lokinet/test/util/test_llarp_util_bencode.cpp

451 lines
11 KiB
C++

#include <util/bencode.h>
#include <util/bencode.hpp>
#include <iostream>
#include <string>
#include <utility>
#include <vector>
#include <gtest/gtest.h>
using TestBuffer = std::vector< byte_t >;
template < typename Result >
struct TestReadData
{
TestBuffer buffer;
bool rc;
Result result;
};
using TestReadInt = TestReadData< uint64_t >;
using TestReadString = TestReadData< std::string >;
template < typename Result >
std::ostream&
operator<<(std::ostream& os, const TestReadData< Result >& d)
{
os << "buf = [ ";
for(auto x : d.buffer)
{
os << x << " ";
}
os << "] rc = ";
os << std::boolalpha << d.rc << " result = " << d.result;
return os;
}
struct ReadInt : public ::testing::TestWithParam< TestReadInt >
{
};
TEST_P(ReadInt, readInt)
{
auto d = GetParam();
llarp_buffer_t buffer(d.buffer);
uint64_t result = 0;
bool rc = bencode_read_integer(&buffer, &result);
EXPECT_EQ(rc, d.rc);
EXPECT_EQ(result, d.result);
}
static constexpr byte_t i = 'i';
static constexpr byte_t e = 'e';
static constexpr byte_t zero = '0';
static constexpr byte_t one = '1';
static constexpr byte_t two = '2';
static constexpr byte_t f = 'f';
static constexpr byte_t z = 'z';
static constexpr byte_t colon = ':';
static const TestReadInt testReadInt[] = {
// good cases
{{i, 0, e}, true, 0},
{{i, zero, e}, true, 0},
{{i, one, e}, true, 1},
{{i, two, e}, true, 2},
{{i, two, e, e, e}, true, 2},
{{i, one, one, one, two, e}, true, 1112},
{{i, f, e}, true, 0},
{{i, z, e}, true, 0},
{{i, one, two, e, one, one}, true, 12},
// failure cases
{{i, e}, false, 0},
{{e}, false, 0},
{{z}, false, 0},
};
INSTANTIATE_TEST_CASE_P(TestBencode, ReadInt,
::testing::ValuesIn(testReadInt), );
struct ReadStr : public ::testing::TestWithParam< TestReadString >
{
};
TEST_P(ReadStr, readStr)
{
auto d = GetParam();
llarp_buffer_t buffer(d.buffer);
llarp_buffer_t result;
bool rc = bencode_read_string(&buffer, &result);
EXPECT_EQ(rc, d.rc);
EXPECT_EQ(result.sz, d.result.size());
EXPECT_EQ(std::string(result.base, result.base + result.sz), d.result);
}
static const TestReadString testReadStr[] = {
// good cases
{{one, colon, 'a'}, true, "a"},
{{one, colon, 'b'}, true, "b"},
{{two, colon, f, z}, true, "fz"},
{{two, colon, f, z, f, f}, true, "fz"},
{{zero, colon}, true, ""},
// failure cases
{{two, colon, f}, false, ""},
{{two, f}, false, ""},
{{'-', one, colon, f}, false, ""},
{{f}, false, ""},
{{one, f, colon}, false, ""},
{{colon}, false, ""},
{{colon, colon}, false, ""},
};
INSTANTIATE_TEST_CASE_P(TestBencode, ReadStr,
::testing::ValuesIn(testReadStr), );
template < typename Input >
struct TestWriteData
{
Input input;
size_t bufferSize;
bool rc;
std::string output;
};
using TestWriteByteString = TestWriteData< std::string >;
using TestWriteInt = TestWriteData< uint64_t >;
struct WriteByteStr : public ::testing::TestWithParam< TestWriteByteString >
{
};
TEST_P(WriteByteStr, writeByte)
{
auto d = GetParam();
std::vector< byte_t > backingBuffer(d.bufferSize, 0);
llarp_buffer_t buffer(backingBuffer);
bool rc = bencode_write_bytestring(&buffer, d.input.data(), d.input.size());
ASSERT_EQ(rc, d.rc);
ASSERT_EQ(std::string(buffer.base, buffer.cur), d.output);
}
static constexpr size_t MAX_1 =
static_cast< size_t >(std::numeric_limits< int16_t >::max()) + 1;
static const TestWriteByteString testWriteByteString[] = {
// good cases
{"abacus", 100, true, "6:abacus"},
{" abacus", 100, true, "8: abacus"},
{"", 100, true, "0:"},
{std::string("\0\0\0", 3), 100, true, std::string("3:\0\0\0", 5)},
{std::string(MAX_1, 'a'), MAX_1 + 100, true,
std::to_string(MAX_1) + std::string(":") + std::string(MAX_1, 'a')},
// bad cases
{"a", 1, false, ""},
};
INSTANTIATE_TEST_CASE_P(TestBencode, WriteByteStr,
::testing::ValuesIn(testWriteByteString), );
struct WriteInt : public ::testing::TestWithParam< TestWriteInt >
{
};
TEST_P(WriteInt, writeInt)
{
auto d = GetParam();
std::vector< byte_t > backingBuffer(d.bufferSize, 0);
llarp_buffer_t buffer(backingBuffer);
bool rc = bencode_write_uint64(&buffer, d.input);
ASSERT_EQ(rc, d.rc);
ASSERT_EQ(std::string(buffer.base, buffer.cur), d.output);
}
static const TestWriteInt testWriteInt[] = {
// Good cases
{0, 100, true, "i0e"},
{1234, 100, true, "i1234e"},
{uint64_t(-1), 100, true, "i18446744073709551615e"},
// Bad cases
{1234567, 3, false, ""},
};
INSTANTIATE_TEST_CASE_P(TestBencode, WriteInt,
::testing::ValuesIn(testWriteInt), );
struct WriteIntValues : public ::testing::TestWithParam< uint64_t >
{
};
TEST_P(WriteIntValues, anyvalue)
{
// test we can encode any uint64_t into a buffer.
uint64_t val = GetParam();
std::vector< byte_t > backingBuffer(100, 0);
{
llarp_buffer_t buffer(backingBuffer);
bool rc = bencode_write_uint64(&buffer, val);
ASSERT_TRUE(rc);
}
{
uint64_t result = 0;
llarp_buffer_t buffer(backingBuffer);
bool rc = bencode_read_integer(&buffer, &result);
ASSERT_TRUE(rc);
ASSERT_EQ(result, val);
}
}
INSTANTIATE_TEST_CASE_P(
TestBencode, WriteIntValues,
::testing::Values(std::numeric_limits< uint64_t >::min(),
std::numeric_limits< uint64_t >::max(),
std::numeric_limits< uint64_t >::max() / 2,
std::numeric_limits< uint64_t >::max() / 3), );
TEST(TestBencode, good_version)
{
std::vector< byte_t > backingBuffer(100, 0);
llarp_buffer_t buffer(backingBuffer);
ASSERT_TRUE(bencode_write_version_entry(&buffer));
ASSERT_EQ(std::string(buffer.base, buffer.cur), "1:vi0e");
}
TEST(TestBencode, bad_version)
{
std::vector< byte_t > otherBuffer(1, 0);
llarp_buffer_t buffer(otherBuffer);
ASSERT_FALSE(bencode_write_version_entry(&buffer));
}
struct ValueData
{
// Variant-ish
std::string theString;
uint64_t theInt;
bool isString;
};
struct ListTestData
{
std::vector< ValueData > list;
size_t bufferSize;
std::string result;
};
struct ListTest : public ::testing::TestWithParam< ListTestData >
{
};
TEST_P(ListTest, list)
{
auto d = GetParam();
std::vector< byte_t > backingBuffer(d.bufferSize, 0);
llarp_buffer_t buffer(backingBuffer);
ASSERT_TRUE(bencode_start_list(&buffer));
for(const auto& x : d.list)
{
if(x.isString)
{
ASSERT_TRUE(bencode_write_bytestring(&buffer, x.theString.data(),
x.theString.size()));
}
else
{
ASSERT_TRUE(bencode_write_uint64(&buffer, x.theInt));
}
}
ASSERT_TRUE(bencode_end(&buffer));
ASSERT_EQ(std::string(buffer.base, buffer.cur), d.result);
}
ListTestData listTestData[] = {
{{}, 100, "le"},
{{{"", 0, true}}, 100, "l0:e"},
{{{"", 0, false}}, 100, "li0ee"},
{{{"", 0, false}, {"", 0, true}}, 100, "li0e0:e"},
{{{"", 123, false}, {"abc", 0, true}}, 100, "li123e3:abce"},
{{{"", 123, false}, {"abc", 0, true}, {"abc", 0, true}},
100,
"li123e3:abc3:abce"},
};
INSTANTIATE_TEST_CASE_P(TestBencode, ListTest,
::testing::ValuesIn(listTestData), );
struct DictTestData
{
std::vector< std::pair< char, ValueData > > list;
size_t bufferSize;
std::string result;
};
struct DictTest : public ::testing::TestWithParam< DictTestData >
{
};
TEST_P(DictTest, dict)
{
auto d = GetParam();
std::vector< byte_t > backingBuffer(d.bufferSize, 0);
llarp_buffer_t buffer(backingBuffer);
ASSERT_TRUE(bencode_start_dict(&buffer));
for(const auto& x : d.list)
{
ASSERT_TRUE(bencode_write_bytestring(&buffer, &x.first, 1));
if(x.second.isString)
{
ASSERT_TRUE(bencode_write_bytestring(&buffer, x.second.theString.data(),
x.second.theString.size()));
}
else
{
ASSERT_TRUE(bencode_write_uint64(&buffer, x.second.theInt));
}
}
ASSERT_TRUE(bencode_end(&buffer));
ASSERT_EQ(std::string(buffer.base, buffer.cur), d.result);
}
DictTestData dictTestData[] = {
{{}, 100, "de"},
{{{'a', {"", 0, true}}}, 100, "d1:a0:e"},
{{{'b', {"", 0, false}}}, 100, "d1:bi0ee"},
{{{'c', {"", 0, false}}, {'d', {"", 0, true}}}, 100, "d1:ci0e1:d0:e"},
{{{'e', {"", 123, false}}, {'f', {"abc", 0, true}}},
100,
"d1:ei123e1:f3:abce"},
{{{'a', {"", 123, false}},
{'b', {"abc", 0, true}},
{'c', {"abc", 0, true}}},
100,
"d1:ai123e1:b3:abc1:c3:abce"},
};
INSTANTIATE_TEST_CASE_P(TestBencode, DictTest,
::testing::ValuesIn(dictTestData), );
struct ReadData
{
std::string input;
std::vector< std::string > output;
};
struct DictReadTest : public ::testing::TestWithParam< ReadData >
{
};
TEST_P(DictReadTest, readtest)
{
auto d = GetParam();
byte_t* input =
const_cast< byte_t* >(reinterpret_cast< const byte_t* >(d.input.data()));
llarp_buffer_t buffer(input, input, d.input.size());
std::vector< std::string > result;
ASSERT_TRUE(llarp::bencode_read_dict(
[&](llarp_buffer_t*, llarp_buffer_t* key) {
if(key)
{
result.emplace_back(key->base, key->base + key->sz);
}
return true;
},
&buffer));
ASSERT_EQ(result, d.output);
}
ReadData dictReadData[] = {{"de", {}},
{"d1:a0:e", {"a", ""}},
{"d1:be", {"b"}},
{"d1:b2:23e", {"b", "23"}}};
INSTANTIATE_TEST_CASE_P(TestBencode, DictReadTest,
::testing::ValuesIn(dictReadData), );
struct ListReadTest : public ::testing::TestWithParam< ReadData >
{
};
TEST_P(ListReadTest, readtest)
{
auto d = GetParam();
byte_t* input =
const_cast< byte_t* >(reinterpret_cast< const byte_t* >(d.input.data()));
llarp_buffer_t buffer(input, input, d.input.size());
std::vector< std::string > result;
ASSERT_TRUE(llarp::bencode_read_list(
[&](llarp_buffer_t* b, bool cont) {
if(cont)
{
llarp_buffer_t tmp;
bencode_read_string(b, &tmp);
result.emplace_back(tmp.base, tmp.base + tmp.sz);
}
return true;
},
&buffer));
ASSERT_EQ(result, d.output);
}
ReadData listReadData[] = {
{"le", {}}, {"l1:ae", {"a"}}, {"l1:be", {"b"}}, {"l1:b2:23e", {"b", "23"}}};
INSTANTIATE_TEST_CASE_P(TestBencode, ListReadTest,
::testing::ValuesIn(listReadData), );
TEST(TestBencode, ReadDictEmptyBuffer)
{
llarp_buffer_t buf((byte_t*)nullptr, 0);
ASSERT_FALSE(llarp::bencode_read_dict(
[](llarp_buffer_t*, llarp_buffer_t*) { return true; }, &buf));
}