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mirror of synced 2024-11-26 00:20:50 +01:00
ImHex/plugins/builtin/include/content/helpers/diagrams.hpp

966 lines
40 KiB
C++

#pragma once
#include <hex.hpp>
#include <imgui.h>
#include <implot.h>
#include <hex/api/imhex_api.hpp>
#include <hex/api/localization_manager.hpp>
#include <hex/providers/provider.hpp>
#include <hex/providers/buffered_reader.hpp>
#include <imgui_internal.h>
#include <random>
namespace hex {
namespace impl {
inline int IntegerAxisFormatter(double value, char* buffer, int size, void *userData) {
u64 integer = static_cast<u64>(value);
return snprintf(buffer, size, static_cast<const char*>(userData), integer);
}
inline std::vector<u8> getSampleSelection(prv::Provider *provider, u64 address, size_t size, size_t sampleSize) {
const size_t sequenceCount = std::ceil(std::sqrt(sampleSize));
std::vector<u8> buffer;
if (size < sampleSize) {
buffer.resize(size);
provider->read(address, buffer.data(), size);
} else {
std::random_device randomDevice;
std::mt19937_64 random(randomDevice());
std::map<u64, std::vector<u8>> orderedData;
for (u32 i = 0; i < sequenceCount; i++) {
ssize_t offset = random() % size;
std::vector<u8> sequence;
sequence.resize(std::min<size_t>(sequenceCount, size - offset));
provider->read(address + offset, sequence.data(), sequence.size());
orderedData.insert({ offset, sequence });
}
buffer.reserve(sampleSize);
u64 lastEnd = 0x00;
for (const auto &[offset, sequence] : orderedData) {
if (offset < lastEnd)
buffer.resize(buffer.size() - (lastEnd - offset));
std::copy(sequence.begin(), sequence.end(), std::back_inserter(buffer));
lastEnd = offset + sequence.size();
}
}
return buffer;
}
inline std::vector<u8> getSampleSelection(const std::vector<u8> &inputBuffer, size_t sampleSize) {
const size_t sequenceCount = std::ceil(std::sqrt(sampleSize));
std::vector<u8> buffer;
if (inputBuffer.size() < sampleSize) {
buffer = inputBuffer;
} else {
std::random_device randomDevice;
std::mt19937_64 random(randomDevice());
std::map<u64, std::vector<u8>> orderedData;
for (u32 i = 0; i < sequenceCount; i++) {
ssize_t offset = random() % inputBuffer.size();
std::vector<u8> sequence;
sequence.reserve(sampleSize);
std::copy_n(inputBuffer.begin() + offset, std::min<size_t>(sequenceCount, inputBuffer.size() - offset), std::back_inserter(sequence));
orderedData.insert({ offset, sequence });
}
buffer.reserve(sampleSize);
u64 lastEnd = 0x00;
for (const auto &[offset, sequence] : orderedData) {
if (offset < lastEnd)
buffer.resize(buffer.size() - (lastEnd - offset));
std::copy(sequence.begin(), sequence.end(), std::back_inserter(buffer));
lastEnd = offset + sequence.size();
}
}
return buffer;
}
}
class DiagramDigram {
public:
explicit DiagramDigram(size_t sampleSize = 0x9000) : m_sampleSize(sampleSize) { }
void draw(ImVec2 size) {
ImGui::PushStyleColor(ImGuiCol_ChildBg, ImU32(ImColor(0, 0, 0)));
if (ImGui::BeginChild("##digram", size, true)) {
auto drawList = ImGui::GetWindowDrawList();
float xStep = (size.x * 0.95F) / 0xFF;
float yStep = (size.y * 0.95F) / 0xFF;
if (!this->m_processing)
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size() - 1); i++) {
auto x = this->m_buffer[i] * xStep;
auto y = this->m_buffer[i + 1] * yStep;
auto color = ImLerp(ImColor(0xFF, 0x6D, 0x01).Value, ImColor(0x01, 0x93, 0xFF).Value, float(i) / this->m_buffer.size()) + ImVec4(this->m_glowBuffer[i], this->m_glowBuffer[i], this->m_glowBuffer[i], 0.0F);
color.w = this->m_opacity;
auto pos = ImGui::GetWindowPos() + ImVec2(size.x * 0.025F, size.y * 0.025F) + ImVec2(x, y);
drawList->AddRectFilled(pos, pos + ImVec2(xStep, yStep), ImColor(color));
}
}
ImGui::EndChild();
ImGui::PopStyleColor();
}
void process(prv::Provider *provider, u64 address, size_t size) {
this->m_processing = true;
this->m_buffer = impl::getSampleSelection(provider, address, size, this->m_sampleSize);
processImpl();
this->m_processing = false;
}
void process(const std::vector<u8> &buffer) {
this->m_processing = true;
this->m_buffer = impl::getSampleSelection(buffer, this->m_sampleSize);
processImpl();
this->m_processing = false;
}
void reset(u64 size) {
this->m_processing = true;
this->m_buffer.clear();
this->m_buffer.reserve(this->m_sampleSize);
this->m_byteCount = 0;
this->m_fileSize = size;
}
void update(u8 byte) {
// Check if there is some space left
if (this->m_byteCount < this->m_fileSize) {
if ((this->m_byteCount % (this->m_fileSize / this->m_sampleSize)) == 0)
this->m_buffer.push_back(byte);
++this->m_byteCount;
if (this->m_byteCount == this->m_fileSize) {
processImpl();
this->m_processing = false;
}
}
}
private:
void processImpl() {
this->m_glowBuffer.resize(this->m_buffer.size());
std::map<u64, size_t> heatMap;
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size() - 1); i++) {
auto count = ++heatMap[this->m_buffer[i] << 8 | heatMap[i + 1]];
this->m_highestCount = std::max(this->m_highestCount, count);
}
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size() - 1); i++) {
this->m_glowBuffer[i] = std::min<float>(0.2F + (float(heatMap[this->m_buffer[i] << 8 | this->m_buffer[i + 1]]) / float(this->m_highestCount / 1000)), 1.0F);
}
this->m_opacity = (log10(float(this->m_sampleSize)) / log10(float(m_highestCount))) / 10.0F;
}
private:
size_t m_sampleSize = 0;
// The number of bytes processed and the size of
// the file to analyze (useful for iterative analysis)
u64 m_byteCount = 0;
u64 m_fileSize = 0;
std::vector<u8> m_buffer;
std::vector<float> m_glowBuffer;
float m_opacity = 0.0F;
size_t m_highestCount = 0;
std::atomic<bool> m_processing = false;
};
class DiagramLayeredDistribution {
public:
explicit DiagramLayeredDistribution(size_t sampleSize = 0x9000) : m_sampleSize(sampleSize) { }
void draw(ImVec2 size) {
ImGui::PushStyleColor(ImGuiCol_ChildBg, ImU32(ImColor(0, 0, 0)));
if (ImGui::BeginChild("##layered_distribution", size, true)) {
auto drawList = ImGui::GetWindowDrawList();
float xStep = (size.x * 0.95F) / 0xFF;
float yStep = (size.y * 0.95F) / 0xFF;
if (!this->m_processing)
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size()); i++) {
auto x = this->m_buffer[i] * xStep;
auto y = yStep * ((float(i) / this->m_buffer.size()) * 0xFF);
auto color = ImLerp(ImColor(0xFF, 0x6D, 0x01).Value, ImColor(0x01, 0x93, 0xFF).Value, float(i) / this->m_buffer.size()) + ImVec4(this->m_glowBuffer[i], this->m_glowBuffer[i], this->m_glowBuffer[i], 0.0F);
color.w = this->m_opacity;
auto pos = ImGui::GetWindowPos() + ImVec2(size.x * 0.025F, size.y * 0.025F) + ImVec2(x, y);
drawList->AddRectFilled(pos, pos + ImVec2(xStep, yStep), ImColor(color));
}
}
ImGui::EndChild();
ImGui::PopStyleColor();
}
void process(prv::Provider *provider, u64 address, size_t size) {
this->m_processing = true;
this->m_buffer = impl::getSampleSelection(provider, address, size, this->m_sampleSize);
processImpl();
this->m_processing = false;
}
void process(const std::vector<u8> &buffer) {
this->m_processing = true;
this->m_buffer = impl::getSampleSelection(buffer, this->m_sampleSize);
processImpl();
this->m_processing = false;
}
void reset(u64 size) {
this->m_processing = true;
this->m_buffer.clear();
this->m_buffer.reserve(this->m_sampleSize);
this->m_byteCount = 0;
this->m_fileSize = size;
}
void update(u8 byte) {
// Check if there is some space left
if (this->m_byteCount < this->m_fileSize) {
if ((this->m_byteCount % (this->m_fileSize / this->m_sampleSize)) == 0)
this->m_buffer.push_back(byte);
++this->m_byteCount;
if (this->m_byteCount == this->m_fileSize) {
processImpl();
this->m_processing = false;
}
}
}
private:
void processImpl() {
this->m_glowBuffer.resize(this->m_buffer.size());
std::map<u64, size_t> heatMap;
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size() - 1); i++) {
auto count = ++heatMap[this->m_buffer[i] << 8 | heatMap[i + 1]];
this->m_highestCount = std::max(this->m_highestCount, count);
}
for (size_t i = 0; i < (this->m_buffer.empty() ? 0 : this->m_buffer.size() - 1); i++) {
this->m_glowBuffer[i] = std::min<float>(0.2F + (float(heatMap[this->m_buffer[i] << 8 | this->m_buffer[i + 1]]) / float(this->m_highestCount / 1000)), 1.0F);
}
this->m_opacity = (log10(float(this->m_sampleSize)) / log10(float(m_highestCount))) / 10.0F;
}
private:
size_t m_sampleSize = 0;
// The number of bytes processed and the size of
// the file to analyze (useful for iterative analysis)
u64 m_byteCount = 0;
u64 m_fileSize = 0;
std::vector<u8> m_buffer;
std::vector<float> m_glowBuffer;
float m_opacity = 0.0F;
size_t m_highestCount = 0;
std::atomic<bool> m_processing = false;
};
class DiagramChunkBasedEntropyAnalysis {
public:
explicit DiagramChunkBasedEntropyAnalysis(u64 blockSize = 256, size_t sampleSize = 0x1000) : m_blockSize(blockSize), m_sampleSize(sampleSize) { }
void draw(ImVec2 size, ImPlotFlags flags, bool updateHandle = false) {
if (!this->m_processing && ImPlot::BeginPlot("##ChunkBasedAnalysis", size, flags)) {
ImPlot::SetupAxes("hex.builtin.common.address"_lang, "hex.builtin.view.information.entropy"_lang,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch);
ImPlot::SetupAxisFormat(ImAxis_X1, impl::IntegerAxisFormatter, (void*)("0x%04llX"));
ImPlot::SetupMouseText(ImPlotLocation_NorthEast);
// Set the axis limit to [first block : last block]
ImPlot::SetupAxesLimits(
this->m_xBlockEntropy.empty() ? 0 : this->m_xBlockEntropy.front(),
this->m_xBlockEntropy.empty() ? 0 : this->m_xBlockEntropy.back(),
-0.1F,
1.1F,
ImGuiCond_Always);
// Draw the plot
ImPlot::PlotLine("##ChunkBasedAnalysisLine", this->m_xBlockEntropy.data(), this->m_yBlockEntropySampled.data(), this->m_xBlockEntropy.size());
// The parameter updateHandle is used when using the pattern language since we don't have a provider
// but just a set of bytes, we won't be able to use the drag bar correctly.
if (updateHandle) {
// Set a draggable line on the plot
if (ImPlot::DragLineX(1, &this->m_handlePosition, ImGui::GetStyleColorVec4(ImGuiCol_Text))) {
// The line was dragged, update the position in the hex editor
// Clamp the value between the start/end of the region to analyze
this->m_handlePosition = std::clamp<double>(
this->m_handlePosition,
this->m_startAddress,
this->m_endAddress);
// Compute the position inside hex editor
u64 address = u64(std::max<double>(this->m_handlePosition, 0)) + this->m_baseAddress;
address = std::min<u64>(address, this->m_baseAddress + this->m_fileSize - 1);
ImHexApi::HexEditor::setSelection(address, 1);
}
}
ImPlot::EndPlot();
}
}
void process(prv::Provider *provider, u64 chunkSize, u64 startAddress, u64 endAddress) {
this->m_processing = true;
// Update attributes
this->m_chunkSize = chunkSize;
this->m_startAddress = startAddress;
this->m_endAddress = endAddress;
this->m_baseAddress = provider->getBaseAddress();
this->m_fileSize = provider->getSize();
// Get a file reader
auto reader = prv::ProviderReader(provider);
std::vector<u8> bytes = reader.read(this->m_startAddress, this->m_endAddress - this->m_startAddress);
this->processImpl(bytes);
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
this->m_processing = false;
}
void process(const std::vector<u8> &buffer, u64 chunkSize) {
this->m_processing = true;
// Update attributes (use buffer size as end address)
this->m_chunkSize = chunkSize;
this->m_startAddress = 0;
this->m_endAddress = buffer.size();
this->m_baseAddress = 0;
this->m_fileSize = buffer.size();
this->processImpl(buffer);
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
this->m_processing = false;
}
// Reset the entropy analysis
void reset(u64 chunkSize, u64 startAddress, u64 endAddress, u64 baseAddress, u64 size) {
this->m_processing = true;
// Update attributes
this->m_chunkSize = chunkSize;
this->m_startAddress = startAddress;
this->m_endAddress = endAddress;
this->m_baseAddress = baseAddress;
this->m_fileSize = size;
this->m_blockValueCounts = { 0 };
// Reset and resize the array
this->m_yBlockEntropy.clear();
this->m_byteCount = 0;
this->m_blockCount = 0;
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
}
// Process one byte at the time
void update(u8 byte) {
u64 totalBlock = std::ceil((this->m_endAddress - this->m_startAddress) / this->m_chunkSize);
// Check if there is still some
if (this->m_blockCount < totalBlock) {
// Increment the occurrence of the current byte
this->m_blockValueCounts[byte]++;
this->m_byteCount++;
// Check if we processed one complete chunk, if so compute the entropy and start analysing the next chunk
if (((this->m_byteCount % this->m_chunkSize) == 0) || this->m_byteCount == (this->m_endAddress - this->m_startAddress)) [[unlikely]] {
this->m_yBlockEntropy.push_back(calculateEntropy(this->m_blockValueCounts, this->m_chunkSize));
this->m_blockCount += 1;
this->m_blockValueCounts = { 0 };
}
// Check if we processed the last block, if so setup the X axis part of the data
if (this->m_blockCount == totalBlock) {
processFinalize();
this->m_processing = false;
}
}
}
// Method used to compute the entropy of a block of size `blockSize`
// using the byte occurrences from `valueCounts` array.
double calculateEntropy(const std::array<ImU64, 256> &valueCounts, size_t blockSize) const {
double entropy = 0;
u8 processedValueCount = 0;
for (const auto count : valueCounts) {
if (count == 0) [[unlikely]]
continue;
processedValueCount += 1;
double probability = static_cast<double>(count) / blockSize;
entropy += probability * std::log2(probability);
}
if (processedValueCount == 1)
return 0.0;
return std::min<double>(1.0, (-entropy) / 8); // log2(256) = 8
}
// Return the highest entropy value among all of the blocks
double getHighestEntropyBlockValue() {
double result = 0.0f;
if (!this->m_yBlockEntropy.empty())
result = *std::max_element(this->m_yBlockEntropy.begin(), this->m_yBlockEntropy.end());
return result;
}
// Return the highest entropy value among all of the blocks
u64 getHighestEntropyBlockAddress() {
u64 address = 0x00;
if (!this->m_yBlockEntropy.empty())
address = (std::max_element(this->m_yBlockEntropy.begin(), this->m_yBlockEntropy.end()) - this->m_yBlockEntropy.begin()) * this->m_blockSize;
return this->m_startAddress + address;
}
// Return the highest entropy value among all of the blocks
double getLowestEntropyBlockValue() {
double result = 0.0f;
if (this->m_yBlockEntropy.size() > 1)
result = *std::min_element(this->m_yBlockEntropy.begin(), this->m_yBlockEntropy.end() - 1);
return result;
}
// Return the highest entropy value among all of the blocks
u64 getLowestEntropyBlockAddress() {
u64 address = 0x00;
if (this->m_yBlockEntropy.size() > 1)
address = (std::min_element(this->m_yBlockEntropy.begin(), this->m_yBlockEntropy.end() - 1) - this->m_yBlockEntropy.begin()) * this->m_blockSize;
return this->m_startAddress + address;
}
// Return the number of blocks that have been processed
u64 getSize() const {
return this->m_yBlockEntropySampled.size();
}
// Return the size of the chunk used for this analysis
u64 getChunkSize() const {
return this->m_chunkSize;
}
void setHandlePosition(u64 filePosition) {
this->m_handlePosition = filePosition;
}
private:
// Private method used to factorize the process public method
void processImpl(const std::vector<u8> &bytes) {
this->m_blockValueCounts = { 0 };
// Reset and resize the array
this->m_yBlockEntropy.clear();
this->m_byteCount = 0;
this->m_blockCount = 0;
// Loop over each byte of the file (or a part of it)
for (u8 byte: bytes) {
// Increment the occurrence of the current byte
this->m_blockValueCounts[byte]++;
this->m_byteCount++;
// Check if we processed one complete chunk, if so compute the entropy and start analysing the next chunk
if (((this->m_byteCount % this->m_chunkSize) == 0) || this->m_byteCount == bytes.size() * 8) [[unlikely]] {
this->m_yBlockEntropy.push_back(calculateEntropy(this->m_blockValueCounts, this->m_chunkSize));
this->m_blockCount += 1;
this->m_blockValueCounts = { 0 };
}
}
processFinalize();
}
void processFinalize() {
// Only save at most m_sampleSize elements of the result
this->m_yBlockEntropySampled = sampleData(this->m_yBlockEntropy, std::min<size_t>(this->m_blockCount + 1, this->m_sampleSize));
if (!this->m_yBlockEntropySampled.empty())
this->m_yBlockEntropySampled.push_back(this->m_yBlockEntropySampled.back());
double stride = std::max(1.0, double(
double(std::ceil((this->m_endAddress - this->m_startAddress)) / this->m_blockSize) / this->m_yBlockEntropySampled.size()));
this->m_blockCount = this->m_yBlockEntropySampled.size() - 1;
// The m_xBlockEntropy attribute is used to specify the position of entropy values
// in the plot when the Y axis doesn't start at 0
this->m_xBlockEntropy.clear();
this->m_xBlockEntropy.resize(this->m_blockCount);
for (u64 i = 0; i < this->m_blockCount; ++i)
this->m_xBlockEntropy[i] = ((this->m_startAddress / this->m_blockSize) + stride * i) * this->m_blockSize;
this->m_xBlockEntropy.push_back(this->m_endAddress);
}
private:
// Variables used to store the parameters to process
// Chunk's size for entropy analysis
u64 m_chunkSize = 0;
u64 m_startAddress = 0x00;
u64 m_endAddress = 0x00;
// Start / size of the file
u64 m_baseAddress = 0x00;
u64 m_fileSize = 0;
// The size of the blocks (for diagram drawing)
u64 m_blockSize = 0;
// Position of the handle inside the plot
double m_handlePosition = 0.0;
// Hold the number of blocks that have been processed
// during the chunk-based entropy analysis
u64 m_blockCount = 0;
// Hold the number of bytes that have been processed
// during the analysis (useful for the iterative analysis)
u64 m_byteCount = 0;
// Array used to hold the occurrences of each byte
// (useful for the iterative analysis)
std::array<ImU64, 256> m_blockValueCounts = {};
// Variable to hold the result of the chunk-based
// entropy analysis
std::vector<double> m_xBlockEntropy;
std::vector<double> m_yBlockEntropy, m_yBlockEntropySampled;
// Sampling size, number of elements displayed in the plot,
// avoid showing to many data because it decreased the frame rate
size_t m_sampleSize = 0;
std::atomic<bool> m_processing = false;
};
class DiagramByteDistribution {
public:
DiagramByteDistribution() = default;
void draw(ImVec2 size, ImPlotFlags flags) {
if (!this->m_processing && ImPlot::BeginPlot("##distribution", size, flags)) {
ImPlot::SetupAxes("hex.builtin.common.value"_lang, "hex.builtin.common.count"_lang,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch);
ImPlot::SetupAxisScale(ImAxis_Y1, ImPlotScale_Log10);
ImPlot::SetupAxesLimits(-1, 256, 1, double(*std::max_element(this->m_valueCounts.begin(), this->m_valueCounts.end())) * 1.1F, ImGuiCond_Always);
ImPlot::SetupAxisFormat(ImAxis_X1, impl::IntegerAxisFormatter, (void*)("0x%02llX"));
ImPlot::SetupAxisTicks(ImAxis_X1, 0, 255, 17);
ImPlot::SetupMouseText(ImPlotLocation_NorthEast);
constexpr static auto x = [] {
std::array<ImU64, 256> result { 0 };
std::iota(result.begin(), result.end(), 0);
return result;
}();
ImPlot::PlotBars<ImU64>("##bytes", x.data(), this->m_valueCounts.data(), x.size(), 1);
ImPlot::EndPlot();
}
}
void process(prv::Provider *provider, u64 startAddress, u64 endAddress) {
this->m_processing = true;
// Update attributes
this->m_startAddress = startAddress;
this->m_endAddress = endAddress;
// Get a file reader
auto reader = prv::ProviderReader(provider);
std::vector<u8> bytes = reader.read(this->m_startAddress, this->m_endAddress - this->m_startAddress);
this->processImpl(bytes);
this->m_processing = false;
}
void process(const std::vector<u8> &buffer) {
this->m_processing = true;
// Update attributes
this->m_startAddress = 0;
this->m_endAddress = buffer.size();
this->processImpl(buffer);
this->m_processing = false;
}
// Reset the byte distribution array
void reset() {
this->m_processing = true;
this->m_valueCounts.fill(0);
this->m_processing = false;
}
// Process one byte at the time
void update(u8 byte) {
this->m_processing = true;
this->m_valueCounts[byte]++;
this->m_processing = false;
}
// Return byte distribution array in it's current state
std::array<ImU64, 256> & get() {
return this->m_valueCounts;
}
private:
// Private method used to factorize the process public method
void processImpl(const std::vector<u8> &bytes) {
// Reset the array
this->m_valueCounts.fill(0);
// Loop over each byte of the file (or a part of it)
// Increment the occurrence of the current byte
for (u8 byte : bytes)
this->m_valueCounts[byte]++;
}
private:
// Variables used to store the parameters to process
u64 m_startAddress = 0;
u64 m_endAddress = 0;
// Hold the result of the byte distribution analysis
std::array<ImU64, 256> m_valueCounts;
std::atomic<bool> m_processing = false;
};
class DiagramByteTypesDistribution {
public:
explicit DiagramByteTypesDistribution(u64 blockSize = 256, size_t sampleSize = 0x1000) : m_blockSize(blockSize), m_sampleSize(sampleSize){ }
void draw(ImVec2 size, ImPlotFlags flags, bool updateHandle = false) {
// Draw the result of the analysis
if (!this->m_processing && ImPlot::BeginPlot("##byte_types", size, flags)) {
ImPlot::SetupAxes("hex.builtin.common.address"_lang, "hex.builtin.common.percentage"_lang,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch,
ImPlotAxisFlags_Lock | ImPlotAxisFlags_NoHighlight | ImPlotAxisFlags_NoSideSwitch);
ImPlot::SetupAxesLimits(
this->m_xBlockTypeDistributions.empty() ? 0 : this->m_xBlockTypeDistributions.front(),
this->m_xBlockTypeDistributions.empty() ? 0 : this->m_xBlockTypeDistributions.back(),
-0.1F,
100.1F,
ImGuiCond_Always);
ImPlot::SetupLegend(ImPlotLocation_South, ImPlotLegendFlags_Horizontal | ImPlotLegendFlags_Outside);
ImPlot::SetupAxisFormat(ImAxis_X1, impl::IntegerAxisFormatter, (void*)("0x%04llX"));
ImPlot::SetupMouseText(ImPlotLocation_NorthEast);
constexpr static std::array Names = { "iscntrl", "isprint", "isspace", "isblank",
"isgraph", "ispunct", "isalnum", "isalpha",
"isupper", "islower", "isdigit", "isxdigit"
};
for (u32 i = 0; i < Names.size(); i++) {
ImPlot::PlotLine(Names[i], this->m_xBlockTypeDistributions.data(), this->m_yBlockTypeDistributionsSampled[i].data(), this->m_xBlockTypeDistributions.size());
}
// The parameter updateHandle is used when using the pattern language since we don't have a provider
// but just a set of bytes, we won't be able to use the drag bar correctly.
if (updateHandle) {
// Set a draggable line on the plot
if (ImPlot::DragLineX(1, &this->m_handlePosition, ImGui::GetStyleColorVec4(ImGuiCol_Text))) {
// The line was dragged, update the position in the hex editor
// Clamp the value between the start/end of the region to analyze
this->m_handlePosition = std::clamp<double>(
this->m_handlePosition,
this->m_startAddress,
this->m_endAddress);
// Compute the position inside hex editor
u64 address = u64(std::max<double>(this->m_handlePosition, 0)) + this->m_baseAddress;
address = std::min<u64>(address, this->m_baseAddress + this->m_fileSize - 1);
ImHexApi::HexEditor::setSelection(address, 1);
}
}
ImPlot::EndPlot();
}
}
void process(prv::Provider *provider, u64 startAddress, u64 endAddress) {
this->m_processing = true;
// Update attributes
this->m_startAddress = startAddress;
this->m_endAddress = endAddress;
this->m_baseAddress = provider->getBaseAddress();
this->m_fileSize = provider->getSize();
// Get a file reader
auto reader = prv::ProviderReader(provider);
std::vector<u8> bytes = reader.read(this->m_startAddress, this->m_endAddress - this->m_startAddress);
this->processImpl(bytes);
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
this->m_processing = false;
}
void process(const std::vector<u8> &buffer, u64 baseAddress, u64 fileSize) {
this->m_processing = true;
// Update attributes
this->m_startAddress = 0;
this->m_endAddress = buffer.size();
this->m_baseAddress = baseAddress;
this->m_fileSize = fileSize;
this->processImpl(buffer);
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
this->m_processing = false;
}
// Reset the byte type distribution analysis
void reset(u64 startAddress, u64 endAddress, u64 baseAddress, u64 size) {
this->m_processing = true;
// Update attributes
this->m_startAddress = startAddress;
this->m_endAddress = endAddress;
this->m_baseAddress = baseAddress;
this->m_fileSize = size;
this->m_byteCount = 0;
this->m_blockCount = 0;
this->m_blockValueCounts = { 0 };
// Reset and resize the array
this->m_yBlockTypeDistributions.fill({});
// Set the diagram handle position to the start of the plot
this->m_handlePosition = this->m_startAddress;
}
// Process one byte at the time
void update(u8 byte) {
u64 totalBlock = std::ceil((this->m_endAddress - this->m_startAddress) / this->m_blockSize);
// Check if there is still some block to process
if (this->m_blockCount < totalBlock) {
this->m_blockValueCounts[byte]++;
this->m_byteCount++;
if (((this->m_byteCount % this->m_blockSize) == 0) || this->m_byteCount == (this->m_endAddress - this->m_startAddress)) [[unlikely]] {
auto typeDist = calculateTypeDistribution(this->m_blockValueCounts, this->m_blockSize);
for (size_t i = 0; i < typeDist.size(); i++)
this->m_yBlockTypeDistributions[i].push_back(typeDist[i] * 100);
this->m_blockCount += 1;
this->m_blockValueCounts = { 0 };
}
// Check if we processed the last block, if so setup the X axis part of the data
if (this->m_blockCount == totalBlock) {
processFinalize();
this->m_processing = false;
}
}
}
// Return the percentage of plain text character inside the analyzed region
double getPlainTextCharacterPercentage() {
if (this->m_yBlockTypeDistributions[2].empty() || this->m_yBlockTypeDistributions[4].empty())
return -1.0;
double plainTextPercentage = std::reduce(this->m_yBlockTypeDistributions[2].begin(), this->m_yBlockTypeDistributions[2].end()) / this->m_yBlockTypeDistributions[2].size();
return plainTextPercentage + std::reduce(this->m_yBlockTypeDistributions[4].begin(), this->m_yBlockTypeDistributions[4].end()) / this->m_yBlockTypeDistributions[4].size();
}
void setHandlePosition(u64 filePosition) {
this->m_handlePosition = filePosition;
}
private:
std::array<float, 12> calculateTypeDistribution(const std::array<ImU64, 256> &valueCounts, size_t blockSize) const {
std::array<ImU64, 12> counts = {};
for (u16 value = 0x00; value < u16(valueCounts.size()); value++) {
const auto &count = valueCounts[value];
if (count == 0) [[unlikely]]
continue;
if (std::iscntrl(value))
counts[0] += count;
if (std::isprint(value))
counts[1] += count;
if (std::isspace(value))
counts[2] += count;
if (std::isblank(value))
counts[3] += count;
if (std::isgraph(value))
counts[4] += count;
if (std::ispunct(value))
counts[5] += count;
if (std::isalnum(value))
counts[6] += count;
if (std::isalpha(value))
counts[7] += count;
if (std::isupper(value))
counts[8] += count;
if (std::islower(value))
counts[9] += count;
if (std::isdigit(value))
counts[10] += count;
if (std::isxdigit(value))
counts[11] += count;
}
std::array<float, 12> distribution = {};
for (u32 i = 0; i < distribution.size(); i++)
distribution[i] = static_cast<float>(counts[i]) / blockSize;
return distribution;
}
// Private method used to factorize the process public method
void processImpl(const std::vector<u8> &bytes) {
this->m_blockValueCounts = { 0 };
this->m_yBlockTypeDistributions.fill({});
this->m_byteCount = 0;
this->m_blockCount = 0;
// Loop over each byte of the file (or a part of it)
for (u8 byte : bytes) {
this->m_blockValueCounts[byte]++;
this->m_byteCount++;
if (((this->m_byteCount % this->m_blockSize) == 0) || this->m_byteCount == (this->m_endAddress - this->m_startAddress)) [[unlikely]] {
auto typeDist = calculateTypeDistribution(this->m_blockValueCounts, this->m_blockSize);
for (size_t i = 0; i < typeDist.size(); i++)
this->m_yBlockTypeDistributions[i].push_back(typeDist[i] * 100);
this->m_blockCount += 1;
this->m_blockValueCounts = { 0 };
}
}
processFinalize();
}
void processFinalize() {
// Only save at most m_sampleSize elements of the result
for (size_t i = 0; i < this->m_yBlockTypeDistributions.size(); ++i) {
this->m_yBlockTypeDistributionsSampled[i] = sampleData(this->m_yBlockTypeDistributions[i], std::min<size_t>(this->m_blockCount + 1, this->m_sampleSize));
if (!this->m_yBlockTypeDistributionsSampled[i].empty())
this->m_yBlockTypeDistributionsSampled[i].push_back(this->m_yBlockTypeDistributionsSampled[i].back());
}
double stride = std::max(1.0, double(this->m_blockCount) / this->m_yBlockTypeDistributionsSampled[0].size());
this->m_blockCount = this->m_yBlockTypeDistributionsSampled[0].size() - 1;
// The m_xBlockTypeDistributions attribute is used to specify the position of entropy
// values in the plot when the Y axis doesn't start at 0
this->m_xBlockTypeDistributions.clear();
this->m_xBlockTypeDistributions.resize(this->m_blockCount);
for (u64 i = 0; i < this->m_blockCount; ++i)
this->m_xBlockTypeDistributions[i] = this->m_startAddress + (stride * i * this->m_blockSize);
this->m_xBlockTypeDistributions.push_back(this->m_endAddress);
}
private:
// Variables used to store the parameters to process
// The size of the block we are considering for the analysis
u64 m_blockSize = 0;
u64 m_startAddress = 0;
u64 m_endAddress = 0;
// Start / size of the file
u64 m_baseAddress = 0;
u64 m_fileSize = 0;
// Position of the handle inside the plot
double m_handlePosition = 0.0;
// Hold the number of blocks that have been processed
// during the chunk-based entropy analysis
u64 m_blockCount = 0;
// Hold the number of bytes that have been processed
// during the analysis (useful for the iterative analysis)
u64 m_byteCount = 0;
// Sampling size, number of elements displayed in the plot,
// avoid showing to many data because it decreased the frame rate
size_t m_sampleSize = 0;
// Array used to hold the occurrences of each byte
// (useful for the iterative analysis)
std::array<ImU64, 256> m_blockValueCounts = {};
// The m_xBlockTypeDistributions attributes are used to specify the position of
// the values in the plot when the Y axis doesn't start at 0
std::vector<float> m_xBlockTypeDistributions;
// Hold the result of the byte distribution analysis
std::array<std::vector<float>, 12> m_yBlockTypeDistributions, m_yBlockTypeDistributionsSampled;
std::atomic<bool> m_processing = false;
};
}