// // immer: immutable data structures for C++ // Copyright (C) 2016, 2017, 2018 Juan Pedro Bolivar Puente // // This software is distributed under the Boost Software License, Version 1.0. // See accompanying file LICENSE or copy at http://boost.org/LICENSE_1_0.txt // #include "extra/fuzzer/fuzzer_input.hpp" #include <array> #include <catch.hpp> #include <immer/flex_vector.hpp> #include <iostream> #define IMMER_FUZZED_TRACE_ENABLE 0 #if IMMER_FUZZED_TRACE_ENABLE #define IMMER_FUZZED_TRACE(...) std::cout << __VA_ARGS__ << std::endl; #else #define IMMER_FUZZED_TRACE(...) #endif namespace { template <std::size_t VarCount = 2, unsigned Bits = 2> int run_input(const std::uint8_t* data, std::size_t size) { using vector_t = immer::flex_vector<int, immer::default_memory_policy, Bits, Bits>; using size_t = std::uint8_t; auto vars = std::array<vector_t, VarCount>{}; #if IMMER_FUZZED_TRACE_ENABLE std::cout << "/// new test run" << std::endl; for (auto i = 0u; i < VarCount; ++i) std::cout << "auto var" << i << " = vector_t{};" << std::endl; #endif auto is_valid_var = [&](auto idx) { return idx >= 0 && idx < VarCount; }; auto is_valid_var_neq = [](auto other) { return [=](auto idx) { return idx >= 0 && idx < VarCount && idx != other; }; }; auto is_valid_index = [](auto& v) { return [&](auto idx) { return idx >= 0 && idx < v.size(); }; }; auto is_valid_size = [](auto& v) { return [&](auto idx) { return idx >= 0 && idx <= v.size(); }; }; auto can_concat = [](auto&& v1, auto&& v2) { using size_type = decltype(v1.size()); return v2.size() < (std::numeric_limits<size_type>::max() - v1.size()); }; auto can_insert = [](auto&& v1) { using size_type = decltype(v1.size()); return v1.size() < std::numeric_limits<size_type>::max(); }; return fuzzer_input{data, size}.run([&](auto& in) { enum ops { op_push_back, op_update, op_take, op_drop, op_concat, op_push_back_move, op_update_move, op_take_move, op_drop_move, op_concat_move_l, op_concat_move_r, op_concat_move_lr, }; auto src = read<std::uint8_t>(in, is_valid_var); auto dst = read<std::uint8_t>(in, is_valid_var); switch (read<char>(in)) { case op_push_back: if (can_insert(vars[src])) { IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << ".push_back(42);"); vars[dst] = vars[src].push_back(42); } break; case op_update: { auto idx = read<size_t>(in, is_valid_index(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << ".update(" << +idx << ", [] (auto x) { return x + 1; });"); vars[dst] = vars[src].update(idx, [](auto x) { return x + 1; }); break; } case op_take: { auto idx = read<size_t>(in, is_valid_size(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << ".take(" << +idx << ");"); vars[dst] = vars[src].take(idx); break; } case op_drop: { auto idx = read<size_t>(in, is_valid_size(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << ".take(" << +idx << ");"); vars[dst] = vars[src].drop(idx); break; } case op_concat: { auto src2 = read<std::uint8_t>(in, is_valid_var); if (can_concat(vars[src], vars[src2])) { IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << " + var" << +src2 << ";"); vars[dst] = vars[src] + vars[src2]; } break; } case op_push_back_move: { if (can_insert(vars[src])) { IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ").push_back(21);"); vars[dst] = std::move(vars[src]).push_back(21); } break; } case op_update_move: { auto idx = read<size_t>(in, is_valid_index(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ").update(" << +idx << ", [] (auto x) { return x + 1; });"); vars[dst] = std::move(vars[src]).update(idx, [](auto x) { return x + 1; }); break; } case op_take_move: { auto idx = read<size_t>(in, is_valid_size(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ").take(" << +idx << ");"); vars[dst] = std::move(vars[src]).take(idx); break; } case op_drop_move: { auto idx = read<size_t>(in, is_valid_size(vars[src])); IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ").drop(" << +idx << ");"); vars[dst] = std::move(vars[src]).drop(idx); break; } case op_concat_move_l: { auto src2 = read<std::uint8_t>(in, is_valid_var_neq(src)); if (can_concat(vars[src], vars[src2])) { IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ") + var" << +src2 << ";"); vars[dst] = std::move(vars[src]) + vars[src2]; } break; } case op_concat_move_r: { auto src2 = read<std::uint8_t>(in, is_valid_var_neq(src)); if (can_concat(vars[src], vars[src2])) { IMMER_FUZZED_TRACE("var" << +dst << " = var" << +src << " + std::move(var" << +src2 << ");"); vars[dst] = vars[src] + std::move(vars[src2]); } break; } case op_concat_move_lr: { auto src2 = read<std::uint8_t>(in, is_valid_var_neq(src)); if (can_concat(vars[src], vars[src2])) { IMMER_FUZZED_TRACE("var" << +dst << " = std::move(var" << +src << ") + std::move(var" << +src2 << ");"); vars[dst] = std::move(vars[src]) + std::move(vars[src2]); } break; } default: break; }; return true; }); } } // namespace TEST_CASE("bug: concat with moving the right side") { // This was a stupid bug on the concatenation of small vectors // when moving one of the sides. SECTION("simplified") { using vector_t = immer::flex_vector<int, immer::default_memory_policy, 2, 2>; auto var0 = vector_t{}; auto var1 = vector_t{}; var0 = var0.push_back(42); var0 = var0.push_back(42); var0 = var0.push_back(42); var1 = var0.push_back(42); var0 = var0 + var0; var0 = var0.push_back(42); var0 = var0 + var1; var0 = var0 + var0; var0 = var0 + std::move(var1); } #if __GNUC__ != 9 SECTION("vm") { constexpr std::uint8_t input[] = { 0x0, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x0, 0x0, 0x0, 0x0, 0x1, 0x0, 0x40, 0x28, 0x0, 0x4, 0x3f, 0x20, 0x0, 0x0, 0x4, 0x3f, 0x8, 0x0, 0x0, 0x0, 0x0, 0x1, 0x0, 0x0, 0x0, 0x4, 0x3f, 0x0, 0x0, 0x40, 0x0, 0x0, 0x0, 0x0, 0x4, 0x3f, 0x1, 0x0, 0x0, 0x4, 0x3f, 0x0, 0x0, 0xff, 0x0, 0xa, 0x1, 0x0, 0xff, 0x0, 0x0, }; CHECK(run_input(input, sizeof(input)) == 0); } #endif }