libsanitizer/tsan/tsan_trace.h - gcc - Git at Google

 //===-- tsan_trace.h --------------------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of ThreadSanitizer (TSan), a race detector.
 //
 //===----------------------------------------------------------------------===//
 #ifndef TSAN_TRACE_H
 #define TSAN_TRACE_H

 #include "tsan_defs.h"
 #include "tsan_ilist.h"
 #include "tsan_mutexset.h"
 #include "tsan_stack_trace.h"

 namespace __tsan {

 const int kTracePartSizeBits = 13;
 const int kTracePartSize = 1 << kTracePartSizeBits;
 const int kTraceParts = 2 * 1024 * 1024 / kTracePartSize;
 const int kTraceSize = kTracePartSize * kTraceParts;

 // Must fit into 3 bits.
 enum EventType {
   EventTypeMop,
   EventTypeFuncEnter,
   EventTypeFuncExit,
   EventTypeLock,
   EventTypeUnlock,
   EventTypeRLock,
   EventTypeRUnlock
 };

 // Represents a thread event (from most significant bit):
 // u64 typ  : 3;   // EventType.
 // u64 addr : 61;  // Associated pc.
 typedef u64 Event;

 const uptr kEventPCBits = 61;

 struct TraceHeader {
 #if !SANITIZER_GO
   BufferedStackTrace stack0;  // Start stack for the trace.
 #else
   VarSizeStackTrace stack0;
 #endif
   u64        epoch0;  // Start epoch for the trace.
   MutexSet   mset0;

   TraceHeader() : stack0(), epoch0() {}
 };

 struct Trace {
   Mutex mtx;
 #if !SANITIZER_GO
   // Must be last to catch overflow as paging fault.
   // Go shadow stack is dynamically allocated.
   uptr shadow_stack[kShadowStackSize];
 #endif
   // Must be the last field, because we unmap the unused part in
   // CreateThreadContext.
   TraceHeader headers[kTraceParts];

   Trace() : mtx(MutexTypeTrace) {}
 };

 namespace v3 {

 enum class EventType : u64 {
   kAccessExt,
   kAccessRange,
   kLock,
   kRLock,
   kUnlock,
   kTime,
 };

 // "Base" type for all events for type dispatch.
 struct Event {
   // We use variable-length type encoding to give more bits to some event
   // types that need them. If is_access is set, this is EventAccess.
   // Otherwise, if is_func is set, this is EventFunc.
   // Otherwise type denotes the type.
   u64 is_access : 1;
   u64 is_func : 1;
   EventType type : 3;
   u64 _ : 59;
 };
 static_assert(sizeof(Event) == 8, "bad Event size");

 // Nop event used as padding and does not affect state during replay.
 static constexpr Event NopEvent = {1, 0, EventType::kAccessExt, 0};

 // Compressed memory access can represent only some events with PCs
 // close enough to each other. Otherwise we fall back to EventAccessExt.
 struct EventAccess {
   static constexpr uptr kPCBits = 15;

   u64 is_access : 1;  // = 1
   u64 is_read : 1;
   u64 is_atomic : 1;
   u64 size_log : 2;
   u64 pc_delta : kPCBits;  // signed delta from the previous memory access PC
   u64 addr : kCompressedAddrBits;
 };
 static_assert(sizeof(EventAccess) == 8, "bad EventAccess size");

 // Function entry (pc != 0) or exit (pc == 0).
 struct EventFunc {
   u64 is_access : 1;  // = 0
   u64 is_func : 1;    // = 1
   u64 pc : 62;
 };
 static_assert(sizeof(EventFunc) == 8, "bad EventFunc size");

 // Extended memory access with full PC.
 struct EventAccessExt {
   u64 is_access : 1;   // = 0
   u64 is_func : 1;     // = 0
   EventType type : 3;  // = EventType::kAccessExt
   u64 is_read : 1;
   u64 is_atomic : 1;
   u64 size_log : 2;
   u64 _ : 11;
   u64 addr : kCompressedAddrBits;
   u64 pc;
 };
 static_assert(sizeof(EventAccessExt) == 16, "bad EventAccessExt size");

 // Access to a memory range.
 struct EventAccessRange {
   static constexpr uptr kSizeLoBits = 13;

   u64 is_access : 1;   // = 0
   u64 is_func : 1;     // = 0
   EventType type : 3;  // = EventType::kAccessRange
   u64 is_read : 1;
   u64 is_free : 1;
   u64 size_lo : kSizeLoBits;
   u64 pc : kCompressedAddrBits;
   u64 addr : kCompressedAddrBits;
   u64 size_hi : 64 - kCompressedAddrBits;
 };
 static_assert(sizeof(EventAccessRange) == 16, "bad EventAccessRange size");

 // Mutex lock.
 struct EventLock {
   static constexpr uptr kStackIDLoBits = 15;

   u64 is_access : 1;   // = 0
   u64 is_func : 1;     // = 0
   EventType type : 3;  // = EventType::kLock or EventType::kRLock
   u64 pc : kCompressedAddrBits;
   u64 stack_lo : kStackIDLoBits;
   u64 stack_hi : sizeof(StackID) * kByteBits - kStackIDLoBits;
   u64 _ : 3;
   u64 addr : kCompressedAddrBits;
 };
 static_assert(sizeof(EventLock) == 16, "bad EventLock size");

 // Mutex unlock.
 struct EventUnlock {
   u64 is_access : 1;   // = 0
   u64 is_func : 1;     // = 0
   EventType type : 3;  // = EventType::kUnlock
   u64 _ : 15;
   u64 addr : kCompressedAddrBits;
 };
 static_assert(sizeof(EventUnlock) == 8, "bad EventUnlock size");

 // Time change event.
 struct EventTime {
   u64 is_access : 1;   // = 0
   u64 is_func : 1;     // = 0
   EventType type : 3;  // = EventType::kTime
   u64 sid : sizeof(Sid) * kByteBits;
   u64 epoch : kEpochBits;
   u64 _ : 64 - 5 - sizeof(Sid) * kByteBits - kEpochBits;
 };
 static_assert(sizeof(EventTime) == 8, "bad EventTime size");

 struct Trace;

 struct TraceHeader {
   Trace* trace = nullptr;  // back-pointer to Trace containing this part
   INode trace_parts;       // in Trace::parts
 };

 struct TracePart : TraceHeader {
   static constexpr uptr kByteSize = 256 << 10;
   static constexpr uptr kSize =
       (kByteSize - sizeof(TraceHeader)) / sizeof(Event);
   // TraceAcquire does a fast event pointer overflow check by comparing
   // pointer into TracePart::events with kAlignment mask. Since TracePart's
   // are allocated page-aligned, this check detects end of the array
   // (it also have false positives in the middle that are filtered separately).
   // This also requires events to be the last field.
   static constexpr uptr kAlignment = 0xff0;
   Event events[kSize];

   TracePart() {}
 };
 static_assert(sizeof(TracePart) == TracePart::kByteSize, "bad TracePart size");

 struct Trace {
   Mutex mtx;
   IList<TraceHeader, &TraceHeader::trace_parts, TracePart> parts;
   Event* final_pos =
       nullptr;  // final position in the last part for finished threads

   Trace() : mtx(MutexTypeTrace) {}
 };

 }  // namespace v3

 }  // namespace __tsan

 #endif  // TSAN_TRACE_H
	//===-- tsan_trace.h --------------------------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of ThreadSanitizer (TSan), a race detector.
	//
	//===----------------------------------------------------------------------===//
	#ifndef TSAN_TRACE_H
	#define TSAN_TRACE_H

	#include "tsan_defs.h"
	#include "tsan_ilist.h"
	#include "tsan_mutexset.h"
	#include "tsan_stack_trace.h"

	namespace __tsan {

	const int kTracePartSizeBits = 13;
	const int kTracePartSize = 1 << kTracePartSizeBits;
	const int kTraceParts = 2 * 1024 * 1024 / kTracePartSize;
	const int kTraceSize = kTracePartSize * kTraceParts;

	// Must fit into 3 bits.
	enum EventType {
	EventTypeMop,
	EventTypeFuncEnter,
	EventTypeFuncExit,
	EventTypeLock,
	EventTypeUnlock,
	EventTypeRLock,
	EventTypeRUnlock
	};

	// Represents a thread event (from most significant bit):
	// u64 typ : 3; // EventType.
	// u64 addr : 61; // Associated pc.
	typedef u64 Event;

	const uptr kEventPCBits = 61;

	struct TraceHeader {
	#if !SANITIZER_GO
	BufferedStackTrace stack0; // Start stack for the trace.
	#else
	VarSizeStackTrace stack0;
	#endif
	u64 epoch0; // Start epoch for the trace.
	MutexSet mset0;

	TraceHeader() : stack0(), epoch0() {}
	};

	struct Trace {
	Mutex mtx;
	#if !SANITIZER_GO
	// Must be last to catch overflow as paging fault.
	// Go shadow stack is dynamically allocated.
	uptr shadow_stack[kShadowStackSize];
	#endif
	// Must be the last field, because we unmap the unused part in
	// CreateThreadContext.
	TraceHeader headers[kTraceParts];

	Trace() : mtx(MutexTypeTrace) {}
	};

	namespace v3 {

	enum class EventType : u64 {
	kAccessExt,
	kAccessRange,
	kLock,
	kRLock,
	kUnlock,
	kTime,
	};

	// "Base" type for all events for type dispatch.
	struct Event {
	// We use variable-length type encoding to give more bits to some event
	// types that need them. If is_access is set, this is EventAccess.
	// Otherwise, if is_func is set, this is EventFunc.
	// Otherwise type denotes the type.
	u64 is_access : 1;
	u64 is_func : 1;
	EventType type : 3;
	u64 _ : 59;
	};
	static_assert(sizeof(Event) == 8, "bad Event size");

	// Nop event used as padding and does not affect state during replay.
	static constexpr Event NopEvent = {1, 0, EventType::kAccessExt, 0};

	// Compressed memory access can represent only some events with PCs
	// close enough to each other. Otherwise we fall back to EventAccessExt.
	struct EventAccess {
	static constexpr uptr kPCBits = 15;

	u64 is_access : 1; // = 1
	u64 is_read : 1;
	u64 is_atomic : 1;
	u64 size_log : 2;
	u64 pc_delta : kPCBits; // signed delta from the previous memory access PC
	u64 addr : kCompressedAddrBits;
	};
	static_assert(sizeof(EventAccess) == 8, "bad EventAccess size");

	// Function entry (pc != 0) or exit (pc == 0).
	struct EventFunc {
	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 1
	u64 pc : 62;
	};
	static_assert(sizeof(EventFunc) == 8, "bad EventFunc size");

	// Extended memory access with full PC.
	struct EventAccessExt {
	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 0
	EventType type : 3; // = EventType::kAccessExt
	u64 is_read : 1;
	u64 is_atomic : 1;
	u64 size_log : 2;
	u64 _ : 11;
	u64 addr : kCompressedAddrBits;
	u64 pc;
	};
	static_assert(sizeof(EventAccessExt) == 16, "bad EventAccessExt size");

	// Access to a memory range.
	struct EventAccessRange {
	static constexpr uptr kSizeLoBits = 13;

	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 0
	EventType type : 3; // = EventType::kAccessRange
	u64 is_read : 1;
	u64 is_free : 1;
	u64 size_lo : kSizeLoBits;
	u64 pc : kCompressedAddrBits;
	u64 addr : kCompressedAddrBits;
	u64 size_hi : 64 - kCompressedAddrBits;
	};
	static_assert(sizeof(EventAccessRange) == 16, "bad EventAccessRange size");

	// Mutex lock.
	struct EventLock {
	static constexpr uptr kStackIDLoBits = 15;

	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 0
	EventType type : 3; // = EventType::kLock or EventType::kRLock
	u64 pc : kCompressedAddrBits;
	u64 stack_lo : kStackIDLoBits;
	u64 stack_hi : sizeof(StackID) * kByteBits - kStackIDLoBits;
	u64 _ : 3;
	u64 addr : kCompressedAddrBits;
	};
	static_assert(sizeof(EventLock) == 16, "bad EventLock size");

	// Mutex unlock.
	struct EventUnlock {
	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 0
	EventType type : 3; // = EventType::kUnlock
	u64 _ : 15;
	u64 addr : kCompressedAddrBits;
	};
	static_assert(sizeof(EventUnlock) == 8, "bad EventUnlock size");

	// Time change event.
	struct EventTime {
	u64 is_access : 1; // = 0
	u64 is_func : 1; // = 0
	EventType type : 3; // = EventType::kTime
	u64 sid : sizeof(Sid) * kByteBits;
	u64 epoch : kEpochBits;
	u64 _ : 64 - 5 - sizeof(Sid) * kByteBits - kEpochBits;
	};
	static_assert(sizeof(EventTime) == 8, "bad EventTime size");

	struct Trace;

	struct TraceHeader {
	Trace* trace = nullptr; // back-pointer to Trace containing this part
	INode trace_parts; // in Trace::parts
	};

	struct TracePart : TraceHeader {
	static constexpr uptr kByteSize = 256 << 10;
	static constexpr uptr kSize =
	(kByteSize - sizeof(TraceHeader)) / sizeof(Event);
	// TraceAcquire does a fast event pointer overflow check by comparing
	// pointer into TracePart::events with kAlignment mask. Since TracePart's
	// are allocated page-aligned, this check detects end of the array
	// (it also have false positives in the middle that are filtered separately).
	// This also requires events to be the last field.
	static constexpr uptr kAlignment = 0xff0;
	Event events[kSize];

	TracePart() {}
	};
	static_assert(sizeof(TracePart) == TracePart::kByteSize, "bad TracePart size");

	struct Trace {
	Mutex mtx;
	IList<TraceHeader, &TraceHeader::trace_parts, TracePart> parts;
	Event* final_pos =
	nullptr; // final position in the last part for finished threads

	Trace() : mtx(MutexTypeTrace) {}
	};

	} // namespace v3

	} // namespace __tsan

	#endif // TSAN_TRACE_H