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Hush Full Node software. We were censored from Github, this is where all development happens now. https://hush.is
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hush3/src/gtest/test_equihash.cpp

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// Copyright (c) 2019-2020 The Hush developers
// Distributed under the GPLv3 software license, see the accompanying
// file COPYING or https://www.gnu.org/licenses/gpl-3.0.en.html
#if defined(HAVE_CONFIG_H)
#include "config/bitcoin-config.h"
#endif
#include <gtest/gtest.h>
#include <gmock/gmock.h>
#include "crypto/equihash.h"
#include "uint256.h"
void TestExpandAndCompress(const std::string &scope, size_t bit_len, size_t byte_pad,
std::vector<unsigned char> compact,
std::vector<unsigned char> expanded)
{
SCOPED_TRACE(scope);
std::vector<unsigned char> out(expanded.size());
ExpandArray(compact.data(), compact.size(),
out.data(), out.size(), bit_len, byte_pad);
EXPECT_EQ(expanded, out);
out.resize(compact.size());
CompressArray(expanded.data(), expanded.size(),
out.data(), out.size(), bit_len, byte_pad);
EXPECT_EQ(compact, out);
}
TEST(equihash_tests, expand_and_contract_arrays) {
TestExpandAndCompress("8 11-bit chunks, all-ones", 11, 0,
ParseHex("ffffffffffffffffffffff"),
ParseHex("07ff07ff07ff07ff07ff07ff07ff07ff"));
TestExpandAndCompress("8 21-bit chunks, alternating 1s and 0s", 21, 0,
ParseHex("aaaaad55556aaaab55555aaaaad55556aaaab55555"),
ParseHex("155555155555155555155555155555155555155555155555"));
TestExpandAndCompress("8 21-bit chunks, based on example in the spec", 21, 0,
ParseHex("000220000a7ffffe00123022b38226ac19bdf23456"),
ParseHex("0000440000291fffff0001230045670089ab00cdef123456"));
TestExpandAndCompress("16 14-bit chunks, alternating 11s and 00s", 14, 0,
ParseHex("cccf333cccf333cccf333cccf333cccf333cccf333cccf333cccf333"),
ParseHex("3333333333333333333333333333333333333333333333333333333333333333"));
TestExpandAndCompress("8 11-bit chunks, all-ones, 2-byte padding", 11, 2,
ParseHex("ffffffffffffffffffffff"),
ParseHex("000007ff000007ff000007ff000007ff000007ff000007ff000007ff000007ff"));
}
void TestMinimalSolnRepr(const std::string &scope, size_t cBitLen,
std::vector<eh_index> indices,
std::vector<unsigned char> minimal)
{
SCOPED_TRACE(scope);
EXPECT_EQ(indices, GetIndicesFromMinimal(minimal, cBitLen));
EXPECT_EQ(minimal, GetMinimalFromIndices(indices, cBitLen));
}
TEST(equihash_tests, minimal_solution_representation) {
TestMinimalSolnRepr("Test 1", 20,
{1, 1, 1, 1, 1, 1, 1, 1},
ParseHex("000008000040000200001000008000040000200001"));
TestMinimalSolnRepr("Test 2", 20,
{2097151, 2097151, 2097151, 2097151,
2097151, 2097151, 2097151, 2097151},
ParseHex("ffffffffffffffffffffffffffffffffffffffffff"));
TestMinimalSolnRepr("Test 3", 20,
{131071, 128, 131071, 128, 131071, 128, 131071, 128},
ParseHex("0ffff8002003fffe000800ffff8002003fffe00080"));
TestMinimalSolnRepr("Test 4", 20,
{68, 41, 2097151, 1233, 665, 1023, 1, 1048575},
ParseHex("000220000a7ffffe004d10014c800ffc00002fffff"));
}
TEST(equihash_tests, is_probably_duplicate) {
std::shared_ptr<eh_trunc> p1 (new eh_trunc[4] {0, 1, 2, 3}, std::default_delete<eh_trunc[]>());
std::shared_ptr<eh_trunc> p2 (new eh_trunc[4] {0, 1, 1, 3}, std::default_delete<eh_trunc[]>());
std::shared_ptr<eh_trunc> p3 (new eh_trunc[4] {3, 1, 1, 3}, std::default_delete<eh_trunc[]>());
ASSERT_FALSE(IsProbablyDuplicate<4>(p1, 4));
ASSERT_FALSE(IsProbablyDuplicate<4>(p2, 4));
ASSERT_TRUE(IsProbablyDuplicate<4>(p3, 4));
}
#ifdef ENABLE_MINING
TEST(equihash_tests, check_basic_solver_cancelled) {
Equihash<48,5> Eh48_5;
crypto_generichash_blake2b_state state;
Eh48_5.InitialiseState(state);
uint256 V = uint256S("0x00");
crypto_generichash_blake2b_update(&state, V.begin(), V.size());
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return false;
}));
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListGeneration;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListSorting;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListColliding;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == RoundEnd;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == FinalSorting;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == FinalColliding;
}), EhSolverCancelledException);
}
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialGeneration;
}));
}
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialSorting;
}));
}
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialSubtreeEnd;
}));
}
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialIndexEnd;
}));
}
{
ASSERT_NO_THROW(Eh48_5.BasicSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialEnd;
}));
}
}
TEST(equihash_tests, check_optimised_solver_cancelled) {
Equihash<48,5> Eh48_5;
crypto_generichash_blake2b_state state;
Eh48_5.InitialiseState(state);
uint256 V = uint256S("0x00");
crypto_generichash_blake2b_update(&state, V.begin(), V.size());
{
ASSERT_NO_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return false;
}));
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListGeneration;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListSorting;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == ListColliding;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == RoundEnd;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == FinalSorting;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == FinalColliding;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialGeneration;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialSorting;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialSubtreeEnd;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialIndexEnd;
}), EhSolverCancelledException);
}
{
ASSERT_THROW(Eh48_5.OptimisedSolve(state, [](std::vector<unsigned char> soln) {
return false;
}, [](EhSolverCancelCheck pos) {
return pos == PartialEnd;
}), EhSolverCancelledException);
}
}
#endif // ENABLE_MINING