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// Copyright 2015 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "courgette/label_manager.h"
#include <stddef.h>
#include <stdint.h>
#include <algorithm>
#include "base/check.h"
#include "base/check_op.h"
#include "base/logging.h"
#include "base/numerics/safe_conversions.h"
#include "base/numerics/safe_math.h"
#include "courgette/consecutive_range_visitor.h"
namespace courgette {
LabelManager::SimpleIndexAssigner::SimpleIndexAssigner(LabelVector* labels)
: labels_(labels) {
// Initialize |num_index_| and |available_|.
num_index_ = std::max(base::checked_cast<int>(labels_->size()),
GetLabelIndexBound(*labels_));
available_.resize(num_index_, true);
size_t used = 0;
for (const Label& label : *labels_) {
if (label.index_ != Label::kNoIndex) {
available_.at(label.index_) = false;
++used;
}
}
VLOG(1) << used << " of " << labels_->size() << " labels pre-assigned.";
}
LabelManager::SimpleIndexAssigner::~SimpleIndexAssigner() = default;
void LabelManager::SimpleIndexAssigner::DoForwardFill() {
size_t count = 0;
// Inside the loop, if |prev_index| == |kNoIndex| then we try to assign 0.
// This allows 0 (if unused) to be assigned in middle of |labels_|.
int prev_index = Label::kNoIndex;
for (auto p = labels_->begin(); p != labels_->end(); ++p) {
if (p->index_ == Label::kNoIndex) {
int index = (prev_index == Label::kNoIndex) ? 0 : prev_index + 1;
if (index < num_index_ && available_.at(index)) {
p->index_ = index;
available_.at(index) = false;
++count;
}
}
prev_index = p->index_;
}
VLOG(1) << " fill forward " << count;
}
void LabelManager::SimpleIndexAssigner::DoBackwardFill() {
size_t count = 0;
// This is asymmetric from DoForwardFill(), to preserve old behavior.
// Inside the loop, if |prev_index| == |kNoIndex| then we skip assignment.
// But we initilaize |prev_index| = |num_index_|, so if the last element in
// |labels_| has no index, then can use |num_index_| - 1 (if unused). We don't
// try this assignment elsewhere.
int prev_index = num_index_;
for (auto p = labels_->rbegin(); p != labels_->rend(); ++p) {
if (p->index_ == Label::kNoIndex && prev_index != Label::kNoIndex) {
int index = prev_index - 1;
if (index >= 0 && available_.at(index)) {
p->index_ = index;
available_.at(index) = false;
++count;
}
}
prev_index = p->index_;
}
VLOG(1) << " fill backward " << count;
}
void LabelManager::SimpleIndexAssigner::DoInFill() {
size_t count = 0;
int index = 0;
for (Label& label : *labels_) {
if (label.index_ == Label::kNoIndex) {
while (!available_.at(index))
++index;
label.index_ = index;
available_.at(index) = false;
++index;
++count;
}
}
VLOG(1) << " infill " << count;
}
LabelManager::LabelManager() = default;
LabelManager::~LabelManager() = default;
// static
int LabelManager::GetLabelIndexBound(const LabelVector& labels) {
int max_index = -1;
for (const Label& label : labels) {
if (label.index_ != Label::kNoIndex)
max_index = std::max(max_index, label.index_);
}
return max_index + 1;
}
// Uses binary search to find |rva|.
Label* LabelManager::Find(RVA rva) {
auto it = std::lower_bound(
labels_.begin(), labels_.end(), Label(rva),
[](const Label& l1, const Label& l2) { return l1.rva_ < l2.rva_; });
return it == labels_.end() || it->rva_ != rva ? nullptr : &(*it);
}
void LabelManager::UnassignIndexes() {
for (Label& label : labels_)
label.index_ = Label::kNoIndex;
}
void LabelManager::DefaultAssignIndexes() {
int cur_index = 0;
for (Label& label : labels_) {
CHECK_EQ(Label::kNoIndex, label.index_);
label.index_ = cur_index++;
}
}
void LabelManager::AssignRemainingIndexes() {
// This adds some memory overhead, about 1 bit per Label (more if indexes >=
// |labels_.size()| get used).
SimpleIndexAssigner assigner(&labels_);
assigner.DoForwardFill();
assigner.DoBackwardFill();
assigner.DoInFill();
}
// We wish to minimize peak memory usage here. Analysis: Let
// m = number of (RVA) elements in |rva_visitor|,
// n = number of distinct (RVA) elements in |rva_visitor|.
// The final storage is n * sizeof(Label) bytes. During computation we uniquify
// m RVAs, and count repeats. Taking sizeof(RVA) = 4, an implementation using
// std::map or std::unordered_map would consume additionally 32 * n bytes.
// Meanwhile, our std::vector implementation consumes additionally 4 * m bytes
// For our typical usage (i.e. Chrome) we see m = ~4n, so we use 16 * n bytes of
// extra contiguous memory during computation. Assuming memory fragmentation
// would not be an issue, this is much better than using std::map.
void LabelManager::Read(RvaVisitor* rva_visitor) {
// Write all values in |rva_visitor| to |rvas|.
size_t num_rva = rva_visitor->Remaining();
std::vector<RVA> rvas(num_rva);
for (size_t i = 0; i < num_rva; ++i, rva_visitor->Next())
rvas[i] = rva_visitor->Get();
// Sort |rvas|, then count the number of distinct values.
using CRV = ConsecutiveRangeVisitor<std::vector<RVA>::iterator>;
std::sort(rvas.begin(), rvas.end());
DCHECK(rvas.empty() || rvas.back() != kUnassignedRVA);
size_t num_distinct_rva = 0;
for (CRV it(rvas.begin(), rvas.end()); it.has_more(); it.advance())
++num_distinct_rva;
// Reserve space for |labels_|, populate with sorted RVA and repeats.
DCHECK(labels_.empty());
labels_.reserve(num_distinct_rva);
for (CRV it(rvas.begin(), rvas.end()); it.has_more(); it.advance()) {
labels_.push_back(Label(*it.cur()));
labels_.back().count_ =
base::checked_cast<decltype(labels_.back().count_)>(it.repeat());
}
}
} // namespace courgette