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feeratediagram.cpp
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feeratediagram.cpp
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// Copyright (c) 2023 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <stdint.h>
#include <vector>
#include <util/feefrac.h>
#include <policy/rbf.h>
#include <test/fuzz/fuzz.h>
#include <test/fuzz/util.h>
#include <assert.h>
namespace {
/** Takes the pre-computed and topologically-valid chunks and generates a fee diagram which starts at FeeFrac of (0, 0) */
std::vector<FeeFrac> BuildDiagramFromChunks(const Span<const FeeFrac> chunks)
{
std::vector<FeeFrac> diagram;
diagram.reserve(chunks.size() + 1);
diagram.emplace_back(0, 0);
for (auto& chunk : chunks) {
diagram.emplace_back(diagram.back() + chunk);
}
return diagram;
}
/** Evaluate a diagram at a specific size, returning the fee as a fraction.
*
* Fees in diagram cannot exceed 2^32, as the returned evaluation could overflow
* the FeeFrac::fee field in the result. */
FeeFrac EvaluateDiagram(int32_t size, Span<const FeeFrac> diagram)
{
assert(diagram.size() > 0);
unsigned not_above = 0;
unsigned not_below = diagram.size() - 1;
// If outside the range of diagram, extend begin/end.
if (size < diagram[not_above].size) return {diagram[not_above].fee, 1};
if (size > diagram[not_below].size) return {diagram[not_below].fee, 1};
// Perform bisection search to locate the diagram segment that size is in.
while (not_below > not_above + 1) {
unsigned mid = (not_below + not_above) / 2;
if (diagram[mid].size <= size) not_above = mid;
if (diagram[mid].size >= size) not_below = mid;
}
// If the size matches a transition point between segments, return its fee.
if (not_below == not_above) return {diagram[not_below].fee, 1};
// Otherwise, interpolate.
auto dir_coef = diagram[not_below] - diagram[not_above];
assert(dir_coef.size > 0);
// Let A = diagram[not_above] and B = diagram[not_below]
const auto& point_a = diagram[not_above];
// We want to return:
// A.fee + (B.fee - A.fee) / (B.size - A.size) * (size - A.size)
// = A.fee + dir_coef.fee / dir_coef.size * (size - A.size)
// = (A.fee * dir_coef.size + dir_coef.fee * (size - A.size)) / dir_coef.size
assert(size >= point_a.size);
return {point_a.fee * dir_coef.size + dir_coef.fee * (size - point_a.size), dir_coef.size};
}
std::weak_ordering CompareFeeFracWithDiagram(const FeeFrac& ff, Span<const FeeFrac> diagram)
{
return FeeRateCompare(FeeFrac{ff.fee, 1}, EvaluateDiagram(ff.size, diagram));
}
std::partial_ordering CompareDiagrams(Span<const FeeFrac> dia1, Span<const FeeFrac> dia2)
{
bool all_ge = true;
bool all_le = true;
for (const auto p1 : dia1) {
auto cmp = CompareFeeFracWithDiagram(p1, dia2);
if (std::is_lt(cmp)) all_ge = false;
if (std::is_gt(cmp)) all_le = false;
}
for (const auto p2 : dia2) {
auto cmp = CompareFeeFracWithDiagram(p2, dia1);
if (std::is_lt(cmp)) all_le = false;
if (std::is_gt(cmp)) all_ge = false;
}
if (all_ge && all_le) return std::partial_ordering::equivalent;
if (all_ge && !all_le) return std::partial_ordering::greater;
if (!all_ge && all_le) return std::partial_ordering::less;
return std::partial_ordering::unordered;
}
void PopulateChunks(FuzzedDataProvider& fuzzed_data_provider, std::vector<FeeFrac>& chunks)
{
chunks.clear();
LIMITED_WHILE(fuzzed_data_provider.ConsumeBool(), 50)
{
chunks.emplace_back(fuzzed_data_provider.ConsumeIntegralInRange<int64_t>(INT32_MIN>>1, INT32_MAX>>1), fuzzed_data_provider.ConsumeIntegralInRange<int32_t>(1, 1000000));
}
return;
}
} // namespace
FUZZ_TARGET(build_and_compare_feerate_diagram)
{
// Generate a random set of chunks
FuzzedDataProvider fuzzed_data_provider(buffer.data(), buffer.size());
std::vector<FeeFrac> chunks1, chunks2;
FeeFrac empty{0, 0};
PopulateChunks(fuzzed_data_provider, chunks1);
PopulateChunks(fuzzed_data_provider, chunks2);
std::vector<FeeFrac> diagram1{BuildDiagramFromChunks(chunks1)};
std::vector<FeeFrac> diagram2{BuildDiagramFromChunks(chunks2)};
assert(diagram1.front() == empty);
assert(diagram2.front() == empty);
auto real = CompareChunks(chunks1, chunks2);
auto sim = CompareDiagrams(diagram1, diagram2);
assert(real == sim);
// Do explicit evaluation at up to 1000 points, and verify consistency with the result.
LIMITED_WHILE(fuzzed_data_provider.remaining_bytes(), 1000) {
int32_t size = fuzzed_data_provider.ConsumeIntegralInRange<int32_t>(0, diagram2.back().size);
auto eval1 = EvaluateDiagram(size, diagram1);
auto eval2 = EvaluateDiagram(size, diagram2);
auto cmp = FeeRateCompare(eval1, eval2);
if (std::is_lt(cmp)) assert(!std::is_gt(real));
if (std::is_gt(cmp)) assert(!std::is_lt(real));
}
}