Merge pull request #8 from Show-maket/STM32

Stm32
Merge branch 'main' into STM32
2026-06-13 23:10:09 +00:00 · 2026-03-11 17:06:20 +03:00 · 2026-03-11 17:06:06 +03:00 · 2026-03-11 16:59:08 +03:00 · 2024-12-25 16:56:18 +03:00 · 2024-09-04 10:12:39 +03:00
39 changed files with 103 additions and 2842 deletions
--- a/.gitignore
+++ b/.gitignore
@ -1,12 +1,3 @@
 .vscode/*
 bin/*
 !.vscode/launch.json
 log/*
 /.vscode
 *.zip
 **/__pycache__
 Analyzer/raw/dll/*.dll
 Analyzer/raw/dll/*.so
 Analyzer/raw/dll/*.dylib
 /Analyzer/raw/IR_Fox/.github
 **/.build
--- a/Analyzer/raw/IR_Fox/.gitignore
+++ b/Analyzer/raw/IR_Fox/.gitignore
@ -1,2 +0,0 @@
 /build
 .DS_Store
--- a/Analyzer/raw/IR_Fox/CMakeLists.txt
+++ b/Analyzer/raw/IR_Fox/CMakeLists.txt
@ -1,26 +0,0 @@
 cmake_minimum_required(VERSION 3.13)
 project(IrFoxAnalyzer)
 add_definitions(-DLOGIC2)
 set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
 set(CMAKE_MODULE_PATH ${PROJECT_SOURCE_DIR}/cmake)
 include(ExternalAnalyzerSDK)
 set(SOURCES
 	src/IrFoxAnalyzer.cpp
 	src/IrFoxAnalyzer.h
 	src/IrFoxDecoder.cpp
 	src/IrFoxDecoder.h
 	src/IrFoxAnalyzerResults.cpp
 	src/IrFoxAnalyzerResults.h
 	src/IrFoxAnalyzerSettings.cpp
 	src/IrFoxAnalyzerSettings.h
 	src/IrFoxSimulationDataGenerator.cpp
 	src/IrFoxSimulationDataGenerator.h
 )
 add_analyzer_plugin(${PROJECT_NAME} SOURCES ${SOURCES})
--- a/Analyzer/raw/IR_Fox/CMakePresets.json
+++ b/Analyzer/raw/IR_Fox/CMakePresets.json
@ -1,49 +0,0 @@
 {
  "version": 3,
  "cmakeMinimumRequired": {
    "major": 3,
    "minor": 19,
    "patch": 0
  },
  "configurePresets": [
    {
      "name": "win-vs2022-x64",
      "displayName": "Visual Studio 2022 (x64)",
      "generator": "Visual Studio 17 2022",
      "architecture": "x64",
      "binaryDir": "${sourceDir}/build"
    },
    {
      "name": "win-vs2019-x64",
      "displayName": "Visual Studio 2019 (x64)",
      "generator": "Visual Studio 16 2019",
      "architecture": "x64",
      "binaryDir": "${sourceDir}/build"
    },
    {
      "name": "win-nmake-release",
      "displayName": "NMake Release (только из «x64 Native Tools Command Prompt for VS»)",
      "generator": "NMake Makefiles",
      "binaryDir": "${sourceDir}/build-nmake",
      "cacheVariables": {
        "CMAKE_BUILD_TYPE": "Release"
      }
    }
  ],
  "buildPresets": [
    {
      "name": "win-release",
      "configurePreset": "win-vs2022-x64",
      "configuration": "Release"
    },
    {
      "name": "win-release-vs2019",
      "configurePreset": "win-vs2019-x64",
      "configuration": "Release"
    },
    {
      "name": "nmake-release",
      "configurePreset": "win-nmake-release"
    }
  ]
 }
--- a/Analyzer/raw/IR_Fox/build_msvc.bat
+++ b/Analyzer/raw/IR_Fox/build_msvc.bat
@ -1,21 +0,0 @@
@echo off
 setlocal EnableDelayedExpansion
 cd /d "%~dp0"
 if not exist build\CMakeCache.txt (
  echo Run configure_msvc.bat first.
  exit /b 1
 )
 set "VSWHERE=%ProgramFiles(x86)%\Microsoft Visual Studio\Installer\vswhere.exe"
 for /f "usebackq tokens=*" %%i in (`"%VSWHERE%" -latest -products * -requires Microsoft.VisualStudio.Component.VC.Tools.x86.x64 -property installationPath`) do set "VSINSTALL=%%i"
 if not defined VSINSTALL (
  echo MSVC not found. Add C++ workload in Visual Studio Installer.
  exit /b 1
 )
 call "!VSINSTALL!\Common7\Tools\VsDevCmd.bat" -arch=x64 -host_arch=x64
 if errorlevel 1 exit /b 1
 cmake --build build
 pause
 exit /b %ERRORLEVEL%
--- a/Analyzer/raw/IR_Fox/cmake/ExternalAnalyzerSDK.cmake
+++ b/Analyzer/raw/IR_Fox/cmake/ExternalAnalyzerSDK.cmake
@ -1,66 +0,0 @@
 include(FetchContent)
 set(CMAKE_CXX_STANDARD 11)
 set(CMAKE_CXX_STANDARD_REQUIRED YES)
 if(NOT CMAKE_RUNTIME_OUTPUT_DIRECTORY OR NOT CMAKE_LIBRARY_OUTPUT_DIRECTORY)
 	set(CMAKE_RUNTIME_OUTPUT_DIRECTORY ${PROJECT_BINARY_DIR}/bin/)
 	set(CMAKE_LIBRARY_OUTPUT_DIRECTORY ${PROJECT_BINARY_DIR}/bin/)
 endif()
 if(NOT TARGET Saleae::AnalyzerSDK)
 	FetchContent_Declare(
 		analyzersdk
 		GIT_REPOSITORY https://github.com/saleae/AnalyzerSDK.git
 		GIT_TAG master
 		GIT_SHALLOW True
 		GIT_PROGRESS True
 	)
 	FetchContent_GetProperties(analyzersdk)
 	if(NOT analyzersdk_POPULATED)
 		FetchContent_Populate(analyzersdk)
 		include(${analyzersdk_SOURCE_DIR}/AnalyzerSDKConfig.cmake)
 		if(APPLE OR WIN32)
 			get_target_property(analyzersdk_lib_location Saleae::AnalyzerSDK IMPORTED_LOCATION)
 			if(CMAKE_LIBRARY_OUTPUT_DIRECTORY)
 				file(COPY ${analyzersdk_lib_location} DESTINATION ${CMAKE_LIBRARY_OUTPUT_DIRECTORY})
 			else()
 				message(WARNING "Please define CMAKE_RUNTIME_OUTPUT_DIRECTORY and CMAKE_LIBRARY_OUTPUT_DIRECTORY if you want unit tests to locate ${analyzersdk_lib_location}")
 			endif()
 		endif()
 	endif()
 endif()
 # Shared folder for all Saleae LLA plugins in this repo: Analyzer/raw/dll
 set(ANALYZER_DLL_OUT_DIR "${CMAKE_SOURCE_DIR}/../dll")
 get_filename_component(ANALYZER_DLL_OUT_DIR "${ANALYZER_DLL_OUT_DIR}" ABSOLUTE)
 file(MAKE_DIRECTORY "${ANALYZER_DLL_OUT_DIR}")
 function(add_analyzer_plugin TARGET)
 	set(options)
 	set(single_value_args)
 	set(multi_value_args SOURCES)
 	cmake_parse_arguments(_p "${options}" "${single_value_args}" "${multi_value_args}" ${ARGN})
 	add_library(${TARGET} MODULE ${_p_SOURCES})
 	target_link_libraries(${TARGET} PRIVATE Saleae::AnalyzerSDK)
 	set(ANALYZER_DESTINATION "Analyzers")
 	install(TARGETS ${TARGET} RUNTIME DESTINATION ${ANALYZER_DESTINATION}
 		LIBRARY DESTINATION ${ANALYZER_DESTINATION})
 	set_target_properties(${TARGET} PROPERTIES
 		RUNTIME_OUTPUT_DIRECTORY "${ANALYZER_DLL_OUT_DIR}"
 		LIBRARY_OUTPUT_DIRECTORY "${ANALYZER_DLL_OUT_DIR}")
 	if(CMAKE_CONFIGURATION_TYPES)
 		foreach(CFG ${CMAKE_CONFIGURATION_TYPES})
 			string(TOUPPER ${CFG} CFG_UPPER)
 			set_target_properties(${TARGET} PROPERTIES
 				RUNTIME_OUTPUT_DIRECTORY_${CFG_UPPER} "${ANALYZER_DLL_OUT_DIR}"
 				LIBRARY_OUTPUT_DIRECTORY_${CFG_UPPER} "${ANALYZER_DLL_OUT_DIR}")
 		endforeach()
 	endif()
 endfunction()
--- a/Analyzer/raw/IR_Fox/configure_msvc.bat
+++ b/Analyzer/raw/IR_Fox/configure_msvc.bat
@ -1,39 +0,0 @@
@echo off
 setlocal EnableDelayedExpansion
 cd /d "%~dp0"
 echo === IrFoxAnalyzer: configure with MSVC ===
 echo.
 set "VSWHERE=%ProgramFiles(x86)%\Microsoft Visual Studio\Installer\vswhere.exe"
 if not exist "%VSWHERE%" (
  echo [ERROR] vswhere not found. Install one of:
  echo   - Visual Studio 2022 with workload "Desktop development with C++"
  echo   - Build Tools for Visual Studio 2022: https://visualstudio.microsoft.com/visual-cpp-build-tools/
  echo     ^(select "Desktop development with C++" / MSVC, Windows SDK^)
  exit /b 1
 )
 for /f "usebackq tokens=*" %%i in (`"%VSWHERE%" -latest -products * -requires Microsoft.VisualStudio.Component.VC.Tools.x86.x64 -property installationPath`) do set "VSINSTALL=%%i"
 if not defined VSINSTALL (
  echo [ERROR] MSVC toolset not found. Add "Desktop development with C++" in Visual Studio Installer.
  exit /b 1
 )
 echo Found: !VSINSTALL!
 call "!VSINSTALL!\Common7\Tools\VsDevCmd.bat" -arch=x64 -host_arch=x64
 if errorlevel 1 exit /b 1
 if exist build rmdir /s /q build
 if exist build-nmake rmdir /s /q build-nmake
 mkdir build
 cd build
 cmake .. -G "NMake Makefiles" -DCMAKE_BUILD_TYPE=Release
 if errorlevel 1 exit /b 1
 echo.
 echo Configure OK. Build: build_msvc.bat ^(or from same VS env: cd build ^& cmake --build .^)
 echo Output DLL: ..\dll\ ^(all analyzers share this folder^)
 pause
 exit /b 0
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzer.cpp
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzer.cpp
@ -1,280 +0,0 @@
 #include "IrFoxAnalyzer.h"
 #include "IrFoxAnalyzerSettings.h"
 #include "IrFoxDecoder.h"
 #include <AnalyzerChannelData.h>
 #include <AnalyzerResults.h>
 #include <algorithm>
 #include <cstdio>
 #include <cstring>
 #include <string>
 #include <vector>
 IrFoxAnalyzer::IrFoxAnalyzer()
 	: Analyzer2(),
 	  mSettings(),
 	  mSimulationInitilized(false)
 {
 	SetAnalyzerSettings(&mSettings);
 	UseFrameV2();
 }
 IrFoxAnalyzer::~IrFoxAnalyzer()
 {
 	KillThread();
 }
 void IrFoxAnalyzer::SetupResults()
 {
 	m_packet_hex_by_frame.clear();
 	mResults.reset(new IrFoxAnalyzerResults(this, &mSettings));
 	SetAnalyzerResults(mResults.get());
 	mResults->AddChannelBubblesWillAppearOn(mSettings.mInputChannel);
 }
 static void append_hex(std::string& s, const uint8_t* p, size_t n, size_t max_bytes = 64)
 {
 	static const char* hd = "0123456789abcdef";
 	const size_t m = n < max_bytes ? n : max_bytes;
 	for (size_t i = 0; i < m; i++)
 	{
 		s.push_back(hd[p[i] >> 4]);
 		s.push_back(hd[p[i] & 0xFu]);
 		if (i + 1 < m)
 			s.push_back(' ');
 	}
 	if (n > max_bytes)
 		s += "...";
 }
 const char* IrFoxAnalyzer::PacketHexForFrame(U64 frame_id)
 {
 	auto it = m_packet_hex_by_frame.find(frame_id);
 	if (it == m_packet_hex_by_frame.end())
 		return "";
 	m_hex_scratch = it->second;
 	return m_hex_scratch.c_str();
 }
 const char* IrFoxAnalyzer::BubbleTextForFrame(U64 frame_id) const
 {
 	auto it = m_bubble_text_by_frame.find(frame_id);
 	if (it == m_bubble_text_by_frame.end())
 		return "";
 	m_bubble_scratch = it->second;
 	return m_bubble_scratch.c_str();
 }
 void IrFoxAnalyzer::WorkerThread()
 {
 	mIr = GetAnalyzerChannelData(mSettings.mInputChannel);
 	m_packet_hex_by_frame.clear();
 	m_bubble_text_by_frame.clear();
 	const U32 fs = GetSampleRate();
 	IrFoxDecoder decoder;
 	decoder.reset();
 	/** Потоковый фильтр: убирает импульсы короче kMinFilteredPulseUs (иголки/дребезг в сэмплах). */
 	const U64 min_seg_samples =
 		std::max<U64>(1ULL, static_cast<U64>((static_cast<double>(irfox::kMinFilteredPulseUs) * 1e-6) * static_cast<double>(fs) + 0.5));
 	struct RawEdge
 	{
 		U64 sample;
 		bool rising;
 	};
 	std::vector<RawEdge> pending;
 	U64 last_dec_edge_sample = 0;
 	bool last_dec_edge_valid = false;
 	auto collapse_short_pairs = [&]() {
 		for (size_t i = 0; i + 1 < pending.size();)
 		{
 			if (pending[i + 1].sample - pending[i].sample < min_seg_samples)
 			{
 				pending.erase(pending.begin() + static_cast<std::ptrdiff_t>(i),
 							  pending.begin() + static_cast<std::ptrdiff_t>(i + 2));
 				if (i > 0)
 					--i;
 			}
 			else
 				++i;
 		}
 	};
 	auto strip_vs_last_decoder = [&]() {
 		for (;;)
 		{
 			collapse_short_pairs();
 			if (!last_dec_edge_valid || pending.empty())
 				return;
 			if (pending[0].sample - last_dec_edge_sample >= min_seg_samples)
 				return;
 			pending.erase(pending.begin());
 		}
 	};
 	U32 frames_since_commit = 0;
 	const U32 kCommitBatch = 256;
 	IrFoxOnBit on_bit = [&](const IrFoxEmitBit& e) {
 		Frame frame;
 		frame.mStartingSampleInclusive = static_cast<S64>(e.start_sample);
 		frame.mEndingSampleInclusive = static_cast<S64>(e.end_sample);
 		frame.mType = e.frame_type;
 		frame.mData1 = e.bit_value;
 		frame.mData2 = e.bit_index | (U64(e.err_low) << 16) | (U64(e.err_high) << 24) | (U64(e.err_other) << 32);
 		frame.mFlags = e.mflags;
 		// В SDK только ERROR/WARNING меняют цвет бабла; sync выделяем янтарным (как warning), данные — обычные.
 		if (e.frame_type == IRF_FT_SYNC_BIT)
 			frame.mFlags |= DISPLAY_AS_WARNING_FLAG;
 		const U64 fid = mResults->AddFrame(frame);
 		if (e.bubble_text[0] != '\0')
 			m_bubble_text_by_frame[fid] = e.bubble_text;
 		if (++frames_since_commit >= kCommitBatch)
 		{
 			mResults->CommitResults();
 			frames_since_commit = 0;
 		}
 	};
 	IrFoxOnPacket on_pkt = [&](const IrFoxEmitPacket& p) {
 		Frame frame;
 		frame.mStartingSampleInclusive = static_cast<S64>(p.start_sample);
 		frame.mEndingSampleInclusive = static_cast<S64>(p.end_sample);
 		frame.mType = p.crc_ok ? IRF_FT_PACKET_OK : IRF_FT_PACKET_CRC_FAIL;
 		frame.mData1 = p.pack_size;
 		frame.mData2 = (U64(p.err_low) << 0) | (U64(p.err_high) << 8) | (U64(p.err_other) << 16);
 		if (!p.crc_ok)
 			frame.mFlags |= DISPLAY_AS_ERROR_FLAG;
 		const U64 fid = mResults->AddFrame(frame);
 		std::string hx;
 		append_hex(hx, p.data_bytes, p.pack_size);
 		m_packet_hex_by_frame[fid] = std::move(hx);
 		FrameV2 fv2;
 		fv2.AddBoolean("crc_ok", p.crc_ok);
 		fv2.AddInteger("len", static_cast<S64>(p.pack_size));
 		fv2.AddInteger("err_low", static_cast<S64>(p.err_low));
 		fv2.AddInteger("err_high", static_cast<S64>(p.err_high));
 		fv2.AddInteger("err_other", static_cast<S64>(p.err_other));
 		fv2.AddByteArray("data", p.data_bytes, p.pack_size);
 		mResults->AddFrameV2(fv2, p.crc_ok ? "packet_ok" : "packet_bad", static_cast<U64>(p.start_sample),
 							  static_cast<U64>(p.end_sample));
 		if (++frames_since_commit >= kCommitBatch)
 		{
 			mResults->CommitResults();
 			frames_since_commit = 0;
 		}
 	};
 	auto emit_confirmed_edges = [&]() {
 		for (;;)
 		{
 			collapse_short_pairs();
 			strip_vs_last_decoder();
 			if (pending.size() < 2)
 				return;
 			if (pending[1].sample - pending[0].sample < min_seg_samples)
 				continue;
 			decoder.processEdge(pending[0].sample, pending[0].rising, fs, on_bit, on_pkt);
 			last_dec_edge_sample = pending[0].sample;
 			last_dec_edge_valid = true;
 			pending.erase(pending.begin());
 		}
 	};
 	auto flush_pending_tail = [&]() {
 		collapse_short_pairs();
 		strip_vs_last_decoder();
 		while (pending.size() >= 2 && pending[1].sample - pending[0].sample >= min_seg_samples)
 		{
 			decoder.processEdge(pending[0].sample, pending[0].rising, fs, on_bit, on_pkt);
 			last_dec_edge_sample = pending[0].sample;
 			last_dec_edge_valid = true;
 			pending.erase(pending.begin());
 			collapse_short_pairs();
 			strip_vs_last_decoder();
 		}
 		if (pending.size() == 1)
 		{
 			decoder.processEdge(pending[0].sample, pending[0].rising, fs, on_bit, on_pkt);
 			last_dec_edge_sample = pending[0].sample;
 			last_dec_edge_valid = true;
 			pending.clear();
 		}
 	};
 	for (;;)
 	{
 		CheckIfThreadShouldExit();
 		const U64 segment_start = mIr->GetSampleNumber();
 		const BitState level = mIr->GetBitState();
 		mIr->AdvanceToNextEdge();
 		const U64 edge_sample = mIr->GetSampleNumber();
 		if (edge_sample == segment_start)
 			break;
 		const BitState new_level = mIr->GetBitState();
 		const bool rising = (new_level == BIT_HIGH);
 		pending.push_back(RawEdge{edge_sample, rising});
 		emit_confirmed_edges();
 		ReportProgress(edge_sample);
 	}
 	flush_pending_tail();
 	decoder.flushEnd(mIr->GetSampleNumber(), fs, on_bit, on_pkt);
 	if (frames_since_commit != 0)
 		mResults->CommitResults();
 }
 bool IrFoxAnalyzer::NeedsRerun()
 {
 	return false;
 }
 U32 IrFoxAnalyzer::GenerateSimulationData(U64 minimum_sample_index, U32 device_sample_rate,
 										  SimulationChannelDescriptor** simulation_channels)
 {
 	if (mSimulationInitilized == false)
 	{
 		mSimulationDataGenerator.Initialize(GetSimulationSampleRate(), &mSettings);
 		mSimulationInitilized = true;
 	}
 	return mSimulationDataGenerator.GenerateSimulationData(minimum_sample_index, device_sample_rate,
 															simulation_channels);
 }
 U32 IrFoxAnalyzer::GetMinimumSampleRateHz()
 {
 	return 200000;
 }
 const char* IrFoxAnalyzer::GetAnalyzerName() const
 {
 	return "IR Fox";
 }
 const char* GetAnalyzerName()
 {
 	return "IR Fox";
 }
 Analyzer* CreateAnalyzer()
 {
 	return new IrFoxAnalyzer();
 }
 void DestroyAnalyzer(Analyzer* analyzer)
 {
 	delete analyzer;
 }
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzer.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzer.h
@ -1,49 +0,0 @@
 #ifndef IRFOX_ANALYZER_H
 #define IRFOX_ANALYZER_H
 #include <Analyzer.h>
 #include "IrFoxAnalyzerSettings.h"
 #include "IrFoxAnalyzerResults.h"
 #include "IrFoxSimulationDataGenerator.h"
 #include <memory>
 #include <string>
 #include <unordered_map>
 class ANALYZER_EXPORT IrFoxAnalyzer : public Analyzer2
 {
 public:
 	IrFoxAnalyzer();
 	virtual ~IrFoxAnalyzer();
 	virtual void SetupResults();
 	virtual void WorkerThread();
 	virtual U32 GenerateSimulationData(U64 newest_sample_requested, U32 sample_rate,
 									 SimulationChannelDescriptor** simulation_channels);
 	virtual U32 GetMinimumSampleRateHz();
 	virtual const char* GetAnalyzerName() const;
 	virtual bool NeedsRerun();
 	const char* PacketHexForFrame(U64 frame_id);
 	const char* BubbleTextForFrame(U64 frame_id) const;
 protected:
 	IrFoxAnalyzerSettings mSettings;
 	std::unique_ptr<IrFoxAnalyzerResults> mResults;
 	AnalyzerChannelData* mIr;
 	IrFoxSimulationDataGenerator mSimulationDataGenerator;
 	bool mSimulationInitilized;
 	std::unordered_map<U64, std::string> m_packet_hex_by_frame;
 	std::unordered_map<U64, std::string> m_bubble_text_by_frame;
 	mutable std::string m_hex_scratch;
 	mutable std::string m_bubble_scratch;
 };
 extern "C" ANALYZER_EXPORT const char* __cdecl GetAnalyzerName();
 extern "C" ANALYZER_EXPORT Analyzer* __cdecl CreateAnalyzer();
 extern "C" ANALYZER_EXPORT void __cdecl DestroyAnalyzer(Analyzer* analyzer);
 #endif
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerResults.cpp
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerResults.cpp
@ -1,175 +0,0 @@
 #include "IrFoxAnalyzerResults.h"
 #include <AnalyzerHelpers.h>
 #include <AnalyzerResults.h>
 #include "IrFoxAnalyzer.h"
 #include "IrFoxAnalyzerSettings.h"
 #include "IrFoxDecoder.h"
 #include <cstdio>
 #include <fstream>
 IrFoxAnalyzerResults::IrFoxAnalyzerResults(IrFoxAnalyzer* analyzer, IrFoxAnalyzerSettings* settings)
 	: AnalyzerResults(),
 	  mSettings(settings),
 	  mAnalyzer(analyzer)
 {
 }
 IrFoxAnalyzerResults::~IrFoxAnalyzerResults()
 {
 }
 void IrFoxAnalyzerResults::GenerateBubbleText(U64 frame_index, Channel& channel, DisplayBase display_base)
 {
 	(void)display_base;
 	(void)channel;
 	ClearResultStrings();
 	Frame frame = GetFrame(frame_index);
 	char line[256];
 	switch (frame.mType)
 	{
 	case IRF_FT_DATA_BIT:
 	case IRF_FT_SYNC_BIT:
 	case IRF_FT_PREAMBLE:
 	case IRF_FT_OVERFLOW:
 	case IRF_FT_ABORT:
 	{
 		const char* bt = mAnalyzer->BubbleTextForFrame(frame_index);
 		if (bt && bt[0])
 			AddResultString(bt);
 		else if (frame.mType == IRF_FT_DATA_BIT)
 			AddResultString(frame.mData1 ? "1" : "0");
 		else if (frame.mType == IRF_FT_SYNC_BIT)
 		{
 			snprintf(line, sizeof line, "sync: %s", frame.mData1 ? "1" : "0");
 			AddResultString(line);
 		}
 		else if (frame.mType == IRF_FT_OVERFLOW)
 			AddResultString("OVF");
 		else if (frame.mType == IRF_FT_ABORT)
 			AddResultString("SYNC!");
 		else
 			AddResultString("PRE");
 		break;
 	}
 	case IRF_FT_PACKET_OK:
 	case IRF_FT_PACKET_CRC_FAIL:
 	{
 		snprintf(line, sizeof line, "%s %lluB", frame.mType == IRF_FT_PACKET_OK ? "OK" : "CRC",
 				 (unsigned long long)frame.mData1);
 		AddResultString(line);
 		const char* hx = mAnalyzer->PacketHexForFrame(frame_index);
 		if (hx && hx[0])
 			AddResultString(hx);
 		break;
 	}
 	default:
 		snprintf(line, sizeof line, "? type=%u", static_cast<unsigned>(frame.mType));
 		AddResultString(line);
 		break;
 	}
 }
 void IrFoxAnalyzerResults::GenerateExportFile(const char* file, DisplayBase display_base, U32 export_type_user_id)
 {
 	(void)export_type_user_id;
 	(void)display_base;
 	std::ofstream file_stream(file, std::ios::out);
 	const U64 trigger_sample = mAnalyzer->GetTriggerSample();
 	const U32 sample_rate = mAnalyzer->GetSampleRate();
 	file_stream << "Time[s],Type,Data1,bit_idx,err_low,err_high,err_other,Flags,Hex" << std::endl;
 	const U64 num_frames = GetNumFrames();
 	for (U32 i = 0; i < num_frames; i++)
 	{
 		Frame frame = GetFrame(i);
 		char time_str[128];
 		AnalyzerHelpers::GetTimeString(frame.mStartingSampleInclusive, trigger_sample, sample_rate, time_str, 128);
 		const char* typ = "?";
 		switch (frame.mType)
 		{
 		case IRF_FT_DATA_BIT:
 			typ = "D";
 			break;
 		case IRF_FT_SYNC_BIT:
 			typ = "S";
 			break;
 		case IRF_FT_PACKET_OK:
 			typ = "OK";
 			break;
 		case IRF_FT_PACKET_CRC_FAIL:
 			typ = "CRC";
 			break;
 		case IRF_FT_OVERFLOW:
 			typ = "OVF";
 			break;
 		case IRF_FT_ABORT:
 			typ = "ABORT";
 			break;
 		case IRF_FT_PREAMBLE:
 			typ = "PRE";
 			break;
 		default:
 			break;
 		}
 		const char* hx = mAnalyzer->PacketHexForFrame(i);
 		if (!hx)
 			hx = "";
 		U64 bit_idx = 0;
 		U32 err_l = 0, err_h = 0, err_o = 0;
 		if (frame.mType == IRF_FT_DATA_BIT || frame.mType == IRF_FT_SYNC_BIT ||
 			frame.mType == IRF_FT_OVERFLOW || frame.mType == IRF_FT_ABORT)
 		{
 			bit_idx = frame.mData2 & 0xFFFFull;
 			err_l = static_cast<U32>((frame.mData2 >> 16) & 0xFFull);
 			err_h = static_cast<U32>((frame.mData2 >> 24) & 0xFFull);
 			err_o = static_cast<U32>((frame.mData2 >> 32) & 0xFFull);
 		}
 		file_stream << time_str << "," << typ << "," << frame.mData1 << "," << bit_idx << "," << err_l << "," << err_h
 					<< "," << err_o << "," << static_cast<unsigned>(frame.mFlags) << "," << hx << std::endl;
 		if (UpdateExportProgressAndCheckForCancel(i, num_frames) == true)
 		{
 			file_stream.close();
 			return;
 		}
 	}
 	file_stream.close();
 }
 void IrFoxAnalyzerResults::GenerateFrameTabularText(U64 frame_index, DisplayBase display_base)
 {
 #ifdef SUPPORTS_PROTOCOL_SEARCH
 	(void)display_base;
 	Frame frame = GetFrame(frame_index);
 	ClearTabularText();
 	char buf[64];
 	snprintf(buf, sizeof buf, "t%u", static_cast<unsigned>(frame.mType));
 	AddTabularText(buf);
 	snprintf(buf, sizeof buf, "%llu", (unsigned long long)frame.mData1);
 	AddTabularText(buf);
 #endif
 }
 void IrFoxAnalyzerResults::GeneratePacketTabularText(U64 packet_id, DisplayBase display_base)
 {
 	(void)packet_id;
 	(void)display_base;
 }
 void IrFoxAnalyzerResults::GenerateTransactionTabularText(U64 transaction_id, DisplayBase display_base)
 {
 	(void)transaction_id;
 	(void)display_base;
 }
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerResults.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerResults.h
@ -1,27 +0,0 @@
 #ifndef IRFOX_ANALYZER_RESULTS
 #define IRFOX_ANALYZER_RESULTS
 #include <AnalyzerResults.h>
 class IrFoxAnalyzer;
 class IrFoxAnalyzerSettings;
 class IrFoxAnalyzerResults : public AnalyzerResults
 {
 public:
 	IrFoxAnalyzerResults(IrFoxAnalyzer* analyzer, IrFoxAnalyzerSettings* settings);
 	virtual ~IrFoxAnalyzerResults();
 	virtual void GenerateBubbleText(U64 frame_index, Channel& channel, DisplayBase display_base);
 	virtual void GenerateExportFile(const char* file, DisplayBase display_base, U32 export_type_user_id);
 	virtual void GenerateFrameTabularText(U64 frame_index, DisplayBase display_base);
 	virtual void GeneratePacketTabularText(U64 packet_id, DisplayBase display_base);
 	virtual void GenerateTransactionTabularText(U64 transaction_id, DisplayBase display_base);
 protected:
 	IrFoxAnalyzerSettings* mSettings;
 	IrFoxAnalyzer* mAnalyzer;
 };
 #endif
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerSettings.cpp
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerSettings.cpp
@ -1,62 +0,0 @@
 #include "IrFoxAnalyzerSettings.h"
 #include <AnalyzerHelpers.h>
 IrFoxAnalyzerSettings::IrFoxAnalyzerSettings()
 	: mInputChannel(UNDEFINED_CHANNEL),
 	  mInputChannelInterface()
 {
 	mInputChannelInterface.SetTitleAndTooltip(
 		"IR",
 		"Demodulated IR receiver output (e.g. TSOP: idle HIGH, active LOW)");
 	mInputChannelInterface.SetChannel(mInputChannel);
 	AddInterface(&mInputChannelInterface);
 	AddExportOption(0, "Export as text/csv file");
 	AddExportExtension(0, "text", "txt");
 	AddExportExtension(0, "csv", "csv");
 	ClearChannels();
 	AddChannel(mInputChannel, "IR", false);
 }
 IrFoxAnalyzerSettings::~IrFoxAnalyzerSettings()
 {
 }
 bool IrFoxAnalyzerSettings::SetSettingsFromInterfaces()
 {
 	mInputChannel = mInputChannelInterface.GetChannel();
 	ClearChannels();
 	AddChannel(mInputChannel, "IR Fox", true);
 	return true;
 }
 void IrFoxAnalyzerSettings::UpdateInterfacesFromSettings()
 {
 	mInputChannelInterface.SetChannel(mInputChannel);
 }
 void IrFoxAnalyzerSettings::LoadSettings(const char* settings)
 {
 	SimpleArchive text_archive;
 	text_archive.SetString(settings);
 	text_archive >> mInputChannel;
 	ClearChannels();
 	AddChannel(mInputChannel, "IR Fox", true);
 	UpdateInterfacesFromSettings();
 }
 const char* IrFoxAnalyzerSettings::SaveSettings()
 {
 	SimpleArchive text_archive;
 	text_archive << mInputChannel;
 	return SetReturnString(text_archive.GetString());
 }
--- a/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerSettings.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxAnalyzerSettings.h
@ -1,24 +0,0 @@
 #ifndef IRFOX_ANALYZER_SETTINGS
 #define IRFOX_ANALYZER_SETTINGS
 #include <AnalyzerSettings.h>
 #include <AnalyzerTypes.h>
 class IrFoxAnalyzerSettings : public AnalyzerSettings
 {
 public:
 	IrFoxAnalyzerSettings();
 	virtual ~IrFoxAnalyzerSettings();
 	virtual bool SetSettingsFromInterfaces();
 	void UpdateInterfacesFromSettings();
 	virtual void LoadSettings(const char* settings);
 	virtual const char* SaveSettings();
 	Channel mInputChannel;
 protected:
 	AnalyzerSettingInterfaceChannel mInputChannelInterface;
 };
 #endif
--- a/Analyzer/raw/IR_Fox/src/IrFoxDecoder.cpp
+++ b/Analyzer/raw/IR_Fox/src/IrFoxDecoder.cpp
@ -1,593 +0,0 @@
 #include "IrFoxDecoder.h"
 #include <AnalyzerResults.h>
 #include <algorithm>
 #include <cstdio>
 #include <cmath>
 #include <cstring>
 void IrFoxDecoder::reset()
 {
 	*this = IrFoxDecoder{};
 	rise_sync_time_us = irfox::kBitTimeUs;
 	next_control_bit = irfox::kBitPerByte;
 	have_last_processed = false;
 	last_processed_edge_us = 0;
 }
 uint16_t IrFoxDecoder::ceil_div_u16(uint16_t val, uint16_t divider)
 {
 	if (divider == 0)
 		return 0;
 	int ret = val / divider;
 	if ((val << 4) / divider - (ret << 4) >= 8)
 		ret++;
 	return static_cast<uint16_t>(ret);
 }
 uint8_t IrFoxDecoder::crc8(const uint8_t* data, uint8_t start, uint8_t end, uint8_t poly)
 {
 	uint8_t crc = 0xff;
 	for (size_t i = start; i < end; i++)
 	{
 		crc ^= data[i];
 		for (size_t j = 0; j < 8; j++)
 		{
 			if ((crc & 0x80) != 0)
 				crc = static_cast<uint8_t>((crc << 1) ^ poly);
 			else
 				crc <<= 1;
 		}
 	}
 	return crc;
 }
 bool IrFoxDecoder::crc_check(uint8_t len, uint16_t& crc_out)
 {
 	crc_out = 0;
 	crc_out = static_cast<uint16_t>(static_cast<uint16_t>(crc8(data_buffer, 0, len, irfox::kPoly1) << 8) & 0xFF00u);
 	crc_out = static_cast<uint16_t>(crc_out | (crc8(data_buffer, 0, static_cast<uint8_t>(len + 1), irfox::kPoly2) & 0xFFu));
 	const bool ok = (data_buffer[len] == static_cast<uint8_t>((crc_out >> 8) & 0xFF)) &&
 					(data_buffer[len + 1] == static_cast<uint8_t>(crc_out & 0xFF));
 	return ok;
 }
 void IrFoxDecoder::first_rx()
 {
 	err_low_signal = err_high_signal = err_other = 0;
 	pack_size = 0;
 	is_buffer_overflow = false;
 	is_available = false;
 	buf_bit_pos = 0;
 	is_data = true;
 	i_data_buffer = 0;
 	next_control_bit = irfox::kBitPerByte;
 	i_sync_bit = 0;
 	err_sync_bit = 0;
 	is_wrong_pack = false;
 	is_preamb = true;
 	is_recive = false;
 	is_recive_raw = false;
 	msg_type_receive = 0;
 	rise_sync_time_us = irfox::kBitTimeUs;
 	std::memset(data_buffer, 0, sizeof data_buffer);
 	preamble_bubble_start_valid_ = false;
 	trim_first_data_bit_cell_ = false;
 }
 void IrFoxDecoder::listen_start(double t_us)
 {
 	const uint32_t irmax = irfox::irTimeoutUs(rise_sync_time_us);
 	// Как IR_DecoderRaw::listenStart: пауза по lastEdgeTime, не по prevRise.
 	if (is_recive_raw && last_edge_time_us > 0.0 && (t_us - last_edge_time_us) > irmax * 2.0)
 	{
 		is_recive_raw = false;
 		first_rx();
 	}
 }
 void IrFoxDecoder::check_timeout(double t_us)
 {
 	if (!is_recive)
 		return;
 	const uint32_t irmax = irfox::irTimeoutUs(rise_sync_time_us);
 	if (t_us - last_edge_time_us > irmax * 2.0)
 	{
 		// Как IR_DecoderRaw::checkTimeout после фикса: полный сброс, иначе залипание FSM.
 		is_recive = false;
 		msg_type_receive = 0;
 		is_recive_raw = false;
 		first_rx();
 		// Не last_edge_time_us = t_us: как IR_DecoderRaw — не расходить с «хвостом» фронтов.
 	}
 }
 void IrFoxDecoder::write_to_buffer(bool bit, bool pack_trace_invert_fix, uint64_t cell_start_s, uint64_t cell_end_s,
 								   const IrFoxOnBit& on_bit, const IrFoxOnPacket& on_pkt, IrFoxEmitBitMode emit_mode)
 {
 	if (i_data_buffer > irfox::kDataByteSizeMax * 8u)
 	{
 		if (!is_buffer_overflow && on_bit)
 		{
 			IrFoxEmitBit e{};
 			e.start_sample = static_cast<int64_t>(cell_start_s);
 			e.end_sample = static_cast<int64_t>(cell_end_s);
 			e.frame_type = IRF_FT_OVERFLOW;
 			e.mflags = DISPLAY_AS_ERROR_FLAG;
 			fill_err_snapshot(e);
 			std::strncpy(e.bubble_text, "OVF", sizeof e.bubble_text);
 			e.bubble_text[sizeof e.bubble_text - 1] = '\0';
 			on_bit(e);
 		}
 		is_buffer_overflow = true;
 	}
 	if (is_buffer_overflow || is_preamb || is_wrong_pack)
 	{
 		// Как IR_DecoderRaw::writeToBuffer: полный first_rx() вместо только сброса флагов приёма.
 		first_rx();
 		return;
 	}
 	if (buf_bit_pos == next_control_bit)
 	{
 		next_control_bit = next_control_bit + (is_data ? irfox::kSyncBits : irfox::kBitPerByte);
 		is_data = !is_data;
 		i_sync_bit = 0;
 		err_sync_bit = 0;
 	}
 	if (is_data)
 	{
 		const bool was_first_data_bit = (i_data_buffer == 0);
 		data_buffer[i_data_buffer / 8] |= static_cast<uint8_t>(bit ? 1 : 0) << (7 - (i_data_buffer % 8));
 		i_data_buffer++;
 		buf_bit_pos++;
 		uint8_t fl = 0;
 		if (pack_trace_invert_fix)
 			fl |= DISPLAY_AS_WARNING_FLAG;
 		if (on_bit && emit_mode == IrFoxEmitBitMode::WithBubble)
 		{
 			IrFoxEmitBit e{static_cast<int64_t>(cell_start_s), static_cast<int64_t>(cell_end_s), IRF_FT_DATA_BIT,
 						   bit ? 1u : 0u, static_cast<uint64_t>(i_data_buffer - 1), fl, pack_trace_invert_fix, 0, 0, 0};
 			fill_err_snapshot(e);
 			e.bubble_text[0] = static_cast<char>(bit ? '1' : '0');
 			e.bubble_text[1] = '\0';
 			on_bit(e);
 		}
 		if (was_first_data_bit && trim_first_data_bit_cell_)
 			trim_first_data_bit_cell_ = false;
 	}
 	else
 	{
 		if (i_sync_bit == 0)
 		{
 			const bool last_data_bit =
 				(data_buffer[((i_data_buffer - 1) / 8)] >> (7 - ((i_data_buffer - 1) % 8))) & 1;
 			if (bit != static_cast<bool>(last_data_bit))
 			{
 				buf_bit_pos++;
 				i_sync_bit++;
 				if (on_bit && emit_mode == IrFoxEmitBitMode::WithBubble)
 				{
 					IrFoxEmitBit e{static_cast<int64_t>(cell_start_s), static_cast<int64_t>(cell_end_s), IRF_FT_SYNC_BIT,
 								   bit ? 1u : 0u, static_cast<uint64_t>(buf_bit_pos), 0, false, 0, 0, 0};
 					fill_err_snapshot(e);
 					std::snprintf(e.bubble_text, sizeof e.bubble_text, "s: %c", bit ? '1' : '0');
 					on_bit(e);
 				}
 			}
 			else
 			{
 				i_sync_bit = 0;
 				err_other++;
 				err_sync_bit++;
 				const bool fatal_sync = (err_sync_bit >= irfox::kSyncBits);
 				if (fatal_sync)
 					is_wrong_pack = true;
 				if (on_bit && fatal_sync)
 				{
 					IrFoxEmitBit e{static_cast<int64_t>(cell_start_s), static_cast<int64_t>(cell_end_s), IRF_FT_ABORT,
 								   0, 0, DISPLAY_AS_ERROR_FLAG, false, 0, 0, 0};
 					fill_err_snapshot(e);
 					std::strncpy(e.bubble_text, "SYNC!", sizeof e.bubble_text);
 					e.bubble_text[sizeof e.bubble_text - 1] = '\0';
 					on_bit(e);
 				}
 			}
 		}
 		else
 		{
 			buf_bit_pos++;
 			i_sync_bit++;
 			if (on_bit && emit_mode == IrFoxEmitBitMode::WithBubble)
 			{
 				IrFoxEmitBit e{static_cast<int64_t>(cell_start_s), static_cast<int64_t>(cell_end_s), IRF_FT_SYNC_BIT,
 							   bit ? 1u : 0u, static_cast<uint64_t>(buf_bit_pos), 0, false, 0, 0, 0};
 				fill_err_snapshot(e);
 				std::snprintf(e.bubble_text, sizeof e.bubble_text, "s: %c", bit ? '1' : '0');
 				on_bit(e);
 			}
 		}
 		is_wrong_pack = (err_sync_bit >= irfox::kSyncBits);
 	}
 	if (!is_available && is_data && !is_wrong_pack)
 	{
 		if (i_data_buffer == 8 * irfox::kMsgBytes)
 			pack_size = static_cast<uint16_t>(data_buffer[0] & 0x1Fu);
 		if (pack_size && (i_data_buffer == 8))
 			msg_type_receive = static_cast<uint8_t>((data_buffer[0] >> 5) | 0xF8u);
 		if (pack_size && (i_data_buffer == pack_size * irfox::kBitPerByte))
 		{
 			uint16_t crc_computed = 0;
 			const bool crc_ok = crc_check(static_cast<uint8_t>(pack_size - irfox::kCrcBytes), crc_computed);
 			crc_value = crc_computed;
 			is_recive = false;
 			is_recive_raw = false;
 			msg_type_receive = 0;
 			is_available = crc_ok;
 			IrFoxEmitPacket pkt{};
 			pkt.start_sample = static_cast<int64_t>(cell_start_s);
 			pkt.end_sample = static_cast<int64_t>(cell_end_s);
 			pkt.crc_ok = crc_ok;
 			pkt.pack_size = static_cast<uint8_t>(pack_size);
 			pkt.err_low = err_low_signal;
 			pkt.err_high = err_high_signal;
 			pkt.err_other = err_other;
 			if (pack_size > 0 && pack_size <= irfox::kDataByteSizeMax)
 				std::memcpy(pkt.data_bytes, data_buffer, pack_size);
 			if (on_pkt)
 				on_pkt(pkt);
 		}
 	}
 }
 void IrFoxDecoder::processEdge(uint64_t sample, bool rising, uint32_t fs, const IrFoxOnBit& on_bit,
 							   const IrFoxOnPacket& on_pkt)
 {
 	const double t_us = sample_to_us(sample, fs);
 	const uint32_t irmax = irfox::irTimeoutUs(rise_sync_time_us);
 	uint32_t rise_min_us = rise_sync_time_us > irfox::kToleranceUs ? rise_sync_time_us - irfox::kToleranceUs : 0U;
 	listen_start(t_us);
 	// Как IR_DecoderRaw: пауза между фронтами по lastEdgeTime при активном приёме кадра.
 	if (last_edge_time_us > 0.0 && (t_us - last_edge_time_us) > irmax * 2.0 && is_recive)
 		check_timeout(t_us);
 	last_edge_time_us = t_us;
 	last_edge_sample = sample;
 	const uint32_t rise_max_us = rise_sync_time_us + irfox::kToleranceUs;
 	/** Визуализация: начало PRE с ближайшего спада в пределах ~3 битовых периодов (ИК-метка). */
 	auto new_bubble_preamble_start = [&](uint64_t edge_s, bool is_rising) -> uint64_t {
 		if (!is_rising)
 			return edge_s;
 		if (edge_s > prev_fall_sample)
 		{
 			const double span_us = double(edge_s - prev_fall_sample) * 1e6 / double(fs);
 			const double max_us = double(rise_max_us) * 3.0;
 			if (span_us <= max_us)
 				return prev_fall_sample;
 		}
 		return edge_s;
 	};
 	if (rising)
 	{
 		const double delta_rp = t_us - prev_rise_us;
 		const uint32_t cand_rp = static_cast<uint32_t>(delta_rp);
 		const uint32_t cand_ht = static_cast<uint32_t>(t_us - prev_fall_us);
 		const uint32_t cand_lt = static_cast<uint32_t>(prev_fall_us - prev_rise_us);
 #if IRFOX_SHORT_LOW_GLITCH_REJECT
 		const bool short_low_glitch =
 			is_recive && !is_preamb && cand_ht < (rise_min_us / 8U) && cand_lt >= rise_min_us &&
 			cand_rp >= rise_min_us && cand_rp <= irmax;
 		if (short_low_glitch)
 		{
 			err_other++;
 			irfox::irfoxGlitchPhaseNudgeUs(t_us, rise_sync_time_us, prev_rise_us);
 			last_processed_edge_us = t_us;
 			have_last_processed = true;
 			return;
 		}
 #endif
 #if IRFOX_MICRO_GAP_RISE_REJECT
 		const bool micro_gap_cand_lt_ok =
 			(cand_lt >= rise_min_us) || (cand_lt >= (rise_min_us / 4U) && cand_lt < rise_min_us);
 		const bool micro_gap_rise = is_recive && !is_preamb && cand_ht < (rise_min_us / 8U) && micro_gap_cand_lt_ok &&
 									cand_rp >= (rise_min_us / 4U) && cand_rp < rise_min_us && cand_rp <= irmax;
 		if (micro_gap_rise)
 		{
 			err_other++;
 			irfox::irfoxGlitchPhaseNudgeUs(t_us, rise_sync_time_us, prev_rise_us);
 			last_processed_edge_us = t_us;
 			have_last_processed = true;
 			return;
 		}
 #endif
 		if (cand_rp <= rise_max_us / 4U && !high_count && !low_count)
 		{
 			err_other++;
 			last_processed_edge_us = t_us;
 			have_last_processed = true;
 			return;
 		}
 		// Визуализация PRE: длинная пауза, первый подъём — якорь от спада метки (декод как STM32DMA).
 		if (cand_rp > irmax * 2U && !is_recive_raw)
 		{
 			preamble_bubble_start_sample_ = new_bubble_preamble_start(sample, true);
 			preamble_bubble_start_valid_ = true;
 		}
 		const bool accept_rise_timing =
 			(delta_rp > static_cast<double>(rise_max_us) / 4.0) || high_count != 0 || low_count != 0;
 		if (accept_rise_timing)
 		{
 			rise_period_anchor_sample_ = prev_rise_sample;
 			rise_period_us = cand_rp;
 			high_time_us = cand_ht;
 			low_time_us = cand_lt;
 			prev_rise_us = t_us;
 			prev_rise_sample = sample;
 		}
 		else
 		{
 			err_other++;
 		}
 	}
 	else
 	{
 		if (t_us - prev_fall_us > rise_min_us / 4.0)
 		{
 			prev_fall_us = t_us;
 			prev_fall_sample = sample;
 		}
 		else
 		{
 			err_other++;
 		}
 	}
 	// Как IR_DecoderRaw::tick: после длинной паузы старт сырого приёма (без отдельного firstRX — флаги ниже).
 	if (t_us > prev_rise_us && (t_us - prev_rise_us) > irmax * 2.0 && !is_recive_raw)
 	{
 		preamb_front_counter = static_cast<int8_t>(irfox::kPreambFronts - 1);
 		is_preamb = true;
 		is_recive = true;
 		is_recive_raw = true;
 		is_wrong_pack = false;
 		if (!preamble_bubble_start_valid_)
 		{
 			preamble_bubble_start_sample_ = new_bubble_preamble_start(sample, rising);
 			preamble_bubble_start_valid_ = true;
 		}
 	}
 	if (preamb_front_counter)
 	{
 		if (rising && rise_period_us < irmax)
 		{
 			if (rise_period_us < rise_min_us / 2U)
 			{
 				preamb_front_counter += 2;
 				err_other++;
 			}
 		}
 		preamb_front_counter--;
 	}
 	else
 	{
 		if (is_preamb)
 		{
 			is_preamb = false;
 			// IR_DecoderRaw: prevRise += risePeriod / 2 — фаза как в прошивке.
 			// Бабл PRE: до текущего фронта (sample−1), чтобы охватить все kPreambPulse периодов (3 импульса),
 			// а не только до предыдущего подъёма (~2 периода).
 			const uint64_t preamble_bubble_end_sample = sample > 0 ? sample - 1 : sample;
 			prev_rise_us += rise_period_us / 2.0;
 			{
 				const double half_us = 0.5 * static_cast<double>(rise_period_us);
 				const uint64_t half_s = static_cast<uint64_t>(std::llround(half_us * double(fs) / 1e6));
 				prev_rise_sample += half_s;
 			}
 			trim_first_data_bit_cell_ = true;
 			if (on_bit && preamble_bubble_start_valid_)
 			{
 				int64_t pe_start = static_cast<int64_t>(preamble_bubble_start_sample_);
 				int64_t pe_end = static_cast<int64_t>(preamble_bubble_end_sample);
 				if (preamble_bubble_end_sample == 0 || pe_end < pe_start)
 					pe_end = static_cast<int64_t>(sample > 0 ? sample - 1 : sample);
 				IrFoxEmitBit pe{};
 				pe.start_sample = pe_start;
 				pe.end_sample = pe_end;
 				pe.frame_type = IRF_FT_PREAMBLE;
 				fill_err_snapshot(pe);
 				std::strncpy(pe.bubble_text, "PRE", sizeof pe.bubble_text);
 				pe.bubble_text[sizeof pe.bubble_text - 1] = '\0';
 				on_bit(pe);
 			}
 			preamble_bubble_start_valid_ = false;
 			last_processed_edge_us = t_us;
 			have_last_processed = true;
 			return;
 		}
 	}
 	if (is_preamb)
 	{
 		last_processed_edge_us = t_us;
 		have_last_processed = true;
 		return;
 	}
 	if (rise_period_us > irmax || is_buffer_overflow || rise_period_us < rise_min_us || is_wrong_pack)
 	{
 		last_processed_edge_us = t_us;
 		have_last_processed = true;
 		return;
 	}
 	if (rising)
 	{
 		high_count = low_count = all_count = 0;
 		bool invert_err = false;
 		uint64_t cell_start_s = rise_period_anchor_sample_;
 		const uint64_t cell_end_s = sample > 0 ? sample - 1 : sample;
 		// После prev_rise += half period якорь может оказаться близко к текущему подъёму;
 		// max(anchor, prev_fall) > cell_end даёт пустой интервал — бабл первого бита пропадает.
 		if (trim_first_data_bit_cell_ && is_data && i_data_buffer == 0)
 		{
 			const uint64_t trimmed = std::max(cell_start_s, prev_fall_sample);
 			if (trimmed <= cell_end_s)
 				cell_start_s = trimmed;
 		}
 		if (irfox::aroundRisePeriod(rise_period_us, rise_sync_time_us))
 		{
 			if (high_time_us > low_time_us)
 				write_to_buffer(true, false, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::WithBubble);
 			else
 				write_to_buffer(false, false, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::WithBubble);
 		}
 		else
 		{
 			uint16_t hc = ceil_div_u16(static_cast<uint16_t>(high_time_us > 0xFFFF ? 0xFFFF : high_time_us),
 									   static_cast<uint16_t>(rise_sync_time_us));
 			uint16_t lc = ceil_div_u16(static_cast<uint16_t>(low_time_us > 0xFFFF ? 0xFFFF : low_time_us),
 									   static_cast<uint16_t>(rise_sync_time_us));
 			uint16_t ac = ceil_div_u16(static_cast<uint16_t>(rise_period_us > 0xFFFF ? 0xFFFF : rise_period_us),
 									   static_cast<uint16_t>(rise_sync_time_us));
 			high_count = static_cast<int8_t>(hc > 127 ? 127 : hc);
 			low_count = static_cast<int8_t>(lc > 127 ? 127 : lc);
 			all_count = static_cast<int8_t>(ac > 127 ? 127 : ac);
 			if (high_count == 0 && high_time_us > rise_sync_time_us / 3U)
 			{
 				high_count++;
 				err_other++;
 			}
 			if (low_count + high_count > all_count)
 			{
 				if (low_count > high_count)
 				{
 					low_count = static_cast<int8_t>(all_count - high_count);
 					err_low_signal = static_cast<uint8_t>(err_low_signal + static_cast<uint8_t>(low_count));
 				}
 				else if (low_count < high_count)
 				{
 					high_count = static_cast<int8_t>(all_count - low_count);
 					err_high_signal = static_cast<uint8_t>(err_high_signal + static_cast<uint8_t>(high_count));
 				}
 				else if (low_count == high_count)
 				{
 					invert_err = true;
 					err_other = static_cast<uint8_t>(err_other + static_cast<uint8_t>(all_count));
 				}
 			}
 			if (low_count < high_count)
 				err_high_signal = static_cast<uint8_t>(err_high_signal + static_cast<uint8_t>(high_count));
 			else
 				err_low_signal = static_cast<uint8_t>(err_low_signal + static_cast<uint8_t>(low_count));
 			const bool burst_is_data_start = is_data;
 			const uint64_t merge_bit_index =
 				burst_is_data_start ? static_cast<uint64_t>(i_data_buffer) : static_cast<uint64_t>(buf_bit_pos + 1);
 			char s_bits[20]{};
 			char d_bits[20]{};
 			size_t s_n = 0;
 			size_t d_n = 0;
 			int first_merge_bit = -1;
 			bool merge_warn = false;
 			auto append_merge = [&](bool as_data, bool bitv) {
 				if (first_merge_bit < 0)
 					first_merge_bit = bitv ? 1 : 0;
 				char* buf = as_data ? d_bits : s_bits;
 				size_t& n = as_data ? d_n : s_n;
 				if (n + 1 < sizeof s_bits)
 					buf[n++] = static_cast<char>(bitv ? '1' : '0');
 			};
 			auto emit_merge_if_needed = [&]() {
 				if ((s_n == 0 && d_n == 0) || !on_bit)
 					return;
 				IrFoxEmitBit e{};
 				e.start_sample = static_cast<int64_t>(cell_start_s);
 				e.end_sample = static_cast<int64_t>(cell_end_s);
 				e.frame_type = (d_n > 0) ? IRF_FT_DATA_BIT : IRF_FT_SYNC_BIT;
 				e.bit_value = (first_merge_bit > 0) ? 1u : 0u;
 				e.bit_index = merge_bit_index;
 				e.mflags = merge_warn ? DISPLAY_AS_WARNING_FLAG : 0;
 				e.invert_fix = merge_warn;
 				fill_err_snapshot(e);
 				s_bits[s_n] = '\0';
 				d_bits[d_n] = '\0';
 				if (s_n && d_n)
 					std::snprintf(e.bubble_text, sizeof e.bubble_text, "s: %s d: %s", s_bits, d_bits);
 				else if (s_n)
 					std::snprintf(e.bubble_text, sizeof e.bubble_text, "s: %s", s_bits);
 				else
 					std::memcpy(e.bubble_text, d_bits, d_n + 1);
 				on_bit(e);
 			};
 			for (int8_t i = 0; i < low_count && 8 - i; i++)
 			{
 				const bool row_is_data = is_data;
 				if (i == low_count - 1 && invert_err)
 				{
 					invert_err = false;
 					write_to_buffer(true, true, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::Quiet);
 					merge_warn = true;
 					append_merge(row_is_data, true);
 				}
 				else
 				{
 					write_to_buffer(false, false, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::Quiet);
 					append_merge(row_is_data, false);
 				}
 			}
 			for (int8_t i = 0; i < high_count && 8 - i; i++)
 			{
 				const bool row_is_data = is_data;
 				if (i == high_count - 1 && invert_err)
 				{
 					invert_err = false;
 					write_to_buffer(false, true, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::Quiet);
 					merge_warn = true;
 					append_merge(row_is_data, false);
 				}
 				else
 				{
 					write_to_buffer(true, false, cell_start_s, cell_end_s, on_bit, on_pkt, IrFoxEmitBitMode::Quiet);
 					append_merge(row_is_data, true);
 				}
 			}
 			emit_merge_if_needed();
 		}
 	}
 	last_processed_edge_us = t_us;
 	have_last_processed = true;
 }
 void IrFoxDecoder::flushEnd(uint64_t last_sample, uint32_t fs, const IrFoxOnBit& on_bit, const IrFoxOnPacket& on_pkt)
 {
 	const double t_us = sample_to_us(last_sample, fs);
 	listen_start(t_us);
 	check_timeout(t_us);
 	(void)on_bit;
 	(void)on_pkt;
 }
--- a/Analyzer/raw/IR_Fox/src/IrFoxDecoder.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxDecoder.h
@ -1,135 +0,0 @@
 #pragma once
 #include "IrFoxProtocolConstants.h"
 #include <cstdint>
 #include <functional>
 enum IrFoxFrameType : uint8_t
 {
 	IRF_FT_DATA_BIT = 1,
 	IRF_FT_SYNC_BIT = 2,
 	IRF_FT_PACKET_OK = 3,
 	IRF_FT_PACKET_CRC_FAIL = 4,
 	IRF_FT_OVERFLOW = 5,
 	IRF_FT_ABORT = 6,
 	IRF_FT_PREAMBLE = 7,
 };
 /** WithBubble — вызвать on_bit; Quiet — только обновить состояние (для пакета битов с одного фронта). */
 enum class IrFoxEmitBitMode : uint8_t
 {
 	WithBubble,
 	Quiet,
 };
 struct IrFoxEmitBit
 {
 	int64_t start_sample;
 	int64_t end_sample;
 	uint8_t frame_type;
 	uint64_t bit_value;
 	uint64_t bit_index;
 	uint8_t mflags;
 	bool invert_fix;
 	uint8_t err_low;
 	uint8_t err_high;
 	uint8_t err_other;
 	/** Подпись бабла: "0", "1" или склейка "001"; пусто — смотреть bit_value. */
 	char bubble_text[32]{};
 };
 struct IrFoxEmitPacket
 {
 	int64_t start_sample;
 	int64_t end_sample;
 	bool crc_ok;
 	uint8_t pack_size;
 	uint8_t err_low;
 	uint8_t err_high;
 	uint8_t err_other;
 	uint8_t data_bytes[irfox::kDataByteSizeMax];
 };
 using IrFoxOnBit = std::function<void(const IrFoxEmitBit&)>;
 using IrFoxOnPacket = std::function<void(const IrFoxEmitPacket&)>;
 class IrFoxDecoder
 {
 public:
 	void reset();
 	void processEdge(uint64_t sample, bool rising, uint32_t sample_rate_hz, const IrFoxOnBit& on_bit,
 					  const IrFoxOnPacket& on_pkt);
 	void flushEnd(uint64_t last_sample, uint32_t sample_rate_hz, const IrFoxOnBit& on_bit, const IrFoxOnPacket& on_pkt);
 private:
 	static uint16_t ceil_div_u16(uint16_t val, uint16_t divider);
 	static uint8_t crc8(const uint8_t* data, uint8_t start, uint8_t end, uint8_t poly);
 	bool crc_check(uint8_t len, uint16_t& crc_out);
 	void first_rx();
 	void listen_start(double t_us);
 	void check_timeout(double t_us);
 	void write_to_buffer(bool bit, bool pack_trace_invert_fix, uint64_t cell_start_s, uint64_t cell_end_s,
 						 const IrFoxOnBit& on_bit, const IrFoxOnPacket& on_pkt,
 						 IrFoxEmitBitMode emit_mode = IrFoxEmitBitMode::WithBubble);
 	double sample_to_us(uint64_t sample, uint32_t fs) const { return double(sample) * 1e6 / double(fs); }
 	// --- state (mirror IR_DecoderRaw) ---
 	uint8_t data_buffer[irfox::kDataByteSizeMax]{};
 	uint8_t err_low_signal = 0;
 	uint8_t err_high_signal = 0;
 	uint8_t err_other = 0;
 	bool is_available = false;
 	uint16_t pack_size = 0;
 	uint16_t crc_value = 0;
 	bool is_recive = false;
 	bool is_recive_raw = false;
 	bool is_preamb = false;
 	bool is_buffer_overflow = false;
 	bool is_wrong_pack = false;
 	uint32_t rise_sync_time_us = irfox::kBitTimeUs;
 	double prev_rise_us = 0;
 	double prev_fall_us = 0;
 	uint64_t prev_rise_sample = 0;
 	uint64_t prev_fall_sample = 0;
 	/** Сэмпл предыдущего нарастающего фронта до обновления на текущем тике (граница ячейки бита, см. IR_DecoderRaw::tick). */
 	uint64_t rise_period_anchor_sample_ = 0;
 	uint64_t preamble_bubble_start_sample_ = 0;
 	bool preamble_bubble_start_valid_ = false;
 	bool trim_first_data_bit_cell_ = false;
 	double last_edge_time_us = 0;
 	uint64_t last_edge_sample = 0;
 	double last_processed_edge_us = 0;
 	bool have_last_processed = false;
 	void fill_err_snapshot(IrFoxEmitBit& e) const
 	{
 		e.err_low = err_low_signal;
 		e.err_high = err_high_signal;
 		e.err_other = err_other;
 	}
 	uint32_t rise_period_us = 0;
 	uint32_t high_time_us = 0;
 	uint32_t low_time_us = 0;
 	int8_t high_count = 0;
 	int8_t low_count = 0;
 	int8_t all_count = 0;
 	uint16_t wrong_counter = 0;
 	int8_t preamb_front_counter = 0;
 	int16_t buf_bit_pos = 0;
 	bool is_data = true;
 	uint16_t i_data_buffer = 0;
 	uint16_t next_control_bit = irfox::kBitPerByte;
 	uint8_t i_sync_bit = 0;
 	uint8_t err_sync_bit = 0;
 	uint16_t error_counter = 0;
 	uint8_t msg_type_receive = 0;
 };
--- a/Analyzer/raw/IR_Fox/src/IrFoxProtocolConstants.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxProtocolConstants.h
@ -1,71 +0,0 @@
 #pragma once
 #include <cstdint>
 namespace irfox {
 constexpr uint32_t kCarrierPeriodUs = 1000000U / 38000U;
 constexpr uint32_t kBitActiveTakts = 25U;
 constexpr uint32_t kBitPauseTakts = 12U;
 constexpr uint32_t kBitTakts = kBitActiveTakts + kBitPauseTakts;
 constexpr uint32_t kBitTimeUs = kBitTakts * kCarrierPeriodUs;
 constexpr uint32_t kToleranceUs = 300U;
 /** Мин. длительность плато (мкс) для потокового анти-глитча в анализаторе; согласовано с IR_INPUT_MIN_PULSE_US. */
 constexpr uint32_t kMinFilteredPulseUs = 10U;
 constexpr uint8_t kBitPerByte = 8U;
 constexpr uint8_t kMsgBytes = 1;
 constexpr uint8_t kAddrBytes = 2;
 constexpr uint8_t kCrcBytes = 2;
 constexpr uint8_t kPoly1 = 0x31;
 constexpr uint8_t kPoly2 = 0x8C;
 constexpr uint8_t kSyncBits = 3U;
 constexpr uint8_t kBytePerPack = 31;
 constexpr uint8_t kDataByteSizeMax =
 	static_cast<uint8_t>(kMsgBytes + kAddrBytes + kAddrBytes + kBytePerPack + kCrcBytes);
 constexpr uint8_t kPreambPulse = 3;
 constexpr uint8_t kPreambFronts = kPreambPulse * 2U;
 /** Отброс ложного подъёма после микро-LOW в паузе; зеркало IR_config.h (прошивка). */
 #ifndef IRFOX_SHORT_LOW_GLITCH_REJECT
 #define IRFOX_SHORT_LOW_GLITCH_REJECT 1
 #endif
 #ifndef IRFOX_GLITCH_REJECT_PHASE_NUDGE
 #define IRFOX_GLITCH_REJECT_PHASE_NUDGE 1
 #endif
 #ifndef IRFOX_MICRO_GAP_RISE_REJECT
 #define IRFOX_MICRO_GAP_RISE_REJECT 1
 #endif
 inline uint32_t irTimeoutUs(uint32_t riseSyncTimeUs)
 {
 	const uint32_t riseMax = riseSyncTimeUs + kToleranceUs;
 	return riseMax * (8U + kSyncBits + 1U);
 }
 /** Как IR_DecoderRaw.h: aroundRise(t) → riseTimeMin < t && t < riseTimeMax (ветка STM32DMA). */
 inline bool aroundRisePeriod(uint32_t periodUs, uint32_t riseSyncTimeUs)
 {
 	const uint32_t lo = riseSyncTimeUs > kToleranceUs ? riseSyncTimeUs - kToleranceUs : 0U;
 	const uint32_t hi = riseSyncTimeUs + kToleranceUs;
 	return lo < periodUs && periodUs < hi;
 }
 inline void irfoxGlitchPhaseNudgeUs(double edge_us, uint32_t rise_sync_us, double& prev_rise_us)
 {
 #if IRFOX_GLITCH_REJECT_PHASE_NUDGE
 	if (!(edge_us > static_cast<double>(rise_sync_us)))
 		return;
 	const double nudged = edge_us - static_cast<double>(rise_sync_us);
 	if (nudged > prev_rise_us && nudged < edge_us)
 		prev_rise_us = nudged;
 #else
 	(void)edge_us;
 	(void)rise_sync_us;
 	(void)prev_rise_us;
 #endif
 }
 } // namespace irfox
--- a/Analyzer/raw/IR_Fox/src/IrFoxSimulationDataGenerator.cpp
+++ b/Analyzer/raw/IR_Fox/src/IrFoxSimulationDataGenerator.cpp
@ -1,67 +0,0 @@
 #include "IrFoxSimulationDataGenerator.h"
 #include "IrFoxAnalyzerSettings.h"
 #include <AnalyzerHelpers.h>
 IrFoxSimulationDataGenerator::IrFoxSimulationDataGenerator()
 {
 }
 IrFoxSimulationDataGenerator::~IrFoxSimulationDataGenerator()
 {
 }
 void IrFoxSimulationDataGenerator::Initialize(U32 simulation_sample_rate, IrFoxAnalyzerSettings* settings)
 {
 	mSimulationSampleRateHz = simulation_sample_rate;
 	mSettings = settings;
 	mIrSimulationData.SetChannel(mSettings->mInputChannel);
 	mIrSimulationData.SetSampleRate(simulation_sample_rate);
 	// Как у «покоя» на выходе TSOP: линия подтянута вверх
 	mIrSimulationData.SetInitialBitState(BIT_HIGH);
 }
 void IrFoxSimulationDataGenerator::EmitIdle(U32 samples)
 {
 	mIrSimulationData.Advance(samples);
 }
 void IrFoxSimulationDataGenerator::EmitLow(U32 samples)
 {
 	mIrSimulationData.TransitionIfNeeded(BIT_LOW);
 	mIrSimulationData.Advance(samples);
 }
 void IrFoxSimulationDataGenerator::EmitHigh(U32 samples)
 {
 	mIrSimulationData.TransitionIfNeeded(BIT_HIGH);
 	mIrSimulationData.Advance(samples);
 }
 U32 IrFoxSimulationDataGenerator::GenerateSimulationData(U64 largest_sample_requested, U32 sample_rate,
 														   SimulationChannelDescriptor** simulation_channel)
 {
 	const U64 adjusted_largest_sample_requested =
 		AnalyzerHelpers::AdjustSimulationTargetSample(largest_sample_requested, sample_rate, mSimulationSampleRateHz);
 	// Упрощённый «пакет»: несколько импульсов вниз (активный уровень приёмника).
 	while (mIrSimulationData.GetCurrentSampleNumber() < adjusted_largest_sample_requested)
 	{
 		const U32 us_to_samples = mSimulationSampleRateHz / 1000000;
 		if (us_to_samples == 0)
 			break;
 		EmitIdle(500 * us_to_samples);
 		EmitLow(4500 * us_to_samples);
 		EmitHigh(4500 * us_to_samples);
 		EmitLow(4500 * us_to_samples);
 		EmitHigh(4500 * us_to_samples);
 		EmitLow(560 * us_to_samples);
 		EmitHigh(560 * us_to_samples);
 		EmitLow(560 * us_to_samples);
 		EmitHigh(20000 * us_to_samples);
 	}
 	*simulation_channel = &mIrSimulationData;
 	return 1;
 }
--- a/Analyzer/raw/IR_Fox/src/IrFoxSimulationDataGenerator.h
+++ b/Analyzer/raw/IR_Fox/src/IrFoxSimulationDataGenerator.h
@ -1,27 +0,0 @@
 #ifndef IRFOX_SIMULATION_DATA_GENERATOR
 #define IRFOX_SIMULATION_DATA_GENERATOR
 #include <SimulationChannelDescriptor.h>
 class IrFoxAnalyzerSettings;
 class IrFoxSimulationDataGenerator
 {
 public:
 	IrFoxSimulationDataGenerator();
 	~IrFoxSimulationDataGenerator();
 	void Initialize(U32 simulation_sample_rate, IrFoxAnalyzerSettings* settings);
 	U32 GenerateSimulationData(U64 newest_sample_requested, U32 sample_rate, SimulationChannelDescriptor** simulation_channel);
 protected:
 	IrFoxAnalyzerSettings* mSettings;
 	U32 mSimulationSampleRateHz;
 	SimulationChannelDescriptor mIrSimulationData;
 	void EmitIdle(U32 samples);
 	void EmitLow(U32 samples);
 	void EmitHigh(U32 samples);
 };
 #endif
--- a/Analyzer/raw/PulseLengthStat/.github/workflows/build.yml
+++ b/Analyzer/raw/PulseLengthStat/.github/workflows/build.yml
@ -1,52 +0,0 @@
 name: Build
 on:
  push:
    branches: [master, main]
    tags:
      - "*"
  pull_request:
    branches: [master, main]
 jobs:
  windows:
    runs-on: windows-latest
    steps:
      - uses: actions/checkout@v4
      - name: Build
        run: |
          cmake -B ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build -S ${{github.workspace}}/Analyzer/raw/PulseLengthStat -A x64
          cmake --build ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build --config Release
      - uses: actions/upload-artifact@v4
        with:
          name: windows
          path: ${{github.workspace}}/Analyzer/raw/dll/*.dll
  macos:
    runs-on: macos-latest
    steps:
      - uses: actions/checkout@v4
      - name: Build
        run: |
          cmake -B ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build -S ${{github.workspace}}/Analyzer/raw/PulseLengthStat -DCMAKE_BUILD_TYPE=Release
          cmake --build ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build
      - uses: actions/upload-artifact@v4
        with:
          name: macos
          path: ${{github.workspace}}/Analyzer/raw/dll/*.so
  linux:
    runs-on: ubuntu-latest
    steps:
      - uses: actions/checkout@v4
      - name: Build
        run: |
          cmake -B ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build -S ${{github.workspace}}/Analyzer/raw/PulseLengthStat -DCMAKE_BUILD_TYPE=Release
          cmake --build ${{github.workspace}}/Analyzer/raw/PulseLengthStat/build
        env:
          CC: gcc-10
          CXX: g++-10
      - uses: actions/upload-artifact@v4
        with:
          name: linux
          path: ${{github.workspace}}/Analyzer/raw/dll/*.so
--- a/Analyzer/raw/PulseLengthStat/.gitignore
+++ b/Analyzer/raw/PulseLengthStat/.gitignore
@ -1,3 +0,0 @@
 /build
 /build-nmake
 .DS_Store
--- a/Analyzer/raw/PulseLengthStat/CMakeLists.txt
+++ b/Analyzer/raw/PulseLengthStat/CMakeLists.txt
@ -1,24 +0,0 @@
 cmake_minimum_required(VERSION 3.13)
 project(PulseLengthStatAnalyzer)
 add_definitions(-DLOGIC2)
 set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
 set(CMAKE_MODULE_PATH ${PROJECT_SOURCE_DIR}/cmake)
 include(ExternalAnalyzerSDK)
 set(SOURCES
 	src/PulseLengthStatAnalyzer.cpp
 	src/PulseLengthStatAnalyzer.h
 	src/PulseLengthStatAnalyzerResults.cpp
 	src/PulseLengthStatAnalyzerResults.h
 	src/PulseLengthStatAnalyzerSettings.cpp
 	src/PulseLengthStatAnalyzerSettings.h
 	src/PulseLengthStatSimulationDataGenerator.cpp
 	src/PulseLengthStatSimulationDataGenerator.h
 )
 add_analyzer_plugin(${PROJECT_NAME} SOURCES ${SOURCES})
--- a/Analyzer/raw/PulseLengthStat/CMakePresets.json
+++ b/Analyzer/raw/PulseLengthStat/CMakePresets.json
@ -1,49 +0,0 @@
 {
  "version": 3,
  "cmakeMinimumRequired": {
    "major": 3,
    "minor": 19,
    "patch": 0
  },
  "configurePresets": [
    {
      "name": "win-vs2022-x64",
      "displayName": "Visual Studio 2022 (x64)",
      "generator": "Visual Studio 17 2022",
      "architecture": "x64",
      "binaryDir": "${sourceDir}/build"
    },
    {
      "name": "win-vs2019-x64",
      "displayName": "Visual Studio 2019 (x64)",
      "generator": "Visual Studio 16 2019",
      "architecture": "x64",
      "binaryDir": "${sourceDir}/build"
    },
    {
      "name": "win-nmake-release",
      "displayName": "NMake Release (x64 Native Tools Command Prompt)",
      "generator": "NMake Makefiles",
      "binaryDir": "${sourceDir}/build-nmake",
      "cacheVariables": {
        "CMAKE_BUILD_TYPE": "Release"
      }
    }
  ],
  "buildPresets": [
    {
      "name": "win-release",
      "configurePreset": "win-vs2022-x64",
      "configuration": "Release"
    },
    {
      "name": "win-release-vs2019",
      "configurePreset": "win-vs2019-x64",
      "configuration": "Release"
    },
    {
      "name": "nmake-release",
      "configurePreset": "win-nmake-release"
    }
  ]
 }
--- a/Analyzer/raw/PulseLengthStat/build_msvc.bat
+++ b/Analyzer/raw/PulseLengthStat/build_msvc.bat
@ -1,21 +0,0 @@
@echo off
 setlocal EnableDelayedExpansion
 cd /d "%~dp0"
 if not exist build\CMakeCache.txt (
  echo Run configure_msvc.bat first.
  exit /b 1
 )
 set "VSWHERE=%ProgramFiles(x86)%\Microsoft Visual Studio\Installer\vswhere.exe"
 for /f "usebackq tokens=*" %%i in (`"%VSWHERE%" -latest -products * -requires Microsoft.VisualStudio.Component.VC.Tools.x86.x64 -property installationPath`) do set "VSINSTALL=%%i"
 if not defined VSINSTALL (
  echo MSVC not found. Add C++ workload in Visual Studio Installer.
  exit /b 1
 )
 call "!VSINSTALL!\Common7\Tools\VsDevCmd.bat" -arch=x64 -host_arch=x64
 if errorlevel 1 exit /b 1
 cmake --build build
 pause
 exit /b %ERRORLEVEL%
--- a/Analyzer/raw/PulseLengthStat/cmake/ExternalAnalyzerSDK.cmake
+++ b/Analyzer/raw/PulseLengthStat/cmake/ExternalAnalyzerSDK.cmake
@ -1,66 +0,0 @@
 include(FetchContent)
 set(CMAKE_CXX_STANDARD 11)
 set(CMAKE_CXX_STANDARD_REQUIRED YES)
 if(NOT CMAKE_RUNTIME_OUTPUT_DIRECTORY OR NOT CMAKE_LIBRARY_OUTPUT_DIRECTORY)
 	set(CMAKE_RUNTIME_OUTPUT_DIRECTORY ${PROJECT_BINARY_DIR}/bin/)
 	set(CMAKE_LIBRARY_OUTPUT_DIRECTORY ${PROJECT_BINARY_DIR}/bin/)
 endif()
 if(NOT TARGET Saleae::AnalyzerSDK)
 	FetchContent_Declare(
 		analyzersdk
 		GIT_REPOSITORY https://github.com/saleae/AnalyzerSDK.git
 		GIT_TAG master
 		GIT_SHALLOW True
 		GIT_PROGRESS True
 	)
 	FetchContent_GetProperties(analyzersdk)
 	if(NOT analyzersdk_POPULATED)
 		FetchContent_Populate(analyzersdk)
 		include(${analyzersdk_SOURCE_DIR}/AnalyzerSDKConfig.cmake)
 		if(APPLE OR WIN32)
 			get_target_property(analyzersdk_lib_location Saleae::AnalyzerSDK IMPORTED_LOCATION)
 			if(CMAKE_LIBRARY_OUTPUT_DIRECTORY)
 				file(COPY ${analyzersdk_lib_location} DESTINATION ${CMAKE_LIBRARY_OUTPUT_DIRECTORY})
 			else()
 				message(WARNING "Please define CMAKE_RUNTIME_OUTPUT_DIRECTORY and CMAKE_LIBRARY_OUTPUT_DIRECTORY if you want unit tests to locate ${analyzersdk_lib_location}")
 			endif()
 		endif()
 	endif()
 endif()
 # Shared folder for all Saleae LLA plugins in this repo: Analyzer/raw/dll
 set(ANALYZER_DLL_OUT_DIR "${CMAKE_SOURCE_DIR}/../dll")
 get_filename_component(ANALYZER_DLL_OUT_DIR "${ANALYZER_DLL_OUT_DIR}" ABSOLUTE)
 file(MAKE_DIRECTORY "${ANALYZER_DLL_OUT_DIR}")
 function(add_analyzer_plugin TARGET)
 	set(options)
 	set(single_value_args)
 	set(multi_value_args SOURCES)
 	cmake_parse_arguments(_p "${options}" "${single_value_args}" "${multi_value_args}" ${ARGN})
 	add_library(${TARGET} MODULE ${_p_SOURCES})
 	target_link_libraries(${TARGET} PRIVATE Saleae::AnalyzerSDK)
 	set(ANALYZER_DESTINATION "Analyzers")
 	install(TARGETS ${TARGET} RUNTIME DESTINATION ${ANALYZER_DESTINATION}
 		LIBRARY DESTINATION ${ANALYZER_DESTINATION})
 	set_target_properties(${TARGET} PROPERTIES
 		RUNTIME_OUTPUT_DIRECTORY "${ANALYZER_DLL_OUT_DIR}"
 		LIBRARY_OUTPUT_DIRECTORY "${ANALYZER_DLL_OUT_DIR}")
 	if(CMAKE_CONFIGURATION_TYPES)
 		foreach(CFG ${CMAKE_CONFIGURATION_TYPES})
 			string(TOUPPER ${CFG} CFG_UPPER)
 			set_target_properties(${TARGET} PROPERTIES
 				RUNTIME_OUTPUT_DIRECTORY_${CFG_UPPER} "${ANALYZER_DLL_OUT_DIR}"
 				LIBRARY_OUTPUT_DIRECTORY_${CFG_UPPER} "${ANALYZER_DLL_OUT_DIR}")
 		endforeach()
 	endif()
 endfunction()
--- a/Analyzer/raw/PulseLengthStat/configure_msvc.bat
+++ b/Analyzer/raw/PulseLengthStat/configure_msvc.bat
@ -1,39 +0,0 @@
@echo off
 setlocal EnableDelayedExpansion
 cd /d "%~dp0"
 echo === PulseLengthStatAnalyzer: configure with MSVC ===
 echo.
 set "VSWHERE=%ProgramFiles(x86)%\Microsoft Visual Studio\Installer\vswhere.exe"
 if not exist "%VSWHERE%" (
  echo [ERROR] vswhere not found. Install one of:
  echo   - Visual Studio 2022 with workload "Desktop development with C++"
  echo   - Build Tools for Visual Studio 2022: https://visualstudio.microsoft.com/visual-cpp-build-tools/
  echo     ^(select "Desktop development with C++" / MSVC, Windows SDK^)
  exit /b 1
 )
 for /f "usebackq tokens=*" %%i in (`"%VSWHERE%" -latest -products * -requires Microsoft.VisualStudio.Component.VC.Tools.x86.x64 -property installationPath`) do set "VSINSTALL=%%i"
 if not defined VSINSTALL (
  echo [ERROR] MSVC toolset not found. Add "Desktop development with C++" in Visual Studio Installer.
  exit /b 1
 )
 echo Found: !VSINSTALL!
 call "!VSINSTALL!\Common7\Tools\VsDevCmd.bat" -arch=x64 -host_arch=x64
 if errorlevel 1 exit /b 1
 if exist build rmdir /s /q build
 if exist build-nmake rmdir /s /q build-nmake
 mkdir build
 cd build
 cmake .. -G "NMake Makefiles" -DCMAKE_BUILD_TYPE=Release
 if errorlevel 1 exit /b 1
 echo.
 echo Configure OK. Build: build_msvc.bat ^(or from same VS env: cd build ^& cmake --build .^)
 echo Output DLL: ..\dll\ ^(all analyzers share this folder^)
 pause
 exit /b 0
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzer.cpp
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzer.cpp
@ -1,110 +0,0 @@
 #include "PulseLengthStatAnalyzer.h"
 #include "PulseLengthStatAnalyzerSettings.h"
 #include <AnalyzerChannelData.h>
 // One frame per stable level between edges. mData1 = duration in samples; mFlags: 1 = HIGH, 0 = LOW.
 PulseLengthStatAnalyzer::PulseLengthStatAnalyzer()
 	: Analyzer2(),
 	  mSettings(),
 	  mSimulationInitilized(false)
 {
 	SetAnalyzerSettings(&mSettings);
 }
 PulseLengthStatAnalyzer::~PulseLengthStatAnalyzer()
 {
 	KillThread();
 }
 void PulseLengthStatAnalyzer::SetupResults()
 {
 	mResults.reset(new PulseLengthStatAnalyzerResults(this, &mSettings));
 	SetAnalyzerResults(mResults.get());
 	mResults->AddChannelBubblesWillAppearOn(mSettings.mInputChannel);
 }
 void PulseLengthStatAnalyzer::WorkerThread()
 {
 	mChannelData = GetAnalyzerChannelData(mSettings.mInputChannel);
 	U32 frames_since_commit = 0;
 	const U32 kCommitBatch = 256;
 	for (;;)
 	{
 		CheckIfThreadShouldExit();
 		const U64 segment_start = mChannelData->GetSampleNumber();
 		const BitState level = mChannelData->GetBitState();
 		mChannelData->AdvanceToNextEdge();
 		const U64 edge_sample = mChannelData->GetSampleNumber();
 		if (edge_sample == segment_start)
 			break;
 		const U64 duration_samples = edge_sample - segment_start;
 		const U64 end_inclusive = edge_sample > segment_start ? edge_sample - 1 : segment_start;
 		Frame frame;
 		frame.mData1 = duration_samples;
 		frame.mFlags = (level == BIT_HIGH) ? 1 : 0;
 		frame.mStartingSampleInclusive = static_cast<S64>(segment_start);
 		frame.mEndingSampleInclusive = static_cast<S64>(end_inclusive);
 		mResults->AddFrame(frame);
 		if (++frames_since_commit >= kCommitBatch)
 		{
 			mResults->CommitResults();
 			frames_since_commit = 0;
 		}
 		ReportProgress(edge_sample);
 	}
 	if (frames_since_commit != 0)
 		mResults->CommitResults();
 }
 bool PulseLengthStatAnalyzer::NeedsRerun()
 {
 	return false;
 }
 U32 PulseLengthStatAnalyzer::GenerateSimulationData(U64 minimum_sample_index, U32 device_sample_rate,
 													SimulationChannelDescriptor** simulation_channels)
 {
 	if (mSimulationInitilized == false)
 	{
 		mSimulationDataGenerator.Initialize(GetSimulationSampleRate(), &mSettings);
 		mSimulationInitilized = true;
 	}
 	return mSimulationDataGenerator.GenerateSimulationData(minimum_sample_index, device_sample_rate,
 															simulation_channels);
 }
 U32 PulseLengthStatAnalyzer::GetMinimumSampleRateHz()
 {
 	return 200000;
 }
 const char* PulseLengthStatAnalyzer::GetAnalyzerName() const
 {
 	return "Pulse Length Stat";
 }
 const char* GetAnalyzerName()
 {
 	return "Pulse Length Stat";
 }
 Analyzer* CreateAnalyzer()
 {
 	return new PulseLengthStatAnalyzer();
 }
 void DestroyAnalyzer(Analyzer* analyzer)
 {
 	delete analyzer;
 }
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzer.h
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzer.h
@ -1,39 +0,0 @@
 #ifndef PULSELENGTHSTAT_ANALYZER_H
 #define PULSELENGTHSTAT_ANALYZER_H
 #include <Analyzer.h>
 #include "PulseLengthStatAnalyzerSettings.h"
 #include "PulseLengthStatAnalyzerResults.h"
 #include "PulseLengthStatSimulationDataGenerator.h"
 #include <memory>
 class ANALYZER_EXPORT PulseLengthStatAnalyzer : public Analyzer2
 {
 public:
 	PulseLengthStatAnalyzer();
 	virtual ~PulseLengthStatAnalyzer();
 	virtual void SetupResults();
 	virtual void WorkerThread();
 	virtual U32 GenerateSimulationData(U64 newest_sample_requested, U32 sample_rate,
 									 SimulationChannelDescriptor** simulation_channels);
 	virtual U32 GetMinimumSampleRateHz();
 	virtual const char* GetAnalyzerName() const;
 	virtual bool NeedsRerun();
 protected:
 	PulseLengthStatAnalyzerSettings mSettings;
 	std::unique_ptr<PulseLengthStatAnalyzerResults> mResults;
 	AnalyzerChannelData* mChannelData;
 	PulseLengthStatSimulationDataGenerator mSimulationDataGenerator;
 	bool mSimulationInitilized;
 };
 extern "C" ANALYZER_EXPORT const char* __cdecl GetAnalyzerName();
 extern "C" ANALYZER_EXPORT Analyzer* __cdecl CreateAnalyzer();
 extern "C" ANALYZER_EXPORT void __cdecl DestroyAnalyzer(Analyzer* analyzer);
 #endif
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerResults.cpp
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerResults.cpp
@ -1,107 +0,0 @@
 #include "PulseLengthStatAnalyzerResults.h"
 #include <AnalyzerHelpers.h>
 #include "PulseLengthStatAnalyzer.h"
 #include "PulseLengthStatAnalyzerSettings.h"
 #include <cstdio>
 #include <fstream>
 PulseLengthStatAnalyzerResults::PulseLengthStatAnalyzerResults(PulseLengthStatAnalyzer* analyzer,
 															   PulseLengthStatAnalyzerSettings* settings)
 	: AnalyzerResults(),
 	  mSettings(settings),
 	  mAnalyzer(analyzer)
 {
 }
 PulseLengthStatAnalyzerResults::~PulseLengthStatAnalyzerResults()
 {
 }
 static void FormatDurationUs(U64 duration_samples, U32 sample_rate_hz, char* out, size_t out_sz)
 {
 	if (sample_rate_hz == 0)
 	{
 		snprintf(out, out_sz, "? us");
 		return;
 	}
 	const double us = double(duration_samples) * 1e6 / double(sample_rate_hz);
 	snprintf(out, out_sz, "%.2f us", us);
 }
 void PulseLengthStatAnalyzerResults::GenerateBubbleText(U64 frame_index, Channel& channel, DisplayBase display_base)
 {
 	(void)display_base;
 	ClearResultStrings();
 	Frame frame = GetFrame(frame_index);
 	const U32 fs = mAnalyzer->GetSampleRate();
 	char dur[64];
 	FormatDurationUs(frame.mData1, fs, dur, sizeof dur);
 	const char* lev = (frame.mFlags != 0) ? "HIGH" : "LOW";
 	char line[160];
 	snprintf(line, sizeof line, "%s %s", lev, dur);
 	AddResultString(line);
 }
 void PulseLengthStatAnalyzerResults::GenerateExportFile(const char* file, DisplayBase display_base, U32 export_type_user_id)
 {
 	(void)export_type_user_id;
 	(void)display_base;
 	std::ofstream file_stream(file, std::ios::out);
 	const U64 trigger_sample = mAnalyzer->GetTriggerSample();
 	const U32 sample_rate = mAnalyzer->GetSampleRate();
 	file_stream << "Time [s],Level,Duration_samples,Duration_us" << std::endl;
 	const U64 num_frames = GetNumFrames();
 	for (U32 i = 0; i < num_frames; i++)
 	{
 		Frame frame = GetFrame(i);
 		char time_str[128];
 		AnalyzerHelpers::GetTimeString(frame.mStartingSampleInclusive, trigger_sample, sample_rate, time_str, 128);
 		char dur_us[64];
 		FormatDurationUs(frame.mData1, sample_rate, dur_us, sizeof dur_us);
 		file_stream << time_str << "," << ((frame.mFlags != 0) ? "HIGH" : "LOW") << "," << frame.mData1 << ","
 					<< dur_us << std::endl;
 		if (UpdateExportProgressAndCheckForCancel(i, num_frames) == true)
 		{
 			file_stream.close();
 			return;
 		}
 	}
 	file_stream.close();
 }
 void PulseLengthStatAnalyzerResults::GenerateFrameTabularText(U64 frame_index, DisplayBase display_base)
 {
 #ifdef SUPPORTS_PROTOCOL_SEARCH
 	(void)display_base;
 	Frame frame = GetFrame(frame_index);
 	ClearTabularText();
 	const U32 fs = mAnalyzer->GetSampleRate();
 	char dur[64];
 	FormatDurationUs(frame.mData1, fs, dur, sizeof dur);
 	AddTabularText((frame.mFlags != 0) ? "H" : "L");
 	AddTabularText(dur);
 #endif
 }
 void PulseLengthStatAnalyzerResults::GeneratePacketTabularText(U64 packet_id, DisplayBase display_base)
 {
 	(void)packet_id;
 	(void)display_base;
 }
 void PulseLengthStatAnalyzerResults::GenerateTransactionTabularText(U64 transaction_id, DisplayBase display_base)
 {
 	(void)transaction_id;
 	(void)display_base;
 }
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerResults.h
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerResults.h
@ -1,27 +0,0 @@
 #ifndef PULSELENGTHSTAT_ANALYZER_RESULTS
 #define PULSELENGTHSTAT_ANALYZER_RESULTS
 #include <AnalyzerResults.h>
 class PulseLengthStatAnalyzer;
 class PulseLengthStatAnalyzerSettings;
 class PulseLengthStatAnalyzerResults : public AnalyzerResults
 {
 public:
 	PulseLengthStatAnalyzerResults(PulseLengthStatAnalyzer* analyzer, PulseLengthStatAnalyzerSettings* settings);
 	virtual ~PulseLengthStatAnalyzerResults();
 	virtual void GenerateBubbleText(U64 frame_index, Channel& channel, DisplayBase display_base);
 	virtual void GenerateExportFile(const char* file, DisplayBase display_base, U32 export_type_user_id);
 	virtual void GenerateFrameTabularText(U64 frame_index, DisplayBase display_base);
 	virtual void GeneratePacketTabularText(U64 packet_id, DisplayBase display_base);
 	virtual void GenerateTransactionTabularText(U64 transaction_id, DisplayBase display_base);
 protected:
 	PulseLengthStatAnalyzerSettings* mSettings;
 	PulseLengthStatAnalyzer* mAnalyzer;
 };
 #endif
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerSettings.cpp
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerSettings.cpp
@ -1,62 +0,0 @@
 #include "PulseLengthStatAnalyzerSettings.h"
 #include <AnalyzerHelpers.h>
 PulseLengthStatAnalyzerSettings::PulseLengthStatAnalyzerSettings()
 	: mInputChannel(UNDEFINED_CHANNEL),
 	  mInputChannelInterface()
 {
 	mInputChannelInterface.SetTitleAndTooltip(
 		"Input",
 		"Digital channel: one frame per stable level between edges (duration in samples / us).");
 	mInputChannelInterface.SetChannel(mInputChannel);
 	AddInterface(&mInputChannelInterface);
 	AddExportOption(0, "Export as text/csv file");
 	AddExportExtension(0, "text", "txt");
 	AddExportExtension(0, "csv", "csv");
 	ClearChannels();
 	AddChannel(mInputChannel, "Input", false);
 }
 PulseLengthStatAnalyzerSettings::~PulseLengthStatAnalyzerSettings()
 {
 }
 bool PulseLengthStatAnalyzerSettings::SetSettingsFromInterfaces()
 {
 	mInputChannel = mInputChannelInterface.GetChannel();
 	ClearChannels();
 	AddChannel(mInputChannel, "Pulse Length Stat", true);
 	return true;
 }
 void PulseLengthStatAnalyzerSettings::UpdateInterfacesFromSettings()
 {
 	mInputChannelInterface.SetChannel(mInputChannel);
 }
 void PulseLengthStatAnalyzerSettings::LoadSettings(const char* settings)
 {
 	SimpleArchive text_archive;
 	text_archive.SetString(settings);
 	text_archive >> mInputChannel;
 	ClearChannels();
 	AddChannel(mInputChannel, "Pulse Length Stat", true);
 	UpdateInterfacesFromSettings();
 }
 const char* PulseLengthStatAnalyzerSettings::SaveSettings()
 {
 	SimpleArchive text_archive;
 	text_archive << mInputChannel;
 	return SetReturnString(text_archive.GetString());
 }
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerSettings.h
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatAnalyzerSettings.h
@ -1,24 +0,0 @@
 #ifndef PULSELENGTHSTAT_ANALYZER_SETTINGS
 #define PULSELENGTHSTAT_ANALYZER_SETTINGS
 #include <AnalyzerSettings.h>
 #include <AnalyzerTypes.h>
 class PulseLengthStatAnalyzerSettings : public AnalyzerSettings
 {
 public:
 	PulseLengthStatAnalyzerSettings();
 	virtual ~PulseLengthStatAnalyzerSettings();
 	virtual bool SetSettingsFromInterfaces();
 	void UpdateInterfacesFromSettings();
 	virtual void LoadSettings(const char* settings);
 	virtual const char* SaveSettings();
 	Channel mInputChannel;
 protected:
 	AnalyzerSettingInterfaceChannel mInputChannelInterface;
 };
 #endif
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatSimulationDataGenerator.cpp
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatSimulationDataGenerator.cpp
@ -1,65 +0,0 @@
 #include "PulseLengthStatSimulationDataGenerator.h"
 #include "PulseLengthStatAnalyzerSettings.h"
 #include <AnalyzerHelpers.h>
 PulseLengthStatSimulationDataGenerator::PulseLengthStatSimulationDataGenerator()
 {
 }
 PulseLengthStatSimulationDataGenerator::~PulseLengthStatSimulationDataGenerator()
 {
 }
 void PulseLengthStatSimulationDataGenerator::Initialize(U32 simulation_sample_rate, PulseLengthStatAnalyzerSettings* settings)
 {
 	mSimulationSampleRateHz = simulation_sample_rate;
 	mSettings = settings;
 	mSimChannel.SetChannel(mSettings->mInputChannel);
 	mSimChannel.SetSampleRate(simulation_sample_rate);
 	mSimChannel.SetInitialBitState(BIT_HIGH);
 }
 void PulseLengthStatSimulationDataGenerator::EmitIdle(U32 samples)
 {
 	mSimChannel.Advance(samples);
 }
 void PulseLengthStatSimulationDataGenerator::EmitLow(U32 samples)
 {
 	mSimChannel.TransitionIfNeeded(BIT_LOW);
 	mSimChannel.Advance(samples);
 }
 void PulseLengthStatSimulationDataGenerator::EmitHigh(U32 samples)
 {
 	mSimChannel.TransitionIfNeeded(BIT_HIGH);
 	mSimChannel.Advance(samples);
 }
 U32 PulseLengthStatSimulationDataGenerator::GenerateSimulationData(U64 largest_sample_requested, U32 sample_rate,
 																   SimulationChannelDescriptor** simulation_channel)
 {
 	const U64 adjusted_largest_sample_requested =
 		AnalyzerHelpers::AdjustSimulationTargetSample(largest_sample_requested, sample_rate, mSimulationSampleRateHz);
 	while (mSimChannel.GetCurrentSampleNumber() < adjusted_largest_sample_requested)
 	{
 		const U32 us_to_samples = mSimulationSampleRateHz / 1000000;
 		if (us_to_samples == 0)
 			break;
 		EmitIdle(500 * us_to_samples);
 		EmitLow(4500 * us_to_samples);
 		EmitHigh(4500 * us_to_samples);
 		EmitLow(4500 * us_to_samples);
 		EmitHigh(4500 * us_to_samples);
 		EmitLow(560 * us_to_samples);
 		EmitHigh(560 * us_to_samples);
 		EmitLow(560 * us_to_samples);
 		EmitHigh(20000 * us_to_samples);
 	}
 	*simulation_channel = &mSimChannel;
 	return 1;
 }
--- a/Analyzer/raw/PulseLengthStat/src/PulseLengthStatSimulationDataGenerator.h
+++ b/Analyzer/raw/PulseLengthStat/src/PulseLengthStatSimulationDataGenerator.h
@ -1,27 +0,0 @@
 #ifndef PULSELENGTHSTAT_SIMULATION_DATA_GENERATOR
 #define PULSELENGTHSTAT_SIMULATION_DATA_GENERATOR
 #include <SimulationChannelDescriptor.h>
 class PulseLengthStatAnalyzerSettings;
 class PulseLengthStatSimulationDataGenerator
 {
 public:
 	PulseLengthStatSimulationDataGenerator();
 	~PulseLengthStatSimulationDataGenerator();
 	void Initialize(U32 simulation_sample_rate, PulseLengthStatAnalyzerSettings* settings);
 	U32 GenerateSimulationData(U64 newest_sample_requested, U32 sample_rate, SimulationChannelDescriptor** simulation_channel);
 protected:
 	PulseLengthStatAnalyzerSettings* mSettings;
 	U32 mSimulationSampleRateHz;
 	SimulationChannelDescriptor mSimChannel;
 	void EmitIdle(U32 samples);
 	void EmitLow(U32 samples);
 	void EmitHigh(U32 samples);
 };
 #endif
--- a/Analyzer/raw/dll/.gitkeep
+++ b/Analyzer/raw/dll/.gitkeep
--- a/IR-protocol.ino
+++ b/IR-protocol.ino
@ -2,26 +2,16 @@
 #include "IR_Encoder.h"
 #include "TimerStatic.h"
 #include "MemoryCheck.h"
 #include "CarCmdList.h"
 /////////////// Pinout ///////////////
-#define dec0_PIN PIN_KT1_IN
+#define encForward_PIN    0
-#define dec1_PIN PIN_KT2_IN
+#define encBackward_PIN   5
 #define dec2_PIN PIN_KT3_IN
 #define dec3_PIN PIN_KT4_IN
 #define dec4_PIN PIN_KT5_IN
 #define dec5_PIN PIN_KT6_IN
 #define dec6_PIN PIN_KT7_IN
 #define dec7_PIN PIN_KT8_IN
 // #define dec8_PIN PB8
 // #define dec9_PIN PB9
 // #define dec10_PIN PB10
 // #define dec11_PIN PB11
 // #define dec12_PIN PB12
 // #define dec13_PIN PB13
 // #define dec14_PIN PB14
 // #define dec15_PIN PB15
-#define LoopOut PC13
+#define LoopOut 12
 #define ISR_Out 10
 #define TestOut 13
 //////////////// Ini /////////////////
@ -49,13 +39,35 @@ void EncoderISR()
    IR_Encoder::isr();
 }
-//-------------------------------------------------------------------
+void decBackwardISR() {
    decBackward.isr();
 }
-IR_Decoder dec0(dec0_PIN, 0);
+static uint8_t* portOut;
-void dec_0_ISR() { dec0.isr(); }
+ISR(TIMER2_COMPA_vect) {
    encForward.isr();
    // encBackward.isr();
    // encTree.isr();
    //TODO: Сделать выбор порта 
    *portOut = (*portOut & 0b11111110) |
        (
            encForward.ir_out_virtual << 0U
            // | encBackward.ir_out_virtual << 6U
            // | encTree.ir_out_virtual << 2U
            );
 }
 /////////////////////////////////////////////////////////////////////
 uint8_t data0 [] = { };
 uint8_t data1 [] = { 42 };
 uint8_t data2 [] = { 42 , 127 };
 uint8_t data3 [] = { 42 , 127, 137 };
 uint8_t data4 [] = { 42 , 127, 137, 255 };
-IR_Decoder dec1(dec1_PIN, 1);
+uint32_t loopTimer;
-void dec_1_ISR() { dec1.isr(); }
+uint8_t sig = 255;
 uint16_t targetAddr = IR_Broadcast;
 Timer t1(750, millis, []() {
 IR_Decoder dec2(dec2_PIN, 2);
 void dec_2_ISR() { dec2.isr(); }
@ -81,8 +93,19 @@ void dec_7_ISR() { dec7.isr(); }
 // IR_Decoder dec9(dec9_PIN, 9);
 // void dec_9_ISR() { dec9.isr(); }
-// IR_Decoder dec10(dec10_PIN, 10);
+        default:
-// void dec_10_ISR() { dec10.isr(); }
+            break;
    }
    // encBackward.sendData(IR_Broadcast, data2);
    // encTree.sendData(IR_Broadcast, rawData3);
 });
 Timer t2(500, millis, []() {
    digitalToggle(13);
 });
 /////////////////////////////////////////////////////////////////////
 void setup() {
    IR_Encoder::timerSetup();
    portOut = &PORTB;
 // IR_Decoder dec11(dec11_PIN, 11);
 // void dec_11_ISR() { dec11.isr(); }
@ -100,9 +123,14 @@ uint8_t data2[] = {42, 127};
 uint8_t data3[] = {42, 127, 137};
 uint8_t data4[] = {42, 127, 137, 255};
-uint32_t loopTimer;
+    pinMode(8, OUTPUT);
-uint8_t sig = 0;
+    pinMode(9, OUTPUT);
-uint16_t targetAddr = IR_Broadcast;
+    pinMode(11, OUTPUT);
    pinMode(13, OUTPUT);
    pinMode(encForward_PIN, OUTPUT);
    pinMode(encBackward_PIN, OUTPUT);
    pinMode(13, OUTPUT);
    pinMode(12, OUTPUT);
 Timer t1(500, millis, []()
         {
@ -217,61 +245,30 @@ void setup()
    pinMode(LoopOut, OUTPUT);
-    pinMode(dec0_PIN, INPUT_PULLUP);
+    attachInterrupt(0, decForwardISR, CHANGE);  // D2 
-    pinMode(dec1_PIN, INPUT_PULLUP);
+    attachInterrupt(1, decBackwardISR, CHANGE); // D3
    pinMode(dec2_PIN, INPUT_PULLUP);
    pinMode(dec3_PIN, INPUT_PULLUP);
    pinMode(dec4_PIN, INPUT_PULLUP);
    pinMode(dec5_PIN, INPUT_PULLUP);
    pinMode(dec6_PIN, INPUT_PULLUP);
    pinMode(dec7_PIN, INPUT_PULLUP);
    // pinMode(dec8_PIN, INPUT_PULLUP);
    // pinMode(dec9_PIN, INPUT_PULLUP);
    // pinMode(dec10_PIN, INPUT_PULLUP);
    // pinMode(dec11_PIN, INPUT_PULLUP);
    // pinMode(dec12_PIN, INPUT_PULLUP);
    // pinMode(dec13_PIN, INPUT_PULLUP);
    attachInterrupt(dec0_PIN, dec_0_ISR, CHANGE);
    attachInterrupt(dec1_PIN, dec_1_ISR, CHANGE);
    attachInterrupt(dec2_PIN, dec_2_ISR, CHANGE);
    attachInterrupt(dec3_PIN, dec_3_ISR, CHANGE);
    attachInterrupt(dec4_PIN, dec_4_ISR, CHANGE);
    attachInterrupt(dec5_PIN, dec_5_ISR, CHANGE);
    attachInterrupt(dec6_PIN, dec_6_ISR, CHANGE);
    attachInterrupt(dec7_PIN, dec_7_ISR, CHANGE);
    // attachInterrupt(dec8_PIN, dec_8_ISR, CHANGE);
    // attachInterrupt(dec9_PIN, dec_9_ISR, CHANGE);
    // attachInterrupt(dec10_PIN, dec_10_ISR, CHANGE);
    // attachInterrupt(dec11_PIN, dec_11_ISR, CHANGE);
    // attachInterrupt(dec12_PIN, dec_12_ISR, CHANGE);
    // attachInterrupt(dec13_PIN, dec_13_ISR, CHANGE);
 }
-void loop()
+
-{
+bool testLed = false;
-    digitalToggle(LoopOut);
+uint32_t testLed_timer;
 void loop() {
    // digitalToggle(LoopOut);
    Timer::tick();
    IR_Decoder::tick();
-    bool rx_flag = false;
+    decForward.tick();
-    rx_flag |= status(dec0);
+    decBackward.tick();
    rx_flag |= status(dec1);
    rx_flag |= status(dec2);
    rx_flag |= status(dec3);
    rx_flag |= status(dec4);
    rx_flag |= status(dec5);
    rx_flag |= status(dec6);
    rx_flag |= status(dec7);
    // rx_flag |= status(dec8);
    // rx_flag |= status(dec9);
    // rx_flag |= status(dec10);
    // rx_flag |= status(dec11);
    // rx_flag |= status(dec12);
    // rx_flag |= status(dec13);
-    if (Serial.available())
+    status(decForward);
-    {
+    status(decBackward);
    // Serial.println(micros() - loopTimer);
    // loopTimer = micros();
    // delayMicroseconds(120*5);
    if (Serial.available()) {
        uint8_t in = Serial.parseInt();
        switch (in)
        {
@ -289,6 +286,13 @@ void loop()
            break;
        }
    }
    if(testLed && millis() - testLed_timer > 100){
        testLed=false;
        digitalWrite(12, LOW);
    }
 }
@ -316,13 +320,19 @@ void detectSignal()
    //                         { digitalWrite(SignalDetectLed, LOW); });
 }
-// test
+
-bool status(IR_Decoder &dec)
+
-{
+//test
-    if (dec.gotData.available())
+void status(IR_Decoder& dec) {
-    {
+    if (dec.gotData.available() && dec.gotData.getAddrFrom() != 42) {
-        detectSignal();
+
-        // Serial.println(micros());
+        digitalWrite(12, HIGH);
        testLed = true;
        testLed_timer = millis();
        encForward.sendData(IR_Broadcast, CarCmd::stop); //<<<<<<<<<<<<<<<<<<<<<<<<<<< CMD IS HERE
        String str;
        if (/* dec.gotData.getDataPrt()[1] */ 1)
        {
--- a/IR_DMA_ISR_signal_analysis.md
+++ b/IR_DMA_ISR_signal_analysis.md
@ -1,141 +0,0 @@
 # IR DMA vs ISR: анализ согласованности сигнала и ответа версии
 Связка с остальным пультом (модули, настройки): **[`ARCHITECTURE.md`](ARCHITECTURE.md)**.
 Документ фиксирует наблюдения по переходу машинки (проект Car) на **DMA-передачу** ИК через `IR_Encoder::setExternalTxBackend` и `IrDmaBackend`, сравнение со **старым путём** (таймер + **`_isr()`**), ручную проверку CRC по логу пульта и роль **`buildGateRuns`** в библиотеке **IR-protocol**.
 ---
 ## 1. Контекст
 - До введения DMA передача шла через **`IR_Encoder::begin(..., IR_Encoder::isr)`**: на каждый тик таймера (`carrierFrec * 2`) вызывается **`_isr()`**, формируются преамбула, данные, синхробиты.
 - После коммита с **IR_DMA** (`Car`, `IR.cpp`): **`beginClockOnly`**, **`setExternalTxBackend`**, фактическая модуляция — **`IrDmaBackend::start`** → **`IR_Encoder::buildGateRuns`** + DMA в **BSRR**.
 - Ответ версии — один из самых **длинных** кадров (до **31 байта** полного кадра по заголовку). Короткие пакеты (эхо `Version_Query`, 8 байт) в логе остаются **FrameOK**; длинный ответ версии даёт **CRC fail** / `Frame reject`.
 ---
 ## 2. Два пути: ISR и DMA
 | Этап | Старый ISR | DMA |
 |------|------------|-----|
 | Байты пакета + CRC | `sendDataFULL` → `sendBuffer` | То же; в `buildGateRuns` — `memcpy` в локальный буфер размером `dataByteSizeMax` |
 | Развёртка в импульсы | **`_isr()`**: счётчик `toggleCounter`, ветки preamb / data / sync | **`buildGateRuns`**: RLE-сегменты `(gate, lenTicks)` → **`nextWord()`** по тикам таймера |
 | Останов передачи | `signal == noSignal`, `isSending = false` | `ticksOutput >= totalTicks`, `sum(runs[i].lenTicks)` |
 Идея `buildGateRuns`: **эмулировать** шаги FSM, которые в ISR выполняются при **`toggleCounter == 0`** (см. комментарий в `IR_Encoder.cpp` рядом с внутренним `while`).
 ### 2.1. Приоритеты NVIC: приём ИК выше, чем DMA передачи (STM32)
 Пока активна **внешняя** передача по DMA (`IrDmaBackend` и т.п.), таймер крутит поток запросов к DMA — срабатывают **`DMA1_Channelx_IRQn`** (половина/конец буфера и т.д.). Если их приоритет **выше**, чем у **EXTI** линии пина приёмника, обработка фронтов на входе ИК **откладывается** → растёт джиттер `micros()` и страдает заполнение `subBuffer` / журнал `@IRF1v1`, хотя алгоритм `tick`/`writeToBuffer` не менялся.
 **Требование:** числовой приоритет **приёма (EXTI)** должен быть **выше приоритета DMA передачи** (в терминах Cortex-M / STM32 HAL: **меньше** значение preempt priority у EXTI, чем у канала DMA ИК).
 **В репозитории:**
 - **`IR_Decoder`**: библиотека **не** задаёт приоритет EXTI по умолчанию. На Arduino STM32 пользователь вызывает **`setReceiveExtiPreemptPriority(preempt)`** (до или после `enable()`); после `attachInterrupt` применяется поверх приоритета ядра. Семейства с укороченной картой EXTI (C0/F0/G0/L0) — без изменения NVIC из этой функции.
 - **DMA ИК-TX** (например **`Car/src/IR/IrDmaBackend.cpp`**): preempt задаётся в прошивке носителя (**`CarIrq::kIrTxDmaPreempt`** и т.д.) и должен быть **больше** (ниже срочность), чем у приёма.
 Свой проект: пользователь обязан согласовать приоритеты; **ни один** канал DMA ИК-TX не должен вытеснять EXTI приёма (меньший preempt у DMA = ошибка).
 ---
 ## 3. Ключевое наблюдение: `runLenTicks = toggleCounter + 1`
 В **`IR_Encoder::buildGateRuns`** на каждой итерации внешнего цикла:
 ```cpp
 const uint16_t runLenTicks = (uint16_t)toggleCounterLocal + 1U;
 ```
 В **`_isr()`** при стартовом **`toggleCounter == N`** выполняется **ровно N** раз ветка `if (toggleCounter) { toggleCounter--; }` подряд, пока счётчик не станет **0**; **следующий** тик попадает в `else` и делает один шаг `switch (signal)`.
 Между двумя такими визитами в `else` проходит **N тиков таймера**, не **N+1**.
 В `buildGateRuns` для того же начального `toggleCounterLocal` в run записывается **`N + 1` тик**. Это даёт **систематическое удлинение каждого сегмента на 1 тик** относительно модели «счётчик убывает N раз до нуля».
 **Следствие:**
 - `totalTicks = Σ lenTicks` в **`IrDmaBackend::startStream`** **больше**, чем число тиков, которое дал бы чистый ISR при том же пакете.
 - Число внешних итераций `buildGateRuns` (шагов FSM) совпадает с числом таких сегментов; приближённо:  
  `totalTicks ≈ totalTicks_ISR + (число_внешних_шагов)`.
 Короткий кадр: ошибка может «теряться» в допусках приёмника. Длинный (версия) — **накопление** ошибки по времени → сдвиг границ битов → **неверные байты**, в том числе **CRC**.
 ---
 ## 4. Ручная проверка CRC по логу (пульт)
 Алгоритм: **`IR_FOX::crc8`** (`IR_config.cpp`), два байта как в **`sendDataFULL`**:
 - первый байт CRC = `crc8(data, 0, packSize - 2, poly1)`;
 - второй = `crc8(data, 0, packSize - 1, poly2)` (в расчёт второго входит уже первый байт CRC).
 Пример **31-байтного** кадра из лога `Frame reject`:
 - Тело **0…28** (29 байт).  
 - Байты **29…30** — CRC на проводе.
 Для фиксированного дампа байтов **0…28** корректная пара CRC по формуле библиотеки — **`6E 54`**, в логе на проводе — **`96 62`** → **не совпадает**; приёмник обоснованно отклоняет кадр.
 Это **не** объясняется разницей AVR vs STM32: счёт идёт по массиву `uint8_t` побайтно.
 Эхо **8 байт** `C8 FA 2A FD E8 5D AA B4`: пересчёт даёт **`AA B4`** — совпадает с последними байтами кадра → для этого пакета цепочка **байт → CRC** согласована.
 ---
 ## 5. Скрипт симуляции
 В репозитории: **`docs/scripts/ir_protocol_gate_runs_sim.py`**.
 Запуск:
 ```bash
 python docs/scripts/ir_protocol_gate_runs_sim.py
 ```
 Скрипт:
 1. Считает **CRC** для примеров пакетов (8 байт эха и 31 байт из reject).
 2. Воспроизводит логику **`buildGateRuns`** (с дополнением буфера до `dataByteSizeMax`, как в C++).
 3. Печатает **`totalTicks`**, число **внешних шагов** FSM и связь **`totalTicks - outer_steps`** как оценку «тиков в модели ISR без +1 на каждый шаг».
 Пример вывода (значения могут слегка отличаться при смене констант в `IR_config.h`):
 - `preambToggle = 97`
 - для 8-байт пакета: сотни шагов FSM, `totalTicks` порядка тысяч тиков
 - для 31-байт: больше шагов и `totalTicks` (~25k+ тиков для текущих констант)
 ---
 ## 6. Связь с проектами
 - **Car** (`Executer.cpp`): ответ версии через **`IR_Module::getENC().sendData(...)`** — тот же **`sendDataFULL`**, затем **`rawSend`** → DMA.
 - **ControlPointUnion** (`CustomCmd.h`, слоты): запрос версии через **`sendResp`** с **`version_query`** — задержка **`IR_ResponseDelay`**, затем **`sendData`** на адрес машинки.
 - **ControlPointUnion** (`Plan_B.ino`): разбор **`version_response`** из **`gotData` / `gotBackData`** только после **успешного CRC** в декодере.
 ---
 ## 7. Выводы
 1. **Байты в RAM** на передаче формируются корректно библиотекой; проблема «после DMA» укладывается в **расхождение тайминговой развёртки** (`buildGateRuns` + DMA) со **старой** развёрткой ISR, а не в «другой CRC на машинке» при неизменённой библиотеке.
 2. **Подозрение №1:** `runLenTicks = toggleCounter + 1` в **`buildGateRuns`** не совпадает с числом тиков ISR между шагами FSM (**`N`** vs **`N+1`**). Требуется сверка с эталонной трассой ISR или логическим анализатором.
 3. **Проверка на будущее:** сравнить побитово выходы ISR и DMA на **одном** буфере (8 и 31 байт); при необходимости поправить формулу длины run в **`IR-protocol`** и пересобрать Car и пульт.
 4. При **DMA-режиме передачи** на STM32 соблюдать **приоритеты NVIC** (раздел **2.1**): приём EXTI **выше**, чем DMA ИК-TX.
 ---
 ## 8. Ссылки на файлы
 | Файл | Назначение |
 |------|------------|
 | `Documents/Arduino/libraries/IR-protocol/IR_Encoder.cpp` | `buildGateRuns`, `_isr`, `rawSend` |
 | `Documents/Arduino/libraries/IR-protocol/IR_Decoder.cpp` | `setReceiveExtiPreemptPriority` / `enable`: опциональный `NVIC_SetPriority` для EXTI (Arduino STM32) |
 | `Documents/Arduino/libraries/IR-protocol/IR_config.cpp` | `crc8` |
 | `Car/src/IR/IR.cpp` | `setExternalTxBackend`, `txStart` |
 | `Car/src/IR/IrDmaBackend.cpp` | `startStream`, `totalTicks`, `nextWord`, NVIC DMA из `CarIrq` |
 | `Car/src/IR/IR.cpp` | `setReceiveExtiPreemptPriority` + `enable` декодера |
 | `ControlPointUnion/Plan_B/TestPoints/CustomCmd.h` | `sendResp` / `version_query` для тестовых слотов |
 ---
 *Документ составлен по обсуждению в чате; при смене версии IR-protocol числа констант и `totalTicks` пересчитывайте скриптом.*
--- a/IR_Encoder.cpp
+++ b/IR_Encoder.cpp
@ -321,7 +321,10 @@ IR_SendResult IR_Encoder::sendData(uint16_t addrTo, uint8_t *data, uint8_t len,
    return sendDataFULL(id, addrTo, data, len, needAccept);
 }
-IR_SendResult IR_Encoder::sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data, uint8_t len, bool needAccept)
+void IR_Encoder::sendData(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false){
    sendData(id, addrTo, data, len, needAccept);
 }
 void IR_Encoder::sendData(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false)
 {
    if (len > bytePerPack)
    {
--- a/IR_Encoder.h
+++ b/IR_Encoder.h
@ -20,7 +20,8 @@ class IR_Encoder : public IR_FOX
    static IR_Encoder *last;
    IR_Encoder *next;
 public:
-    static HardwareTimer* IR_Timer;
+private:
    // uint16_t id; /// @brief Адрес передатчика
    struct IR_TxGateRun {
        uint16_t lenTicks; // number of timer ticks at carrierFrec*2
@ -60,10 +61,9 @@ public:
    void setBlindDecoders(IR_DecoderRaw *decoders[], uint8_t count);
    void rawSend(uint8_t *ptr, uint8_t len);
-    IR_SendResult sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept = false);
+    void sendData(uint16_t addrTo, uint8_t dataByte, bool needAccept = false);
-    IR_SendResult sendData(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
+    void sendData(uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
-    IR_SendResult sendDataFULL(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
+    void sendData(uint16_t addrFrom, uint16_t addrTo, uint8_t *data = nullptr, uint8_t len = 0, bool needAccept = false);
    IR_SendResult sendAccept(uint16_t addrTo, uint8_t customByte = 0);
    IR_SendResult sendRequest(uint16_t addrTo);
--- a/ir_protocol_gate_runs_sim.py
+++ b/ir_protocol_gate_runs_sim.py
@ -1,174 +0,0 @@
 #!/usr/bin/env python3
 """
 Симуляция логики IR_Encoder::buildGateRuns (IR-protocol) и утилиты CRC8.
 Запуск из корня репозитория: python docs/scripts/ir_protocol_gate_runs_sim.py
 Или: python ir_protocol_gate_runs_sim.py из каталога scripts/
 """
 from __future__ import annotations
 import sys
 # --- IR_config.h (фрагмент) ---
 bitPauseTakts = 12
 bitActiveTakts = 25
 preambPulse = 3
 syncBits = 3
 bitPerByte = 8
 preambToggle = ((bitPauseTakts * 2 + bitActiveTakts) * 2 - 1)
 bitHigh = [(bitPauseTakts) * 2 - 1, (bitActiveTakts) * 2 - 1]
 bitLow = [(bitPauseTakts // 2 + bitActiveTakts) * 2 - 1, (bitPauseTakts) - 1]
 preamb, data, sync, noSignal = 0, 1, 2, 3
 HIGH = True
 def crc8(data: bytes, start: int, end: int, poly: int) -> int:
    """Как IR_FOX::crc8 в IR_config.cpp: [start, end)."""
    crc = 0xFF
    for i in range(start, end):
        crc ^= data[i]
        for _ in range(8):
            if (crc & 0x80) != 0:
                crc = ((crc << 1) ^ poly) & 0xFF
            else:
                crc = (crc << 1) & 0xFF
    return crc
 def crc_pair_over_wire(packet: bytes) -> tuple[int, int]:
    """Два байта CRC как в IR_Encoder::sendDataFULL (poly1 старший, poly2 младший)."""
    ps = len(packet)
    if ps < 2:
        return 0, 0
    b1 = crc8(packet, 0, ps - 2, 0x31) & 0xFF
    b2 = crc8(packet, 0, ps - 1, 0x8C) & 0xFF
    return b1, b2
 # Как dataByteSizeMax в IR_config.h (msg+addr+addr+bytePerPack+crc)
 DATA_BYTE_SIZE_MAX = 1 + 2 + 2 + 31 + 2
 def build_gate_runs(packet: bytes):
    """
    Повторяет IR_Encoder::buildGateRuns: список (gate: bool, lenTicks: int), сумма lenTicks = totalTicks DMA.
    Буфер дополняется нулями до dataByteSizeMax, как sendBufferLocal[dataByteSizeMax] в C++.
    """
    send_len = len(packet)
    send_buf = bytearray(packet) + bytes(max(0, DATA_BYTE_SIZE_MAX - len(packet)))
    toggle = preambToggle
    data_bit = bitPerByte - 1
    data_byte = 0
    preamb_front = preambPulse * 2 - 1
    data_seq = bitPerByte * 2
    sync_seq = syncBits * 2
    sync_last = False
    sig = preamb
    state = HIGH
    cur_seq = bitHigh
    runs: list[tuple[bool, int]] = []
    outer_steps = 0
    while True:
        outer_steps += 1
        gate = state
        run_len = toggle + 1  # как в C++: (uint16_t)toggleCounterLocal + 1U
        if runs and runs[-1][0] == gate:
            g, ln = runs[-1]
            runs[-1] = (g, ln + run_len)
        else:
            runs.append((gate, run_len))
        while True:
            if sig == noSignal:
                return runs, outer_steps
            if sig == preamb:
                if preamb_front:
                    preamb_front -= 1
                    toggle = preambToggle
                    break
                sig = data
                state = not False
                continue
            if sig == data:
                if data_seq:
                    if not (data_seq & 1):
                        cur_seq = bitHigh if ((send_buf[data_byte] >> data_bit) & 1) else bitLow
                        data_bit -= 1
                    toggle = cur_seq[not state]
                    data_seq -= 1
                    break
                sync_last = send_buf[data_byte] & 1
                data_byte += 1
                data_bit = bitPerByte - 1
                data_seq = bitPerByte * 2
                sig = sync
                continue
            if sig == sync:
                if sync_seq:
                    if not (sync_seq & 1):
                        if sync_seq == 2:
                            cur_seq = bitLow if (send_buf[data_byte] & 0x80) else bitHigh
                        else:
                            cur_seq = bitLow if sync_last else bitHigh
                            sync_last = not sync_last
                    toggle = cur_seq[not state]
                    sync_seq -= 1
                    break
                sig = data
                sync_seq = syncBits * 2
                if data_byte >= send_len:
                    sig = noSignal
                continue
            return [], 0
        state = not state
 def main() -> int:
    print("IR-protocol: preambToggle =", preambToggle)
    print()
    # Пример из лога: 8-байтный эхо-пакет Version_Query (CRC OK на приёме)
    echo = bytes.fromhex("C8 FA 2A FD E8 5D AA B4")
    c1, c2 = crc_pair_over_wire(echo)
    print("8 байт (эхо): CRC вычисленный:", f"{c1:02X}", f"{c2:02X}", "| на проводе:", f"{echo[6]:02X}", f"{echo[7]:02X}")
    runs8, steps8 = build_gate_runs(echo)
    total8 = sum(r[1] for r in runs8)
    print("  buildGateRuns: внешних шагов FSM =", steps8, ", totalTicks =", total8, ", число run-сегментов =", len(runs8))
    print()
    # 31 байт из лога Frame reject (пример)
    reject = bytes.fromhex(
        "DF 00 00 FA 2A 5E 43 61 72 5F 76 34 2E 33 2E 38 5F 5B 31 32 4D 68 7A 5D 6B ED 1D 9A 53 96 62"
    )
    if len(reject) == 31:
        c1, c2 = crc_pair_over_wire(reject)
        print("31 байт (reject): CRC по телу 0..28 должен быть:", f"{c1:02X}", f"{c2:02X}", "| байты [29:31]:", f"{reject[29]:02X}", f"{reject[30]:02X}")
        print("  Совпадение с формулой:", c1 == reject[29] and c2 == reject[30])
    runs31, steps31 = build_gate_runs(reject)
    total31 = sum(r[1] for r in runs31)
    print("  buildGateRuns: внешних шагов =", steps31, ", totalTicks =", total31, ", run-сегментов =", len(runs31))
    print()
    # Связь totalTicks с моделью «N тиков на сегмент до шага FSM»
    # total_build = sum(toggle_i + 1); если бы было sum(toggle_i), разница = steps
    theoretical_isr_ticks = total31 - steps31
    print("Для 31-байт пакета: totalTicks (buildGateRuns) =", total31)
    print("  Если каждый внешний шаг даёт +1 к длине сегмента относительно ISR (runLen = toggle+1 vs toggle),")
    print("  оценка «ISR-тиков» как totalTicks - outer_steps =", theoretical_isr_ticks)
    return 0
 if __name__ == "__main__":
    sys.exit(main())
Author	SHA1	Message	Date
DashyFox	fc93ea41db	Merge pull request #8 from Show-maket/STM32 Stm32	2026-03-11 17:06:20 +03:00
DashyFox	0620d98e35	Merge branch 'main' into STM32	2026-03-11 17:06:06 +03:00
DashyFox	4caed06218	Merge pull request #7 from Show-maket/STM32DMA upd	2026-03-11 16:59:08 +03:00
DashyFox	37522f974f	upd	2024-12-25 16:56:18 +03:00
DashyFox	6375c4eed5	for debug test	2024-09-04 10:12:39 +03:00
DashyFox	c4000d6b75	test	2024-08-14 17:43:12 +03:00
DashyFox	fc02c79135	upd	2024-04-22 14:56:12 +03:00
DashyFox	d068a576f7	Merge pull request #3 from Show-maket/dev v2.0	2024-03-18 16:24:38 +03:00