aboutsummaryrefslogtreecommitdiff
path: root/src/support/lockedpool.cpp
diff options
context:
space:
mode:
authorMartin Ankerl <Martin.Ankerl@gmail.com>2017-12-29 11:36:11 +0100
committerMartin Ankerl <Martin.Ankerl@gmail.com>2017-12-29 11:36:11 +0100
commit1e0ee9095ce87a3cee0b44a120f6297ac672f5d0 (patch)
tree36ac4110adf4859e426474a24cad4a7a69d4bad7 /src/support/lockedpool.cpp
parent5180a86c96bc05d2a731f70f36aae28ab5a3fad4 (diff)
Use best-fit strategy in Arena, now O(log(n)) instead O(n)
This replaces the first-fit algorithm used in the Arena with a best-fit. According to "Dynamic Storage Allocation: A Survey and Critical Review", Wilson et. al. 1995, http://www.scs.stanford.edu/14wi-cs140/sched/readings/wilson.pdf, both startegies work well in practice. The advantage of using best-fit is that we can switch the slow O(n) algorithm to O(log(n)) operations. Additionally, some previously O(log(n)) operations are now replaced with O(1) operations by using a hash map. The end effect is that the benchmark runs about 2.5 times faster on my machine: old: BenchLockedPool, 5, 530, 5.25749, 0.00196938, 0.00199755, 0.00198172 new: BenchLockedPool, 5, 1300, 5.11313, 0.000781493, 0.000793314, 0.00078606 I've run all unit tests and benchmarks.
Diffstat (limited to 'src/support/lockedpool.cpp')
-rw-r--r--src/support/lockedpool.cpp70
1 files changed, 45 insertions, 25 deletions
diff --git a/src/support/lockedpool.cpp b/src/support/lockedpool.cpp
index 98e8694181..ddb84b6523 100644
--- a/src/support/lockedpool.cpp
+++ b/src/support/lockedpool.cpp
@@ -47,7 +47,9 @@ Arena::Arena(void *base_in, size_t size_in, size_t alignment_in):
base(static_cast<char*>(base_in)), end(static_cast<char*>(base_in) + size_in), alignment(alignment_in)
{
// Start with one free chunk that covers the entire arena
- chunks_free.emplace(base, size_in);
+ auto it = size_to_free_chunk.emplace(size_in, base);
+ chunks_free.emplace(base, it);
+ chunks_free_end.emplace(base + size_in, it);
}
Arena::~Arena()
@@ -63,26 +65,30 @@ void* Arena::alloc(size_t size)
if (size == 0)
return nullptr;
- // Pick a large enough free-chunk
- auto it = std::find_if(chunks_free.begin(), chunks_free.end(),
- [=](const std::map<char*, size_t>::value_type& chunk){ return chunk.second >= size; });
- if (it == chunks_free.end())
+ // Pick a large enough free-chunk. Returns an iterator pointing to the first element that is not less than key.
+ // This allocation strategy is best-fit. According to "Dynamic Storage Allocation: A Survey and Critical Review",
+ // Wilson et. al. 1995, http://www.scs.stanford.edu/14wi-cs140/sched/readings/wilson.pdf, best-fit and first-fit
+ // policies seem to work well in practice.
+ auto sizePtrIt = size_to_free_chunk.lower_bound(size);
+ if (sizePtrIt == size_to_free_chunk.end())
return nullptr;
// Create the used-chunk, taking its space from the end of the free-chunk
- auto alloced = chunks_used.emplace(it->first + it->second - size, size).first;
- if (!(it->second -= size))
- chunks_free.erase(it);
- return reinterpret_cast<void*>(alloced->first);
-}
-
-/* extend the Iterator if other begins at its end */
-template <class Iterator, class Pair> bool extend(Iterator it, const Pair& other) {
- if (it->first + it->second == other.first) {
- it->second += other.second;
- return true;
+ const size_t sizeRemaining = sizePtrIt->first - size;
+ auto alloced = chunks_used.emplace(sizePtrIt->second + sizeRemaining, size).first;
+ chunks_free_end.erase(sizePtrIt->second + sizePtrIt->first);
+ if (sizePtrIt->first == size) {
+ // whole chunk is used up
+ chunks_free.erase(sizePtrIt->second);
+ } else {
+ // still some memory left in the chunk
+ auto itRemaining = size_to_free_chunk.emplace(sizeRemaining, sizePtrIt->second);
+ chunks_free[sizePtrIt->second] = itRemaining;
+ chunks_free_end.emplace(sizePtrIt->second + sizeRemaining, itRemaining);
}
- return false;
+ size_to_free_chunk.erase(sizePtrIt);
+
+ return reinterpret_cast<void*>(alloced->first);
}
void Arena::free(void *ptr)
@@ -97,16 +103,30 @@ void Arena::free(void *ptr)
if (i == chunks_used.end()) {
throw std::runtime_error("Arena: invalid or double free");
}
- auto freed = *i;
+ std::pair<char*, size_t> freed = *i;
chunks_used.erase(i);
- // Add space to free map, coalescing contiguous chunks
- auto next = chunks_free.upper_bound(freed.first);
- auto prev = (next == chunks_free.begin()) ? chunks_free.end() : std::prev(next);
- if (prev == chunks_free.end() || !extend(prev, freed))
- prev = chunks_free.emplace_hint(next, freed);
- if (next != chunks_free.end() && extend(prev, *next))
+ // Coalesc freed with previous chunk
+ auto prev = chunks_free_end.find(freed.first);
+ if (prev != chunks_free_end.end()) {
+ freed.first -= prev->second->first;
+ freed.second += prev->second->first;
+ size_to_free_chunk.erase(prev->second);
+ chunks_free_end.erase(prev);
+ }
+
+ // Coalesc freed with chunk after freed
+ auto next = chunks_free.find(freed.first + freed.second);
+ if (next != chunks_free.end()) {
+ freed.second += next->second->first;
+ size_to_free_chunk.erase(next->second);
chunks_free.erase(next);
+ }
+
+ // Add/set space with coalesced free chunk
+ auto it = size_to_free_chunk.emplace(freed.second, freed.first);
+ chunks_free[freed.first] = it;
+ chunks_free_end[freed.first + freed.second] = it;
}
Arena::Stats Arena::stats() const
@@ -115,7 +135,7 @@ Arena::Stats Arena::stats() const
for (const auto& chunk: chunks_used)
r.used += chunk.second;
for (const auto& chunk: chunks_free)
- r.free += chunk.second;
+ r.free += chunk.second->first;
r.total = r.used + r.free;
return r;
}