mirror of
https://github.com/TokTok/c-toxcore
synced 2026-06-06 15:32:22 +00:00
iphydf
a549807df7
This will allow us to do more interesting things with memory allocation within toxcore, and allow fuzzers to explore various allocation failure paths.
173 lines
5.3 KiB
C++
173 lines
5.3 KiB
C++
#include "ping_array.h"
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#include <gtest/gtest.h>
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#include <memory>
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#include "mono_time.h"
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namespace {
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struct Ping_Array_Deleter {
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void operator()(Ping_Array *arr) { ping_array_kill(arr); }
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};
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using Ping_Array_Ptr = std::unique_ptr<Ping_Array, Ping_Array_Deleter>;
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struct Mono_Time_Deleter {
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Mono_Time_Deleter(const Memory *mem)
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: mem_(mem)
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{
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}
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void operator()(Mono_Time *arr) { mono_time_free(mem_, arr); }
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private:
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const Memory *mem_;
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};
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using Mono_Time_Ptr = std::unique_ptr<Mono_Time, Mono_Time_Deleter>;
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TEST(PingArray, MinimumTimeoutIsOne)
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{
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const Memory *mem = system_memory();
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EXPECT_EQ(ping_array_new(mem, 1, 0), nullptr);
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EXPECT_NE(Ping_Array_Ptr(ping_array_new(mem, 1, 1)), nullptr);
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}
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TEST(PingArray, MinimumArraySizeIsOne)
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{
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const Memory *mem = system_memory();
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EXPECT_EQ(ping_array_new(mem, 0, 1), nullptr);
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EXPECT_NE(Ping_Array_Ptr(ping_array_new(mem, 1, 1)), nullptr);
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}
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TEST(PingArray, ArraySizeMustBePowerOfTwo)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr arr;
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arr.reset(ping_array_new(mem, 2, 1));
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EXPECT_NE(arr, nullptr);
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arr.reset(ping_array_new(mem, 4, 1));
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EXPECT_NE(arr, nullptr);
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arr.reset(ping_array_new(mem, 1024, 1));
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EXPECT_NE(arr, nullptr);
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EXPECT_EQ(ping_array_new(mem, 1023, 1), nullptr);
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EXPECT_EQ(ping_array_new(mem, 1234, 1), nullptr);
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}
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TEST(PingArray, StoredDataCanBeRetrieved)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 2, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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const Random *rng = system_random();
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ASSERT_NE(rng, nullptr);
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uint64_t const ping_id = ping_array_add(
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arr.get(), mono_time.get(), rng, std::vector<uint8_t>{1, 2, 3, 4}.data(), 4);
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EXPECT_NE(ping_id, 0);
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std::vector<uint8_t> data(4);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), data.data(), data.size(), ping_id), 4);
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EXPECT_EQ(data, std::vector<uint8_t>({1, 2, 3, 4}));
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}
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TEST(PingArray, RetrievingDataWithTooSmallOutputBufferHasNoEffect)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 2, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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const Random *rng = system_random();
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ASSERT_NE(rng, nullptr);
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uint64_t const ping_id = ping_array_add(
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arr.get(), mono_time.get(), rng, (std::vector<uint8_t>{1, 2, 3, 4}).data(), 4);
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EXPECT_NE(ping_id, 0);
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std::vector<uint8_t> data(4);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), data.data(), 3, ping_id), -1);
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// It doesn't write anything to the data array.
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EXPECT_EQ(data, std::vector<uint8_t>({0, 0, 0, 0}));
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// Afterwards, we can still read it.
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), data.data(), 4, ping_id), 4);
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EXPECT_EQ(data, std::vector<uint8_t>({1, 2, 3, 4}));
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}
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TEST(PingArray, ZeroLengthDataCanBeAdded)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 2, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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const Random *rng = system_random();
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ASSERT_NE(rng, nullptr);
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uint8_t c = 0;
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uint64_t const ping_id = ping_array_add(arr.get(), mono_time.get(), rng, &c, sizeof(c));
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EXPECT_NE(ping_id, 0);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), ping_id), 1);
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}
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TEST(PingArray, PingId0IsInvalid)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 2, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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uint8_t c = 0;
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), 0), -1);
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}
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// Protection against replay attacks.
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TEST(PingArray, DataCanOnlyBeRetrievedOnce)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 2, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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const Random *rng = system_random();
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ASSERT_NE(rng, nullptr);
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uint8_t c = 0;
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uint64_t const ping_id = ping_array_add(arr.get(), mono_time.get(), rng, &c, sizeof(c));
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EXPECT_NE(ping_id, 0);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), ping_id), 1);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), ping_id), -1);
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}
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TEST(PingArray, PingIdMustMatchOnCheck)
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{
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const Memory *mem = system_memory();
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Ping_Array_Ptr const arr(ping_array_new(mem, 1, 1));
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Mono_Time_Ptr const mono_time(mono_time_new(mem, nullptr, nullptr), mem);
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ASSERT_NE(mono_time, nullptr);
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const Random *rng = system_random();
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ASSERT_NE(rng, nullptr);
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uint8_t c = 0;
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uint64_t const ping_id = ping_array_add(arr.get(), mono_time.get(), rng, &c, sizeof(c));
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EXPECT_NE(ping_id, 0);
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uint64_t const bad_ping_id = ping_id == 1 ? 2 : 1;
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// bad_ping_id will also be pointing at the same element, but won't match the
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// actual ping_id.
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), bad_ping_id), -1);
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EXPECT_EQ(ping_array_check(arr.get(), mono_time.get(), &c, sizeof(c), ping_id), 1);
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}
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} // namespace
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