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tdlib-fork/test/http.cpp
levlam 968689157c Make max_compression_ratio required parameter in gzencode.
GitOrigin-RevId: c787fdeae202d3b80944412e7db4209f35adcd07
2020-03-15 01:56:48 +03:00

377 lines
11 KiB
C++

//
// Copyright Aliaksei Levin (levlam@telegram.org), Arseny Smirnov (arseny30@gmail.com) 2014-2020
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
#include "td/utils/tests.h"
#include "td/net/HttpChunkedByteFlow.h"
#include "td/net/HttpHeaderCreator.h"
#include "td/net/HttpQuery.h"
#include "td/net/HttpReader.h"
#include "td/utils/AesCtrByteFlow.h"
#include "td/utils/base64.h"
#include "td/utils/buffer.h"
#include "td/utils/BufferedFd.h"
#include "td/utils/ByteFlow.h"
#include "td/utils/common.h"
#include "td/utils/crypto.h"
#include "td/utils/format.h"
#include "td/utils/Gzip.h"
#include "td/utils/GzipByteFlow.h"
#include "td/utils/logging.h"
#include "td/utils/misc.h"
#include "td/utils/port/detail/PollableFd.h"
#include "td/utils/port/FileFd.h"
#include "td/utils/port/path.h"
#include "td/utils/port/PollFlags.h"
#include "td/utils/port/thread_local.h"
#include "td/utils/Random.h"
#include "td/utils/Slice.h"
#include "td/utils/Status.h"
#include "td/utils/UInt.h"
#include "data.h"
#include <algorithm>
#include <cstdlib>
#include <limits>
REGISTER_TESTS(http)
using namespace td;
static string make_chunked(string str) {
auto v = rand_split(str);
string res;
for (auto &s : v) {
res += PSTRING() << format::as_hex_dump(static_cast<int32>(s.size()));
res += "\r\n";
res += s;
res += "\r\n";
}
res += "0\r\n\r\n";
return res;
}
static string gen_http_content() {
int t = Random::fast(0, 2);
int len;
if (t == 0) {
len = Random::fast(1, 10);
} else if (t == 1) {
len = Random::fast(100, 200);
} else {
len = Random::fast(1000, 20000);
}
return rand_string(std::numeric_limits<char>::min(), std::numeric_limits<char>::max(), len);
}
static string make_http_query(string content, bool is_chunked, bool is_gzip, double gzip_k = 5,
string zip_override = "") {
HttpHeaderCreator hc;
hc.init_post("/");
hc.add_header("jfkdlsahhjk", rand_string('a', 'z', Random::fast(1, 2000)));
if (is_gzip) {
BufferSlice zip;
if (zip_override.empty()) {
zip = gzencode(content, gzip_k);
} else {
zip = BufferSlice(zip_override);
}
if (!zip.empty()) {
hc.add_header("content-encoding", "gzip");
content = zip.as_slice().str();
}
}
if (is_chunked) {
hc.add_header("transfer-encoding", "chunked");
content = make_chunked(content);
} else {
hc.set_content_size(content.size());
}
string res;
auto r_header = hc.finish();
CHECK(r_header.is_ok());
res += r_header.ok().str();
res += content;
return res;
}
static string rand_http_query(string content) {
bool is_chunked = Random::fast(0, 1) == 0;
bool is_gzip = Random::fast(0, 1) == 0;
return make_http_query(std::move(content), is_chunked, is_gzip);
}
static string join(const std::vector<string> &v) {
string res;
for (auto &s : v) {
res += s;
}
return res;
}
TEST(Http, stack_overflow) {
ChainBufferWriter writer;
BufferSlice slice(string(256, 'A'));
for (int i = 0; i < 1000000; i++) {
ChainBufferWriter tmp_writer;
writer.append(slice.clone());
}
{
auto reader = writer.extract_reader();
reader.sync_with_writer();
}
}
TEST(Http, reader) {
#if TD_ANDROID || TD_TIZEN
return;
#endif
clear_thread_locals();
SET_VERBOSITY_LEVEL(VERBOSITY_NAME(ERROR));
auto start_mem = BufferAllocator::get_buffer_mem();
{
td::ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
HttpReader reader;
int max_post_size = 10000;
reader.init(&input, max_post_size, 0);
std::srand(4);
std::vector<string> contents(1000);
std::generate(contents.begin(), contents.end(), gen_http_content);
auto v = td::transform(contents, rand_http_query);
auto vec_str = rand_split(join(v));
HttpQuery q;
std::vector<string> res;
for (auto &str : vec_str) {
input_writer.append(str);
input.sync_with_writer();
while (true) {
auto r_state = reader.read_next(&q);
LOG_IF(ERROR, r_state.is_error()) << r_state.error() << tag("ok", res.size());
ASSERT_TRUE(r_state.is_ok());
auto state = r_state.ok();
if (state == 0) {
if (q.files_.empty()) {
ASSERT_TRUE(td::narrow_cast<int>(q.content_.size()) <= max_post_size);
auto expected = contents[res.size()];
ASSERT_EQ(expected, q.content_.str());
res.push_back(q.content_.str());
} else {
auto r_fd = FileFd::open(q.files_[0].temp_file_name, FileFd::Read);
ASSERT_TRUE(r_fd.is_ok());
auto fd = r_fd.move_as_ok();
string content(td::narrow_cast<size_t>(q.files_[0].size), '\0');
auto r_size = fd.read(MutableSlice(content));
ASSERT_TRUE(r_size.is_ok());
ASSERT_TRUE(r_size.ok() == content.size());
ASSERT_TRUE(td::narrow_cast<int>(content.size()) > max_post_size);
ASSERT_EQ(contents[res.size()], content);
res.push_back(content);
fd.close();
}
} else {
break;
}
}
}
ASSERT_EQ(contents.size(), res.size());
ASSERT_EQ(contents, res);
}
clear_thread_locals();
ASSERT_EQ(start_mem, BufferAllocator::get_buffer_mem());
}
TEST(Http, gzip_bomb) {
#if TD_ANDROID || TD_TIZEN || TD_EMSCRIPTEN // the test should be disabled on low-memory systems
return;
#endif
auto gzip_bomb_str =
gzdecode(gzdecode(base64url_decode(Slice(gzip_bomb, gzip_bomb_size)).ok()).as_slice()).as_slice().str();
auto query = make_http_query("", false, true, 0.01, gzip_bomb_str);
auto parts = rand_split(query);
td::ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
HttpReader reader;
HttpQuery q;
reader.init(&input, 100000000, 0);
for (auto &part : parts) {
input_writer.append(part);
input.sync_with_writer();
auto r_state = reader.read_next(&q);
if (r_state.is_error()) {
LOG(INFO) << r_state.error();
return;
}
ASSERT_TRUE(r_state.ok() != 0);
}
}
TEST(Http, aes_ctr_encode_decode_flow) {
auto str = rand_string('a', 'z', 1000000);
auto parts = rand_split(str);
td::ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
ByteFlowSource source(&input);
UInt256 key;
UInt128 iv;
Random::secure_bytes(key.raw, sizeof(key));
Random::secure_bytes(iv.raw, sizeof(iv));
AesCtrByteFlow aes_encode;
aes_encode.init(key, iv);
AesCtrByteFlow aes_decode;
aes_decode.init(key, iv);
ByteFlowSink sink;
source >> aes_encode >> aes_decode >> sink;
ASSERT_TRUE(!sink.is_ready());
for (auto &part : parts) {
input_writer.append(part);
source.wakeup();
}
ASSERT_TRUE(!sink.is_ready());
source.close_input(Status::OK());
ASSERT_TRUE(sink.is_ready());
LOG_IF(ERROR, sink.status().is_error()) << sink.status();
ASSERT_TRUE(sink.status().is_ok());
ASSERT_EQ(str, sink.result()->move_as_buffer_slice().as_slice().str());
}
TEST(Http, aes_file_encryption) {
auto str = rand_string('a', 'z', 1000000);
CSlice name = "test_encryption";
unlink(name).ignore();
UInt256 key;
UInt128 iv;
Random::secure_bytes(key.raw, sizeof(key));
Random::secure_bytes(iv.raw, sizeof(iv));
{
BufferedFdBase<FileFd> fd(FileFd::open(name, FileFd::Write | FileFd::Create).move_as_ok());
auto parts = rand_split(str);
ChainBufferWriter output_writer;
auto output_reader = output_writer.extract_reader();
ByteFlowSource source(&output_reader);
AesCtrByteFlow aes_encode;
aes_encode.init(key, iv);
ByteFlowSink sink;
source >> aes_encode >> sink;
fd.set_output_reader(sink.get_output());
for (auto &part : parts) {
output_writer.append(part);
source.wakeup();
fd.flush_write().ensure();
}
fd.close();
}
{
BufferedFdBase<FileFd> fd(FileFd::open(name, FileFd::Read).move_as_ok());
ChainBufferWriter input_writer;
auto input_reader = input_writer.extract_reader();
ByteFlowSource source(&input_reader);
AesCtrByteFlow aes_encode;
aes_encode.init(key, iv);
ByteFlowSink sink;
source >> aes_encode >> sink;
fd.set_input_writer(&input_writer);
fd.get_poll_info().add_flags(PollFlags::Read());
while (can_read(fd)) {
fd.flush_read(4096).ensure();
source.wakeup();
}
fd.close();
source.close_input(Status::OK());
ASSERT_TRUE(sink.is_ready());
LOG_IF(ERROR, sink.status().is_error()) << sink.status();
ASSERT_TRUE(sink.status().is_ok());
auto result = sink.result()->move_as_buffer_slice().as_slice().str();
ASSERT_EQ(str, result);
}
}
TEST(Http, chunked_flow) {
auto str = rand_string('a', 'z', 100);
auto parts = rand_split(make_chunked(str));
td::ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
ByteFlowSource source(&input);
HttpChunkedByteFlow chunked_flow;
ByteFlowSink sink;
source >> chunked_flow >> sink;
for (auto &part : parts) {
input_writer.append(part);
source.wakeup();
}
source.close_input(Status::OK());
ASSERT_TRUE(sink.is_ready());
LOG_IF(ERROR, sink.status().is_error()) << sink.status();
ASSERT_TRUE(sink.status().is_ok());
auto res = sink.result()->move_as_buffer_slice().as_slice().str();
ASSERT_EQ(str.size(), res.size());
ASSERT_EQ(str, res);
}
TEST(Http, chunked_flow_error) {
auto str = rand_string('a', 'z', 100000);
for (int d = 1; d < 100; d += 10) {
auto new_str = make_chunked(str);
new_str.resize(str.size() - d);
auto parts = rand_split(new_str);
td::ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
ByteFlowSource source(&input);
HttpChunkedByteFlow chunked_flow;
ByteFlowSink sink;
source >> chunked_flow >> sink;
for (auto &part : parts) {
input_writer.append(part);
source.wakeup();
}
ASSERT_TRUE(!sink.is_ready());
source.close_input(Status::OK());
ASSERT_TRUE(sink.is_ready());
ASSERT_TRUE(!sink.status().is_ok());
}
}
TEST(Http, gzip_chunked_flow) {
auto str = rand_string('a', 'z', 1000000);
auto parts = rand_split(make_chunked(gzencode(str, 2.0).as_slice().str()));
ChainBufferWriter input_writer;
auto input = input_writer.extract_reader();
ByteFlowSource source(&input);
HttpChunkedByteFlow chunked_flow;
GzipByteFlow gzip_flow(Gzip::Mode::Decode);
ByteFlowSink sink;
source >> chunked_flow >> gzip_flow >> sink;
for (auto &part : parts) {
input_writer.append(part);
source.wakeup();
}
source.close_input(Status::OK());
ASSERT_TRUE(sink.is_ready());
LOG_IF(ERROR, sink.status().is_error()) << sink.status();
ASSERT_TRUE(sink.status().is_ok());
ASSERT_EQ(str, sink.result()->move_as_buffer_slice().as_slice().str());
}