(1));
s.read_bytes(data, 24);
EXPECT_FALSE(s.require(1));
}
int SrsSource::on_dvr_request_sh()
{
int ret = ERROR_SUCCESS;
#ifdef SRS_AUTO_DVR
// feed the dvr the metadata/sequence header,
// when reload to start dvr, dvr will never get the sequence header in stream,
// use the SrsSource.on_dvr_request_sh to push the sequence header to DVR.
if (cache_metadata) {
char* payload = (char*)cache_metadata->payload;
int size = (int)cache_metadata->size;
SrsStream stream;
if ((ret = stream.initialize(payload, size)) != ERROR_SUCCESS) {
srs_error("dvr decode metadata stream failed. ret=%d", ret);
return ret;
}
SrsOnMetaDataPacket pkt;
if ((ret = pkt.decode(&stream)) != ERROR_SUCCESS) {
srs_error("dvr decode metadata packet failed.");
return ret;
}
if ((ret = dvr->on_meta_data(&pkt)) != ERROR_SUCCESS) {
srs_error("dvr process onMetaData message failed. ret=%d", ret);
return ret;
}
}
if (cache_sh_video && (ret = dvr->on_video(cache_sh_video->copy())) != ERROR_SUCCESS) {
srs_error("dvr process video sequence header message failed. ret=%d", ret);
return ret;
}
if (cache_sh_audio && (ret = dvr->on_audio(cache_sh_audio->copy())) != ERROR_SUCCESS) {
srs_error("dvr process audio sequence header message failed. ret=%d", ret);
return ret;
}
#endif
return ret;
}
/**
* test the stream utility, write 1bytes
*/
VOID TEST(KernelStreamTest, StreamWrite1Bytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
s.write_1bytes(0x10);
s.write_1bytes(0x11);
s.write_1bytes(0x12);
s.write_1bytes(0x13);
s.skip(-1 * s.pos());
EXPECT_EQ(0x10, s.read_1bytes());
s.skip(2);
EXPECT_EQ(0x13, s.read_1bytes());
}
/**
* test the stream utility, write bytes
*/
VOID TEST(KernelStreamTest, StreamWriteBytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
char str[] = {
(char)0x10, (char)0x11, (char)0x12, (char)0x13,
(char)0x14, (char)0x15, (char)0x16, (char)0x17,
(char)0x18, (char)0x19, (char)0x20, (char)0x21
};
s.write_bytes(str, 12);
s.skip(-1 * s.pos());
EXPECT_EQ(0x10, s.read_1bytes());
s.skip(2);
EXPECT_EQ(0x13, s.read_1bytes());
s.skip(5);
EXPECT_EQ(0x19, s.read_1bytes());
}
int SrsHandshakeBytes::create_c0c1()
{
int ret = ERROR_SUCCESS;
if (c0c1) {
return ret;
}
c0c1 = new char[1537];
srs_random_generate(c0c1, 1537);
// plain text required.
static SrsStream stream;
if ((ret = stream.initialize(c0c1, 9)) != ERROR_SUCCESS) {
return ret;
}
stream.write_1bytes(0x03);
stream.write_4bytes(::time(NULL));
stream.write_4bytes(0x00);
return ret;
}
int SrsHandshakeBytes::create_c2()
{
int ret = ERROR_SUCCESS;
if (c2) {
return ret;
}
c2 = new char[1536];
srs_random_generate(c2, 1536);
// time
SrsStream stream;
if ((ret = stream.initialize(c2, 8)) != ERROR_SUCCESS) {
return ret;
}
stream.write_4bytes(::time(NULL));
// c2 time2 copy from s1
if (s0s1s2) {
stream.write_bytes(s0s1s2 + 1, 4);
}
return ret;
}
/**
* test the stream utility, skip bytes
*/
VOID TEST(KernelStreamTest, StreamSkip)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_EQ(0, s.pos());
s.skip(1);
EXPECT_EQ(1, s.pos());
s.skip(-1);
EXPECT_EQ(0 , s.pos());
}
/**
* test the stream utility, access pos
*/
VOID TEST(KernelStreamTest, StreamPos)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(s.pos() == 0);
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_TRUE(s.pos() == 0);
s.read_bytes(data, 1024);
EXPECT_TRUE(s.pos() == 1024);
}
/**
* test the stream utility, access empty
*/
VOID TEST(KernelStreamTest, StreamEmpty)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(s.empty());
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
EXPECT_FALSE(s.empty());
s.read_bytes(data, 1024);
EXPECT_TRUE(s.empty());
}
/**
* test the stream utility, read 1bytes
*/
VOID TEST(KernelStreamTest, StreamRead1Bytes)
{
SrsStream s;
char data[1024];
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, 1024));
data[0] = 0x12;
data[99] = 0x13;
data[100] = 0x14;
data[101] = 0x15;
EXPECT_EQ(0x12, s.read_1bytes());
s.skip(-1 * s.pos());
s.skip(100);
EXPECT_EQ(0x14, s.read_1bytes());
}
/**
* test the stream utility, read string
*/
VOID TEST(KernelStreamTest, StreamReadString)
{
SrsStream s;
char data[] = "Hello, world!";
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, sizeof(data) - 1));
string str = s.read_string(2);
EXPECT_STREQ("He", str.c_str());
str = s.read_string(2);
EXPECT_STREQ("ll", str.c_str());
s.skip(3);
str = s.read_string(6);
EXPECT_STREQ("world!", str.c_str());
EXPECT_TRUE(s.empty());
}
/**
* test the stream utility, read bytes
*/
VOID TEST(KernelStreamTest, StreamReadBytes)
{
SrsStream s;
char data[] = "Hello, world!";
EXPECT_TRUE(ERROR_SUCCESS == s.initialize(data, sizeof(data) - 1));
char bytes[64];
s.read_bytes(bytes, 2);
bytes[2] = 0;
EXPECT_STREQ("He", bytes);
s.read_bytes(bytes, 2);
bytes[2] = 0;
EXPECT_STREQ("ll", bytes);
s.skip(3);
s.read_bytes(bytes, 6);
bytes[6] = 0;
EXPECT_STREQ("world!", bytes);
EXPECT_TRUE(s.empty());
}
int SrsSource::on_aggregate(SrsMessage* msg)
{
int ret = ERROR_SUCCESS;
SrsStream* stream = aggregate_stream;
if ((ret = stream->initialize((char*)msg->payload, msg->size)) != ERROR_SUCCESS) {
return ret;
}
while (!stream->empty()) {
if (!stream->require(1)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message type. ret=%d", ret);
return ret;
}
int8_t type = stream->read_1bytes();
if (!stream->require(3)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message size. ret=%d", ret);
return ret;
}
int32_t data_size = stream->read_3bytes();
if (data_size < 0) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message size(negative). ret=%d", ret);
return ret;
}
if (!stream->require(3)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message time. ret=%d", ret);
return ret;
}
int32_t timestamp = stream->read_3bytes();
if (!stream->require(1)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message time(high). ret=%d", ret);
return ret;
}
int32_t time_h = stream->read_1bytes();
timestamp |= time_h<<24;
timestamp &= 0x7FFFFFFF;
if (!stream->require(3)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message stream_id. ret=%d", ret);
return ret;
}
int32_t stream_id = stream->read_3bytes();
if (data_size > 0 && !stream->require(data_size)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message data. ret=%d", ret);
return ret;
}
// to common message.
SrsCommonMessage __o;
SrsMessage& o = __o;
o.header.message_type = type;
o.header.payload_length = data_size;
o.header.timestamp_delta = timestamp;
o.header.timestamp = timestamp;
o.header.stream_id = stream_id;
o.header.perfer_cid = msg->header.perfer_cid;
if (data_size > 0) {
o.size = data_size;
o.payload = new char[o.size];
stream->read_bytes(o.payload, o.size);
}
if (!stream->require(4)) {
ret = ERROR_RTMP_AGGREGATE;
srs_error("invalid aggregate message previous tag size. ret=%d", ret);
return ret;
}
stream->read_4bytes();
// process parsed message
if (o.header.is_audio()) {
if ((ret = on_audio(&o)) != ERROR_SUCCESS) {
return ret;
}
} else if (o.header.is_video()) {
if ((ret = on_video(&o)) != ERROR_SUCCESS) {
return ret;
}
}
}
return ret;
}
VOID TEST(AMF0Test, ApiAnyAssert)
{
SrsStream s;
SrsAmf0Any* o = NULL;
char buf[1024];
memset(buf, 0, sizeof(buf));
EXPECT_EQ(ERROR_SUCCESS, s.initialize(buf, sizeof(buf)));
// read any
if (true) {
s.reset();
s.current()[0] = 0x12;
EXPECT_NE(ERROR_SUCCESS, srs_amf0_read_any(&s, &o));
EXPECT_TRUE(NULL == o);
srs_freep(o);
}
// any convert
if (true) {
o = SrsAmf0Any::str();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_string());
}
if (true) {
o = SrsAmf0Any::number();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_number());
}
if (true) {
o = SrsAmf0Any::boolean();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_boolean());
}
if (true) {
o = SrsAmf0Any::null();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_null());
}
if (true) {
o = SrsAmf0Any::undefined();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_undefined());
}
if (true) {
o = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_object());
}
if (true) {
o = SrsAmf0Any::ecma_array();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_ecma_array());
}
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_TRUE(o->is_strict_array());
}
// empty object
if (true) {
o = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Any, o);
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(1+3, s.pos());
}
// empty ecma array
if (true) {
o = SrsAmf0Any::ecma_array();
SrsAutoFree(SrsAmf0Any, o);
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(1+4+3, s.pos());
}
// strict array
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0Any, o);
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(1+4, s.pos());
}
}
VOID TEST(AMF0Test, ApiAnyIO)
{
SrsStream s;
SrsAmf0Any* o = NULL;
char buf[1024];
memset(buf, 0, sizeof(buf));
EXPECT_EQ(ERROR_SUCCESS, s.initialize(buf, sizeof(buf)));
// object eof
if (true) {
s.reset();
s.current()[2] = 0x09;
o = SrsAmf0Any::object_eof();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_EQ(3, s.pos());
s.reset();
s.current()[0] = 0x01;
EXPECT_NE(ERROR_SUCCESS, o->read(&s));
}
if (true) {
s.reset();
o = SrsAmf0Any::object_eof();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_EQ(3, s.pos());
s.skip(-3);
EXPECT_EQ(0x09, s.read_3bytes());
}
// string
if (true) {
s.reset();
o = SrsAmf0Any::str("winlin");
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(2, s.read_1bytes());
EXPECT_EQ(6, s.read_2bytes());
EXPECT_EQ('w', s.current()[0]);
EXPECT_EQ('n', s.current()[5]);
s.reset();
s.current()[3] = 'x';
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_STREQ("xinlin", o->to_str().c_str());
}
// number
if (true) {
s.reset();
o = SrsAmf0Any::number(10);
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(0, s.read_1bytes());
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_DOUBLE_EQ(10, o->to_number());
}
// boolean
if (true) {
s.reset();
o = SrsAmf0Any::boolean(true);
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(1, s.read_1bytes());
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_TRUE(o->to_boolean());
}
if (true) {
s.reset();
o = SrsAmf0Any::boolean(false);
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(1, s.read_1bytes());
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_FALSE(o->to_boolean());
}
// null
if (true) {
s.reset();
o = SrsAmf0Any::null();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(5, s.read_1bytes());
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_TRUE(o->is_null());
}
// undefined
if (true) {
s.reset();
o = SrsAmf0Any::undefined();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
EXPECT_EQ(6, s.read_1bytes());
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->read(&s));
EXPECT_EQ(o->total_size(), s.pos());
EXPECT_TRUE(o->is_undefined());
}
// any: string
if (true) {
s.reset();
o = SrsAmf0Any::str("winlin");
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
SrsAutoFree(SrsAmf0Any, po);
ASSERT_TRUE(po->is_string());
EXPECT_STREQ("winlin", po->to_str().c_str());
}
// any: number
if (true) {
s.reset();
o = SrsAmf0Any::number(10);
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
SrsAutoFree(SrsAmf0Any, po);
ASSERT_TRUE(po->is_number());
EXPECT_DOUBLE_EQ(10, po->to_number());
}
// any: boolean
if (true) {
s.reset();
o = SrsAmf0Any::boolean(true);
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
SrsAutoFree(SrsAmf0Any, po);
ASSERT_TRUE(po->is_boolean());
EXPECT_TRUE(po->to_boolean());
}
// any: null
if (true) {
s.reset();
o = SrsAmf0Any::null();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
SrsAutoFree(SrsAmf0Any, po);
ASSERT_TRUE(po->is_null());
}
// any: undefined
if (true) {
s.reset();
o = SrsAmf0Any::undefined();
SrsAutoFree(SrsAmf0Any, o);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(o->total_size(), s.pos());
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
SrsAutoFree(SrsAmf0Any, po);
ASSERT_TRUE(po->is_undefined());
}
// mixed any
if (true) {
s.reset();
o = SrsAmf0Any::str("winlin");
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
srs_freep(o);
o = SrsAmf0Any::number(10);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
srs_freep(o);
o = SrsAmf0Any::boolean(true);
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
srs_freep(o);
o = SrsAmf0Any::null();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
srs_freep(o);
o = SrsAmf0Any::undefined();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
srs_freep(o);
s.reset();
SrsAmf0Any* po = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
ASSERT_TRUE(po->is_string());
EXPECT_STREQ("winlin", po->to_str().c_str());
srs_freep(po);
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
ASSERT_TRUE(po->is_number());
EXPECT_DOUBLE_EQ(10, po->to_number());
srs_freep(po);
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
ASSERT_TRUE(po->is_boolean());
EXPECT_TRUE(po->to_boolean());
srs_freep(po);
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
ASSERT_TRUE(po->is_null());
srs_freep(po);
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &po));
ASSERT_TRUE(NULL != po);
ASSERT_TRUE(po->is_undefined());
srs_freep(po);
}
}
// user scenario: coding and decoding with amf0
VOID TEST(AMF0Test, ScenarioMain)
{
// coded amf0 object
int nb_bytes = 0;
char* bytes = NULL;
// coding data to binaries by amf0
// for example, send connect app response to client.
if (true) {
// props: object
// fmsVer: string
// capabilities: number
// mode: number
// info: object
// level: string
// code: string
// descrption: string
// objectEncoding: number
// data: array
// version: string
// srs_sig: string
SrsAmf0Object* props = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Object, props);
props->set("fmsVer", SrsAmf0Any::str("FMS/3,5,3,888"));
props->set("capabilities", SrsAmf0Any::number(253));
props->set("mode", SrsAmf0Any::number(123));
SrsAmf0Object* info = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Object, info);
info->set("level", SrsAmf0Any::str("info"));
info->set("code", SrsAmf0Any::str("NetStream.Connnect.Success"));
info->set("descrption", SrsAmf0Any::str("connected"));
info->set("objectEncoding", SrsAmf0Any::number(3));
SrsAmf0EcmaArray* data = SrsAmf0Any::ecma_array();
info->set("data", data);
data->set("version", SrsAmf0Any::str("FMS/3,5,3,888"));
data->set("srs_sig", SrsAmf0Any::str("srs"));
// buf store the serialized props/info
nb_bytes = props->total_size() + info->total_size();
ASSERT_GT(nb_bytes, 0);
bytes = new char[nb_bytes];
// use SrsStream to write props/info to binary buf.
SrsStream s;
EXPECT_EQ(ERROR_SUCCESS, s.initialize(bytes, nb_bytes));
EXPECT_EQ(ERROR_SUCCESS, props->write(&s));
EXPECT_EQ(ERROR_SUCCESS, info->write(&s));
EXPECT_TRUE(s.empty());
// now, user can use the buf
EXPECT_EQ(0x03, bytes[0]);
EXPECT_EQ(0x09, bytes[nb_bytes - 1]);
}
SrsAutoFree(char, bytes);
// decoding amf0 object from bytes
// when user know the schema
if (true) {
ASSERT_TRUE(NULL != bytes);
// use SrsStream to assist amf0 object to read from bytes.
SrsStream s;
EXPECT_EQ(ERROR_SUCCESS, s.initialize(bytes, nb_bytes));
// decoding
// if user know the schema, for instance, it's an amf0 object,
// user can use specified object to decoding.
SrsAmf0Object* props = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Object, props);
EXPECT_EQ(ERROR_SUCCESS, props->read(&s));
// user can use specified object to decoding.
SrsAmf0Object* info = SrsAmf0Any::object();
SrsAutoFree(SrsAmf0Object, info);
EXPECT_EQ(ERROR_SUCCESS, info->read(&s));
// use the decoded data.
SrsAmf0Any* prop = NULL;
// if user requires specified property, use ensure of amf0 object
EXPECT_TRUE(NULL != (prop = props->ensure_property_string("fmsVer")));
// the property can assert to string.
ASSERT_TRUE(prop->is_string());
// get the prop string value.
EXPECT_STREQ("FMS/3,5,3,888", prop->to_str().c_str());
// get other type property value
EXPECT_TRUE(NULL != (prop = info->get_property("data")));
// we cannot assert the property is ecma array
if (prop->is_ecma_array()) {
SrsAmf0EcmaArray* data = prop->to_ecma_array();
// it must be a ecma array.
ASSERT_TRUE(NULL != data);
// get property of array
EXPECT_TRUE(NULL != (prop = data->ensure_property_string("srs_sig")));
ASSERT_TRUE(prop->is_string());
EXPECT_STREQ("srs", prop->to_str().c_str());
}
// confidence about the schema
EXPECT_TRUE(NULL != (prop = info->ensure_property_string("level")));
ASSERT_TRUE(prop->is_string());
EXPECT_STREQ("info", prop->to_str().c_str());
}
// use any to decoding it,
// if user donot know the schema
if (true) {
ASSERT_TRUE(NULL != bytes);
// use SrsStream to assist amf0 object to read from bytes.
SrsStream s;
EXPECT_EQ(ERROR_SUCCESS, s.initialize(bytes, nb_bytes));
// decoding a amf0 any, for user donot know
SrsAmf0Any* any = NULL;
EXPECT_EQ(ERROR_SUCCESS, srs_amf0_read_any(&s, &any));
SrsAutoFree(SrsAmf0Any, any);
// for amf0 object
if (any->is_object()) {
SrsAmf0Object* obj = any->to_object();
ASSERT_TRUE(NULL != obj);
// use foreach to process properties
for (int i = 0; i < obj->count(); ++i) {
string name = obj->key_at(i);
SrsAmf0Any* value = obj->value_at(i);
// use the property name
EXPECT_TRUE("" != name);
// use the property value
EXPECT_TRUE(NULL != value);
}
}
}
}
VOID TEST(AMF0Test, ApiStrictArray)
{
SrsStream s;
char buf[1024];
memset(buf, 0, sizeof(buf));
EXPECT_EQ(ERROR_SUCCESS, s.initialize(buf, sizeof(buf)));
SrsAmf0StrictArray* o = NULL;
// append property
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0StrictArray, o);
o->append(SrsAmf0Any::number(100));
EXPECT_DOUBLE_EQ(100, o->at(0)->to_number());
o->append(SrsAmf0Any::number(101));
EXPECT_DOUBLE_EQ(101, o->at(1)->to_number());
o->append(SrsAmf0Any::str("winlin"));
EXPECT_STREQ("winlin", o->at(2)->to_str().c_str());
}
// count
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0StrictArray, o);
EXPECT_EQ(0, o->count());
o->append(SrsAmf0Any::boolean());
EXPECT_EQ(1, o->count());
o->append(SrsAmf0Any::boolean());
EXPECT_EQ(2, o->count());
o->clear();
EXPECT_EQ(0, o->count());
}
// io
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0StrictArray, o);
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(5, s.pos());
s.reset();
EXPECT_EQ(0x0a, s.read_1bytes());
EXPECT_EQ(0x00, s.read_4bytes());
}
if (true) {
o = SrsAmf0Any::strict_array();
SrsAutoFree(SrsAmf0StrictArray, o);
o->append(SrsAmf0Any::number(0));
s.reset();
EXPECT_EQ(ERROR_SUCCESS, o->write(&s));
EXPECT_EQ(5 + SrsAmf0Size::number(), s.pos());
}
}
