llvm-project/compiler-rt/lib/msan/msan_origin.h

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//===-- msan_origin.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
//
//===----------------------------------------------------------------------===//
//
// Origin id utils.
//===----------------------------------------------------------------------===//
#ifndef MSAN_ORIGIN_H
#define MSAN_ORIGIN_H
#include "sanitizer_common/sanitizer_stackdepot.h"
#include "msan_chained_origin_depot.h"
namespace __msan {
// Origin handling.
//
// Origin is a 32-bit identifier that is attached to any uninitialized value in
// the program and describes, more or less exactly, how this memory came to be
// uninitialized.
//
// There are 3 kinds of origin ids:
// 1xxx xxxx xxxx xxxx heap origin id
// 0000 xxxx xxxx xxxx stack origin id
// 0zzz xxxx xxxx xxxx chained origin id
//
// Heap origin id describes a heap memory allocation and contains (in the xxx
// part) a value of StackDepot.
//
// Stack origin id describes a stack memory allocation and contains (in the xxx
// part) an index into StackOriginDescr and StackOriginPC. We don't store a
// stack trace for such origins for performance reasons.
//
// Chained origin id describes an event of storing an uninitialized value to
// memory. The xxx part is a value of ChainedOriginDepot, which is a mapping of
// (stack_id, prev_id) -> id, where
// * stack_id describes the event.
// StackDepot keeps a mapping between those and corresponding stack traces.
// * prev_id is another origin id that describes the earlier part of the
// uninitialized value history.
// Following a chain of prev_id provides the full recorded history of an
// uninitialized value.
//
// This, effectively, defines a tree (or 2 trees, see below) where nodes are
// points in value history marked with origin ids, and edges are events that are
// marked with stack_id.
//
// The "zzz" bits of chained origin id are used to store the length (or depth)
// of the origin chain.
class Origin {
public:
static bool isValidId(u32 id) { return id != 0 && id != (u32)-1; }
u32 raw_id() const { return raw_id_; }
bool isHeapOrigin() const {
// 0xxx xxxx xxxx xxxx
return raw_id_ >> kHeapShift == 0;
}
bool isStackOrigin() const {
// 1000 xxxx xxxx xxxx
return (raw_id_ >> kDepthShift) == (1 << kDepthBits);
}
bool isChainedOrigin() const {
// 1zzz xxxx xxxx xxxx, zzz != 000
return (raw_id_ >> kDepthShift) > (1 << kDepthBits);
}
u32 getChainedId() const {
CHECK(isChainedOrigin());
return raw_id_ & kChainedIdMask;
}
u32 getStackId() const {
CHECK(isStackOrigin());
return raw_id_ & kChainedIdMask;
}
u32 getHeapId() const {
CHECK(isHeapOrigin());
return raw_id_ & kHeapIdMask;
}
// Returns the next origin in the chain and the current stack trace.
Origin getNextChainedOrigin(StackTrace *stack) const {
CHECK(isChainedOrigin());
u32 prev_id;
u32 stack_id = ChainedOriginDepotGet(getChainedId(), &prev_id);
if (stack) *stack = StackDepotGet(stack_id);
return Origin(prev_id);
}
StackTrace getStackTraceForHeapOrigin() const {
return StackDepotGet(getHeapId());
}
static Origin CreateStackOrigin(u32 id) {
CHECK((id & kStackIdMask) == id);
return Origin((1 << kHeapShift) | id);
}
static Origin CreateHeapOrigin(StackTrace *stack) {
u32 stack_id = StackDepotPut(*stack);
CHECK(stack_id);
CHECK((stack_id & kHeapIdMask) == stack_id);
return Origin(stack_id);
}
static Origin CreateChainedOrigin(Origin prev, StackTrace *stack) {
int depth = prev.isChainedOrigin() ? prev.depth() : 0;
// depth is the length of the chain minus 1.
// origin_history_size of 0 means unlimited depth.
if (flags()->origin_history_size > 0) {
if (depth + 1 >= flags()->origin_history_size) {
return prev;
} else {
++depth;
CHECK(depth < (1 << kDepthBits));
}
}
StackDepotHandle h = StackDepotPut_WithHandle(*stack);
if (!h.valid()) return prev;
if (flags()->origin_history_per_stack_limit > 0) {
int use_count = h.use_count();
if (use_count > flags()->origin_history_per_stack_limit) return prev;
}
u32 chained_id;
bool inserted = ChainedOriginDepotPut(h.id(), prev.raw_id(), &chained_id);
CHECK((chained_id & kChainedIdMask) == chained_id);
if (inserted && flags()->origin_history_per_stack_limit > 0)
h.inc_use_count_unsafe();
return Origin((1 << kHeapShift) | (depth << kDepthShift) | chained_id);
}
static Origin FromRawId(u32 id) {
return Origin(id);
}
private:
static const int kDepthBits = 3;
static const int kDepthShift = 32 - kDepthBits - 1;
static const int kHeapShift = 31;
static const u32 kChainedIdMask = ((u32)-1) >> (32 - kDepthShift);
static const u32 kStackIdMask = ((u32)-1) >> (32 - kDepthShift);
static const u32 kHeapIdMask = ((u32)-1) >> (32 - kHeapShift);
u32 raw_id_;
explicit Origin(u32 raw_id) : raw_id_(raw_id) {}
int depth() const {
CHECK(isChainedOrigin());
return (raw_id_ >> kDepthShift) & ((1 << kDepthBits) - 1);
}
public:
static const int kMaxDepth = (1 << kDepthBits) - 1;
};
} // namespace __msan
#endif // MSAN_ORIGIN_H