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tracy/client/tracy_rpmalloc.cpp
Bartosz Taudul 6db581ff4e Suppress warning.
2020-08-11 23:25:23 +02:00

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#ifdef TRACY_ENABLE
/* rpmalloc.c - Memory allocator - Public Domain - 2016 Mattias Jansson
*
* This library provides a cross-platform lock free thread caching malloc implementation in C11.
* The latest source code is always available at
*
* https://github.com/mjansson/rpmalloc
*
* This library is put in the public domain; you can redistribute it and/or modify it without any restrictions.
*
*/
#include "tracy_rpmalloc.hpp"
/// Build time configurable limits
#ifndef HEAP_ARRAY_SIZE
//! Size of heap hashmap
#define HEAP_ARRAY_SIZE 47
#endif
#ifndef ENABLE_THREAD_CACHE
//! Enable per-thread cache
#define ENABLE_THREAD_CACHE 1
#endif
#ifndef ENABLE_GLOBAL_CACHE
//! Enable global cache shared between all threads, requires thread cache
#define ENABLE_GLOBAL_CACHE 1
#endif
#ifndef ENABLE_VALIDATE_ARGS
//! Enable validation of args to public entry points
#define ENABLE_VALIDATE_ARGS 0
#endif
#ifndef ENABLE_STATISTICS
//! Enable statistics collection
#define ENABLE_STATISTICS 0
#endif
#ifndef ENABLE_ASSERTS
//! Enable asserts
#define ENABLE_ASSERTS 0
#endif
#ifndef ENABLE_OVERRIDE
//! Override standard library malloc/free and new/delete entry points
#define ENABLE_OVERRIDE 0
#endif
#ifndef ENABLE_PRELOAD
//! Support preloading
#define ENABLE_PRELOAD 0
#endif
#ifndef DISABLE_UNMAP
//! Disable unmapping memory pages
#define DISABLE_UNMAP 0
#endif
#ifndef DEFAULT_SPAN_MAP_COUNT
//! Default number of spans to map in call to map more virtual memory (default values yield 4MiB here)
#define DEFAULT_SPAN_MAP_COUNT 64
#endif
#if ENABLE_THREAD_CACHE
#ifndef ENABLE_UNLIMITED_CACHE
//! Unlimited thread and global cache
#define ENABLE_UNLIMITED_CACHE 0
#endif
#ifndef ENABLE_UNLIMITED_THREAD_CACHE
//! Unlimited cache disables any thread cache limitations
#define ENABLE_UNLIMITED_THREAD_CACHE ENABLE_UNLIMITED_CACHE
#endif
#if !ENABLE_UNLIMITED_THREAD_CACHE
#ifndef THREAD_CACHE_MULTIPLIER
//! Multiplier for thread cache (cache limit will be span release count multiplied by this value)
#define THREAD_CACHE_MULTIPLIER 16
#endif
#ifndef ENABLE_ADAPTIVE_THREAD_CACHE
//! Enable adaptive size of per-thread cache (still bounded by THREAD_CACHE_MULTIPLIER hard limit)
#define ENABLE_ADAPTIVE_THREAD_CACHE 0
#endif
#endif
#endif
#if ENABLE_GLOBAL_CACHE && ENABLE_THREAD_CACHE
#ifndef ENABLE_UNLIMITED_GLOBAL_CACHE
//! Unlimited cache disables any global cache limitations
#define ENABLE_UNLIMITED_GLOBAL_CACHE ENABLE_UNLIMITED_CACHE
#endif
#if !ENABLE_UNLIMITED_GLOBAL_CACHE
//! Multiplier for global cache (cache limit will be span release count multiplied by this value)
#define GLOBAL_CACHE_MULTIPLIER (THREAD_CACHE_MULTIPLIER * 6)
#endif
#else
# undef ENABLE_GLOBAL_CACHE
# define ENABLE_GLOBAL_CACHE 0
#endif
#if !ENABLE_THREAD_CACHE || ENABLE_UNLIMITED_THREAD_CACHE
# undef ENABLE_ADAPTIVE_THREAD_CACHE
# define ENABLE_ADAPTIVE_THREAD_CACHE 0
#endif
#if DISABLE_UNMAP && !ENABLE_GLOBAL_CACHE
# error Must use global cache if unmap is disabled
#endif
#if defined( _WIN32 ) || defined( __WIN32__ ) || defined( _WIN64 )
# define PLATFORM_WINDOWS 1
# define PLATFORM_POSIX 0
#else
# define PLATFORM_WINDOWS 0
# define PLATFORM_POSIX 1
#endif
#define _Static_assert static_assert
/// Platform and arch specifics
#ifndef FORCEINLINE
# if defined(_MSC_VER) && !defined(__clang__)
# define FORCEINLINE inline __forceinline
# else
# define FORCEINLINE inline __attribute__((__always_inline__))
# endif
#endif
#if PLATFORM_WINDOWS
# ifndef WIN32_LEAN_AND_MEAN
# define WIN32_LEAN_AND_MEAN
# endif
# include <windows.h>
# if ENABLE_VALIDATE_ARGS
# include <Intsafe.h>
# endif
#else
# include <unistd.h>
# include <stdio.h>
# include <stdlib.h>
# if defined(__APPLE__)
# include <mach/mach_vm.h>
# include <mach/vm_statistics.h>
# include <pthread.h>
# endif
# if defined(__HAIKU__)
# include <OS.h>
# include <pthread.h>
# endif
#endif
#include <stdint.h>
#include <string.h>
#if ENABLE_ASSERTS
# undef NDEBUG
# if defined(_MSC_VER) && !defined(_DEBUG)
# define _DEBUG
# endif
# include <assert.h>
#else
# undef assert
# define assert(x) do {} while(0)
#endif
#if ENABLE_STATISTICS
# include <stdio.h>
#endif
#include <atomic>
namespace tracy
{
typedef std::atomic<int32_t> atomic32_t;
typedef std::atomic<int64_t> atomic64_t;
typedef std::atomic<void*> atomicptr_t;
#define atomic_thread_fence_acquire() std::atomic_thread_fence(std::memory_order_acquire)
#define atomic_thread_fence_release() std::atomic_thread_fence(std::memory_order_release)
static FORCEINLINE int32_t atomic_load32(atomic32_t* src) { return std::atomic_load_explicit(src, std::memory_order_relaxed); }
static FORCEINLINE void atomic_store32(atomic32_t* dst, int32_t val) { std::atomic_store_explicit(dst, val, std::memory_order_relaxed); }
static FORCEINLINE int32_t atomic_incr32(atomic32_t* val) { return std::atomic_fetch_add_explicit(val, 1, std::memory_order_relaxed) + 1; }
#if ENABLE_STATISTICS || ENABLE_ADAPTIVE_THREAD_CACHE
static FORCEINLINE int32_t atomic_decr32(atomic32_t* val) { return atomic_fetch_add_explicit(val, -1, memory_order_relaxed) - 1; }
#endif
static FORCEINLINE int32_t atomic_add32(atomic32_t* val, int32_t add) { return std::atomic_fetch_add_explicit(val, add, std::memory_order_relaxed) + add; }
static FORCEINLINE void* atomic_load_ptr(atomicptr_t* src) { return std::atomic_load_explicit(src, std::memory_order_relaxed); }
static FORCEINLINE void atomic_store_ptr(atomicptr_t* dst, void* val) { std::atomic_store_explicit(dst, val, std::memory_order_relaxed); }
static FORCEINLINE int atomic_cas_ptr(atomicptr_t* dst, void* val, void* ref) { return std::atomic_compare_exchange_weak_explicit(dst, &ref, val, std::memory_order_release, std::memory_order_acquire); }
#if defined(_MSC_VER) && !defined(__clang__)
# define EXPECTED(x) (x)
# define UNEXPECTED(x) (x)
#else
# define EXPECTED(x) __builtin_expect((x), 1)
# define UNEXPECTED(x) __builtin_expect((x), 0)
#endif
/// Preconfigured limits and sizes
//! Granularity of a small allocation block
#define SMALL_GRANULARITY 16
//! Small granularity shift count
#define SMALL_GRANULARITY_SHIFT 4
//! Number of small block size classes
#define SMALL_CLASS_COUNT 65
//! Maximum size of a small block
#define SMALL_SIZE_LIMIT (SMALL_GRANULARITY * (SMALL_CLASS_COUNT - 1))
//! Granularity of a medium allocation block
#define MEDIUM_GRANULARITY 512
//! Medium granularity shift count
#define MEDIUM_GRANULARITY_SHIFT 9
//! Number of medium block size classes
#define MEDIUM_CLASS_COUNT 61
//! Total number of small + medium size classes
#define SIZE_CLASS_COUNT (SMALL_CLASS_COUNT + MEDIUM_CLASS_COUNT)
//! Number of large block size classes
#define LARGE_CLASS_COUNT 32
//! Maximum size of a medium block
#define MEDIUM_SIZE_LIMIT (SMALL_SIZE_LIMIT + (MEDIUM_GRANULARITY * MEDIUM_CLASS_COUNT))
//! Maximum size of a large block
#define LARGE_SIZE_LIMIT ((LARGE_CLASS_COUNT * _memory_span_size) - SPAN_HEADER_SIZE)
//! Size of a span header (must be a multiple of SMALL_GRANULARITY)
#define SPAN_HEADER_SIZE 96
#if ENABLE_VALIDATE_ARGS
//! Maximum allocation size to avoid integer overflow
#undef MAX_ALLOC_SIZE
#define MAX_ALLOC_SIZE (((size_t)-1) - _memory_span_size)
#endif
#define pointer_offset(ptr, ofs) (void*)((char*)(ptr) + (ptrdiff_t)(ofs))
#define pointer_diff(first, second) (ptrdiff_t)((const char*)(first) - (const char*)(second))
#define INVALID_POINTER ((void*)((uintptr_t)-1))
/// Data types
//! A memory heap, per thread
typedef struct heap_t heap_t;
//! Heap spans per size class
typedef struct heap_class_t heap_class_t;
//! Span of memory pages
typedef struct span_t span_t;
//! Span list
typedef struct span_list_t span_list_t;
//! Span active data
typedef struct span_active_t span_active_t;
//! Size class definition
typedef struct size_class_t size_class_t;
//! Global cache
typedef struct global_cache_t global_cache_t;
//! Flag indicating span is the first (master) span of a split superspan
#define SPAN_FLAG_MASTER 1U
//! Flag indicating span is a secondary (sub) span of a split superspan
#define SPAN_FLAG_SUBSPAN 2U
//! Flag indicating span has blocks with increased alignment
#define SPAN_FLAG_ALIGNED_BLOCKS 4U
#if ENABLE_ADAPTIVE_THREAD_CACHE || ENABLE_STATISTICS
struct span_use_t {
//! Current number of spans used (actually used, not in cache)
atomic32_t current;
//! High water mark of spans used
uint32_t high;
#if ENABLE_STATISTICS
//! Number of spans transitioned to global cache
uint32_t spans_to_global;
//! Number of spans transitioned from global cache
uint32_t spans_from_global;
//! Number of spans transitioned to thread cache
uint32_t spans_to_cache;
//! Number of spans transitioned from thread cache
uint32_t spans_from_cache;
//! Number of spans transitioned to reserved state
uint32_t spans_to_reserved;
//! Number of spans transitioned from reserved state
uint32_t spans_from_reserved;
//! Number of raw memory map calls
uint32_t spans_map_calls;
#endif
};
typedef struct span_use_t span_use_t;
#endif
#if ENABLE_STATISTICS
struct size_class_use_t {
//! Current number of allocations
atomic32_t alloc_current;
//! Peak number of allocations
int32_t alloc_peak;
//! Total number of allocations
int32_t alloc_total;
//! Total number of frees
atomic32_t free_total;
//! Number of spans in use
uint32_t spans_current;
//! Number of spans transitioned to cache
uint32_t spans_peak;
//! Number of spans transitioned to cache
uint32_t spans_to_cache;
//! Number of spans transitioned from cache
uint32_t spans_from_cache;
//! Number of spans transitioned from reserved state
uint32_t spans_from_reserved;
//! Number of spans mapped
uint32_t spans_map_calls;
};
typedef struct size_class_use_t size_class_use_t;
#endif
typedef enum span_state_t {
SPAN_STATE_ACTIVE = 0,
SPAN_STATE_PARTIAL,
SPAN_STATE_FULL
} span_state_t;
//A span can either represent a single span of memory pages with size declared by span_map_count configuration variable,
//or a set of spans in a continuous region, a super span. Any reference to the term "span" usually refers to both a single
//span or a super span. A super span can further be divided into multiple spans (or this, super spans), where the first
//(super)span is the master and subsequent (super)spans are subspans. The master span keeps track of how many subspans
//that are still alive and mapped in virtual memory, and once all subspans and master have been unmapped the entire
//superspan region is released and unmapped (on Windows for example, the entire superspan range has to be released
//in the same call to release the virtual memory range, but individual subranges can be decommitted individually
//to reduce physical memory use).
struct span_t {
//! Free list
void* free_list;
//! State
uint32_t state;
//! Used count when not active (not including deferred free list)
uint32_t used_count;
//! Block count
uint32_t block_count;
//! Size class
uint32_t size_class;
//! Index of last block initialized in free list
uint32_t free_list_limit;
//! Span list size when part of a cache list, or size of deferred free list when partial/full
uint32_t list_size;
//! Deferred free list
atomicptr_t free_list_deferred;
//! Size of a block
uint32_t block_size;
//! Flags and counters
uint32_t flags;
//! Number of spans
uint32_t span_count;
//! Total span counter for master spans, distance for subspans
uint32_t total_spans_or_distance;
//! Remaining span counter, for master spans
atomic32_t remaining_spans;
//! Alignment offset
uint32_t align_offset;
//! Owning heap
heap_t* heap;
//! Next span
span_t* next;
//! Previous span
span_t* prev;
};
_Static_assert(sizeof(span_t) <= SPAN_HEADER_SIZE, "span size mismatch");
struct heap_class_t {
//! Free list of active span
void* free_list;
//! Double linked list of partially used spans with free blocks for each size class.
// Current active span is at head of list. Previous span pointer in head points to tail span of list.
span_t* partial_span;
};
struct heap_t {
//! Active and semi-used span data per size class
heap_class_t span_class[SIZE_CLASS_COUNT];
#if ENABLE_THREAD_CACHE
//! List of free spans (single linked list)
span_t* span_cache[LARGE_CLASS_COUNT];
//! List of deferred free spans of class 0 (single linked list)
atomicptr_t span_cache_deferred;
#endif
#if ENABLE_ADAPTIVE_THREAD_CACHE || ENABLE_STATISTICS
//! Current and high water mark of spans used per span count
span_use_t span_use[LARGE_CLASS_COUNT];
#endif
//! Mapped but unused spans
span_t* span_reserve;
//! Master span for mapped but unused spans
span_t* span_reserve_master;
//! Number of mapped but unused spans
size_t spans_reserved;
//! Next heap in id list
heap_t* next_heap;
//! Next heap in orphan list
heap_t* next_orphan;
//! Memory pages alignment offset
size_t align_offset;
//! Heap ID
int32_t id;
#if ENABLE_STATISTICS
//! Number of bytes transitioned thread -> global
size_t thread_to_global;
//! Number of bytes transitioned global -> thread
size_t global_to_thread;
//! Allocation stats per size class
size_class_use_t size_class_use[SIZE_CLASS_COUNT + 1];
#endif
};
struct size_class_t {
//! Size of blocks in this class
uint32_t block_size;
//! Number of blocks in each chunk
uint16_t block_count;
//! Class index this class is merged with
uint16_t class_idx;
};
_Static_assert(sizeof(size_class_t) == 8, "Size class size mismatch");
struct global_cache_t {
//! Cache list pointer
atomicptr_t cache;
//! Cache size
atomic32_t size;
//! ABA counter
atomic32_t counter;
};
/// Global data
//! Initialized flag
static int _rpmalloc_initialized;
//! Configuration
static rpmalloc_config_t _memory_config;
//! Memory page size
static size_t _memory_page_size;
//! Shift to divide by page size
static size_t _memory_page_size_shift;
//! Granularity at which memory pages are mapped by OS
static size_t _memory_map_granularity;
#if RPMALLOC_CONFIGURABLE
//! Size of a span of memory pages
static size_t _memory_span_size;
//! Shift to divide by span size
static size_t _memory_span_size_shift;
//! Mask to get to start of a memory span
static uintptr_t _memory_span_mask;
#else
//! Hardwired span size (64KiB)
#define _memory_span_size (64 * 1024)
#define _memory_span_size_shift 16
#define _memory_span_mask (~((uintptr_t)(_memory_span_size - 1)))
#endif
//! Number of spans to map in each map call
static size_t _memory_span_map_count;
//! Number of spans to release from thread cache to global cache (single spans)
static size_t _memory_span_release_count;
//! Number of spans to release from thread cache to global cache (large multiple spans)
static size_t _memory_span_release_count_large;
//! Global size classes
static size_class_t _memory_size_class[SIZE_CLASS_COUNT];
//! Run-time size limit of medium blocks
static size_t _memory_medium_size_limit;
//! Heap ID counter
static atomic32_t _memory_heap_id;
//! Huge page support
static int _memory_huge_pages;
#if ENABLE_GLOBAL_CACHE
//! Global span cache
static global_cache_t _memory_span_cache[LARGE_CLASS_COUNT];
#endif
//! All heaps
static atomicptr_t _memory_heaps[HEAP_ARRAY_SIZE];
//! Orphaned heaps
static atomicptr_t _memory_orphan_heaps;
//! Running orphan counter to avoid ABA issues in linked list
static atomic32_t _memory_orphan_counter;
#if ENABLE_STATISTICS
//! Active heap count
static atomic32_t _memory_active_heaps;
//! Number of currently mapped memory pages
static atomic32_t _mapped_pages;
//! Peak number of concurrently mapped memory pages
static int32_t _mapped_pages_peak;
//! Number of currently unused spans
static atomic32_t _reserved_spans;
//! Running counter of total number of mapped memory pages since start
static atomic32_t _mapped_total;
//! Running counter of total number of unmapped memory pages since start
static atomic32_t _unmapped_total;
//! Number of currently mapped memory pages in OS calls
static atomic32_t _mapped_pages_os;
//! Number of currently allocated pages in huge allocations
static atomic32_t _huge_pages_current;
//! Peak number of currently allocated pages in huge allocations
static int32_t _huge_pages_peak;
#endif
//! Current thread heap
#if (defined(__APPLE__) || defined(__HAIKU__)) && ENABLE_PRELOAD
static pthread_key_t _memory_thread_heap;
#else
# ifdef _MSC_VER
# define _Thread_local __declspec(thread)
# define TLS_MODEL
# else
# define TLS_MODEL __attribute__((tls_model("initial-exec")))
# if !defined(__clang__) && defined(__GNUC__)
# define _Thread_local __thread
# endif
# endif
static _Thread_local heap_t* _memory_thread_heap TLS_MODEL;
#endif
static inline heap_t*
get_thread_heap_raw(void) {
#if (defined(__APPLE__) || defined(__HAIKU__)) && ENABLE_PRELOAD
return pthread_getspecific(_memory_thread_heap);
#else
return _memory_thread_heap;
#endif
}
//! Get the current thread heap
static inline heap_t*
get_thread_heap(void) {
heap_t* heap = get_thread_heap_raw();
#if ENABLE_PRELOAD
if (EXPECTED(heap != 0))
return heap;
rpmalloc_initialize();
return get_thread_heap_raw();
#else
return heap;
#endif
}
//! Set the current thread heap
static void
set_thread_heap(heap_t* heap) {
#if (defined(__APPLE__) || defined(__HAIKU__)) && ENABLE_PRELOAD
pthread_setspecific(_memory_thread_heap, heap);
#else
_memory_thread_heap = heap;
#endif
}
//! Default implementation to map more virtual memory
static void*
_memory_map_os(size_t size, size_t* offset);
//! Default implementation to unmap virtual memory
static void
_memory_unmap_os(void* address, size_t size, size_t offset, size_t release);
//! Lookup a memory heap from heap ID
static heap_t*
_memory_heap_lookup(int32_t id) {
uint32_t list_idx = id % HEAP_ARRAY_SIZE;
heap_t* heap = (heap_t*)atomic_load_ptr(&_memory_heaps[list_idx]);
while (heap && (heap->id != id))
heap = heap->next_heap;
return heap;
}
#if ENABLE_STATISTICS
# define _memory_statistics_inc(counter, value) counter += value
# define _memory_statistics_dec(counter, value) counter -= value
# define _memory_statistics_add(atomic_counter, value) atomic_add32(atomic_counter, (int32_t)(value))
# define _memory_statistics_add_peak(atomic_counter, value, peak) do { int32_t _cur_count = atomic_add32(atomic_counter, (int32_t)(value)); if (_cur_count > (peak)) peak = _cur_count; } while (0)
# define _memory_statistics_sub(atomic_counter, value) atomic_add32(atomic_counter, -(int32_t)(value))
# define _memory_statistics_inc_alloc(heap, class_idx) do { \
int32_t alloc_current = atomic_incr32(&heap->size_class_use[class_idx].alloc_current); \
if (alloc_current > heap->size_class_use[class_idx].alloc_peak) \
heap->size_class_use[class_idx].alloc_peak = alloc_current; \
heap->size_class_use[class_idx].alloc_total++; \
} while(0)
# define _memory_statistics_inc_free(heap, class_idx) do { \
atomic_decr32(&heap->size_class_use[class_idx].alloc_current); \
atomic_incr32(&heap->size_class_use[class_idx].free_total); \
} while(0)
#else
# define _memory_statistics_inc(counter, value) do {} while(0)
# define _memory_statistics_dec(counter, value) do {} while(0)
# define _memory_statistics_add(atomic_counter, value) do {} while(0)
# define _memory_statistics_add_peak(atomic_counter, value, peak) do {} while (0)
# define _memory_statistics_sub(atomic_counter, value) do {} while(0)
# define _memory_statistics_inc_alloc(heap, class_idx) do {} while(0)
# define _memory_statistics_inc_free(heap, class_idx) do {} while(0)
#endif
static void
_memory_heap_cache_insert(heap_t* heap, span_t* span);
//! Map more virtual memory
static void*
_memory_map(size_t size, size_t* offset) {
assert(!(size % _memory_page_size));
assert(size >= _memory_page_size);
_memory_statistics_add_peak(&_mapped_pages, (size >> _memory_page_size_shift), _mapped_pages_peak);
_memory_statistics_add(&_mapped_total, (size >> _memory_page_size_shift));
return _memory_config.memory_map(size, offset);
}
//! Unmap virtual memory
static void
_memory_unmap(void* address, size_t size, size_t offset, size_t release) {
assert(!release || (release >= size));
assert(!release || (release >= _memory_page_size));
if (release) {
assert(!(release % _memory_page_size));
_memory_statistics_sub(&_mapped_pages, (release >> _memory_page_size_shift));
_memory_statistics_add(&_unmapped_total, (release >> _memory_page_size_shift));
}
_memory_config.memory_unmap(address, size, offset, release);
}
//! Declare the span to be a subspan and store distance from master span and span count
static void
_memory_span_mark_as_subspan_unless_master(span_t* master, span_t* subspan, size_t span_count) {
assert((subspan != master) || (subspan->flags & SPAN_FLAG_MASTER));
if (subspan != master) {
subspan->flags = SPAN_FLAG_SUBSPAN;
subspan->total_spans_or_distance = (uint32_t)((uintptr_t)pointer_diff(subspan, master) >> _memory_span_size_shift);
subspan->align_offset = 0;
}
subspan->span_count = (uint32_t)span_count;
}
//! Use reserved spans to fulfill a memory map request (reserve size must be checked by caller)
static span_t*
_memory_map_from_reserve(heap_t* heap, size_t span_count) {
//Update the heap span reserve
span_t* span = heap->span_reserve;
heap->span_reserve = (span_t*)pointer_offset(span, span_count * _memory_span_size);
heap->spans_reserved -= span_count;
_memory_span_mark_as_subspan_unless_master(heap->span_reserve_master, span, span_count);
if (span_count <= LARGE_CLASS_COUNT)
_memory_statistics_inc(heap->span_use[span_count - 1].spans_from_reserved, 1);
return span;
}
//! Get the aligned number of spans to map in based on wanted count, configured mapping granularity and the page size
static size_t
_memory_map_align_span_count(size_t span_count) {
size_t request_count = (span_count > _memory_span_map_count) ? span_count : _memory_span_map_count;
if ((_memory_page_size > _memory_span_size) && ((request_count * _memory_span_size) % _memory_page_size))
request_count += _memory_span_map_count - (request_count % _memory_span_map_count);
return request_count;
}
//! Store the given spans as reserve in the given heap
static void
_memory_heap_set_reserved_spans(heap_t* heap, span_t* master, span_t* reserve, size_t reserve_span_count) {
heap->span_reserve_master = master;
heap->span_reserve = reserve;
heap->spans_reserved = reserve_span_count;
}
//! Setup a newly mapped span
static void
_memory_span_initialize(span_t* span, size_t total_span_count, size_t span_count, size_t align_offset) {
span->total_spans_or_distance = (uint32_t)total_span_count;
span->span_count = (uint32_t)span_count;
span->align_offset = (uint32_t)align_offset;
span->flags = SPAN_FLAG_MASTER;
atomic_store32(&span->remaining_spans, (int32_t)total_span_count);
}
//! Map a akigned set of spans, taking configured mapping granularity and the page size into account
static span_t*
_memory_map_aligned_span_count(heap_t* heap, size_t span_count) {
//If we already have some, but not enough, reserved spans, release those to heap cache and map a new
//full set of spans. Otherwise we would waste memory if page size > span size (huge pages)
size_t aligned_span_count = _memory_map_align_span_count(span_count);
size_t align_offset = 0;
span_t* span = (span_t*)_memory_map(aligned_span_count * _memory_span_size, &align_offset);
if (!span)
return 0;
_memory_span_initialize(span, aligned_span_count, span_count, align_offset);
_memory_statistics_add(&_reserved_spans, aligned_span_count);
if (span_count <= LARGE_CLASS_COUNT)
_memory_statistics_inc(heap->span_use[span_count - 1].spans_map_calls, 1);
if (aligned_span_count > span_count) {
if (heap->spans_reserved) {
_memory_span_mark_as_subspan_unless_master(heap->span_reserve_master, heap->span_reserve, heap->spans_reserved);
_memory_heap_cache_insert(heap, heap->span_reserve);
}
_memory_heap_set_reserved_spans(heap, span, (span_t*)pointer_offset(span, span_count * _memory_span_size), aligned_span_count - span_count);
}
return span;
}
//! Map in memory pages for the given number of spans (or use previously reserved pages)
static span_t*
_memory_map_spans(heap_t* heap, size_t span_count) {
if (span_count <= heap->spans_reserved)
return _memory_map_from_reserve(heap, span_count);
return _memory_map_aligned_span_count(heap, span_count);
}
//! Unmap memory pages for the given number of spans (or mark as unused if no partial unmappings)
static void
_memory_unmap_span(span_t* span) {
assert((span->flags & SPAN_FLAG_MASTER) || (span->flags & SPAN_FLAG_SUBSPAN));
assert(!(span->flags & SPAN_FLAG_MASTER) || !(span->flags & SPAN_FLAG_SUBSPAN));
int is_master = !!(span->flags & SPAN_FLAG_MASTER);
span_t* master = is_master ? span : (span_t*)(pointer_offset(span, -(int32_t)(span->total_spans_or_distance * _memory_span_size)));
assert(is_master || (span->flags & SPAN_FLAG_SUBSPAN));
assert(master->flags & SPAN_FLAG_MASTER);
size_t span_count = span->span_count;
if (!is_master) {
//Directly unmap subspans (unless huge pages, in which case we defer and unmap entire page range with master)
assert(span->align_offset == 0);
if (_memory_span_size >= _memory_page_size) {
_memory_unmap(span, span_count * _memory_span_size, 0, 0);
_memory_statistics_sub(&_reserved_spans, span_count);
}
} else {
//Special double flag to denote an unmapped master
//It must be kept in memory since span header must be used
span->flags |= SPAN_FLAG_MASTER | SPAN_FLAG_SUBSPAN;
}
if (atomic_add32(&master->remaining_spans, -(int32_t)span_count) <= 0) {
//Everything unmapped, unmap the master span with release flag to unmap the entire range of the super span
assert(!!(master->flags & SPAN_FLAG_MASTER) && !!(master->flags & SPAN_FLAG_SUBSPAN));
size_t unmap_count = master->span_count;
if (_memory_span_size < _memory_page_size)
unmap_count = master->total_spans_or_distance;
_memory_statistics_sub(&_reserved_spans, unmap_count);
_memory_unmap(master, unmap_count * _memory_span_size, master->align_offset, master->total_spans_or_distance * _memory_span_size);
}
}
#if ENABLE_THREAD_CACHE
//! Unmap a single linked list of spans
static void
_memory_unmap_span_list(span_t* span) {
size_t list_size = span->list_size;
for (size_t ispan = 0; ispan < list_size; ++ispan) {
span_t* next_span = span->next;
_memory_unmap_span(span);
span = next_span;
}
assert(!span);
}
//! Add span to head of single linked span list
static size_t
_memory_span_list_push(span_t** head, span_t* span) {
span->next = *head;
if (*head)
span->list_size = (*head)->list_size + 1;
else
span->list_size = 1;
*head = span;
return span->list_size;
}
//! Remove span from head of single linked span list, returns the new list head
static span_t*
_memory_span_list_pop(span_t** head) {
span_t* span = *head;
span_t* next_span = 0;
if (span->list_size > 1) {
assert(span->next);
next_span = span->next;
assert(next_span);
next_span->list_size = span->list_size - 1;
}
*head = next_span;
return span;
}
//! Split a single linked span list
static span_t*
_memory_span_list_split(span_t* span, size_t limit) {
span_t* next = 0;
if (limit < 2)
limit = 2;
if (span->list_size > limit) {
uint32_t list_size = 1;
span_t* last = span;
next = span->next;
while (list_size < limit) {
last = next;
next = next->next;
++list_size;
}
last->next = 0;
assert(next);
next->list_size = span->list_size - list_size;
span->list_size = list_size;
span->prev = 0;
}
return next;
}
#endif
//! Add a span to partial span double linked list at the head
static void
_memory_span_partial_list_add(span_t** head, span_t* span) {
if (*head) {
span->next = *head;
//Maintain pointer to tail span
span->prev = (*head)->prev;
(*head)->prev = span;
} else {
span->next = 0;
span->prev = span;
}
*head = span;
}
//! Add a span to partial span double linked list at the tail
static void
_memory_span_partial_list_add_tail(span_t** head, span_t* span) {
span->next = 0;
if (*head) {
span_t* tail = (*head)->prev;
tail->next = span;
span->prev = tail;
//Maintain pointer to tail span
(*head)->prev = span;
} else {
span->prev = span;
*head = span;
}
}
//! Pop head span from partial span double linked list
static void
_memory_span_partial_list_pop_head(span_t** head) {
span_t* span = *head;
*head = span->next;
if (*head) {
//Maintain pointer to tail span
(*head)->prev = span->prev;
}
}
//! Remove a span from partial span double linked list
static void
_memory_span_partial_list_remove(span_t** head, span_t* span) {
if (UNEXPECTED(*head == span)) {
_memory_span_partial_list_pop_head(head);
} else {
span_t* next_span = span->next;
span_t* prev_span = span->prev;
prev_span->next = next_span;
if (EXPECTED(next_span != 0)) {
next_span->prev = prev_span;
} else {
//Update pointer to tail span
(*head)->prev = prev_span;
}
}
}
#if ENABLE_GLOBAL_CACHE
//! Insert the given list of memory page spans in the global cache
static void
_memory_cache_insert(global_cache_t* cache, span_t* span, size_t cache_limit) {
assert((span->list_size == 1) || (span->next != 0));
int32_t list_size = (int32_t)span->list_size;
//Unmap if cache has reached the limit
if (atomic_add32(&cache->size, list_size) > (int32_t)cache_limit) {
#if !ENABLE_UNLIMITED_GLOBAL_CACHE
_memory_unmap_span_list(span);
atomic_add32(&cache->size, -list_size);
return;
#endif
}
void* current_cache, *new_cache;
do {
current_cache = atomic_load_ptr(&cache->cache);
span->prev = (span_t*)((uintptr_t)current_cache & _memory_span_mask);
new_cache = (void*)((uintptr_t)span | ((uintptr_t)atomic_incr32(&cache->counter) & ~_memory_span_mask));
} while (!atomic_cas_ptr(&cache->cache, new_cache, current_cache));
}
//! Extract a number of memory page spans from the global cache
static span_t*
_memory_cache_extract(global_cache_t* cache) {
uintptr_t span_ptr;
do {
void* global_span = atomic_load_ptr(&cache->cache);
span_ptr = (uintptr_t)global_span & _memory_span_mask;
if (span_ptr) {
span_t* span = (span_t*)span_ptr;
//By accessing the span ptr before it is swapped out of list we assume that a contending thread
//does not manage to traverse the span to being unmapped before we access it
void* new_cache = (void*)((uintptr_t)span->prev | ((uintptr_t)atomic_incr32(&cache->counter) & ~_memory_span_mask));
if (atomic_cas_ptr(&cache->cache, new_cache, global_span)) {
atomic_add32(&cache->size, -(int32_t)span->list_size);
return span;
}
}
} while (span_ptr);
return 0;
}
//! Finalize a global cache, only valid from allocator finalization (not thread safe)
static void
_memory_cache_finalize(global_cache_t* cache) {
void* current_cache = atomic_load_ptr(&cache->cache);
span_t* span = (span_t*)((uintptr_t)current_cache & _memory_span_mask);
while (span) {
span_t* skip_span = (span_t*)((uintptr_t)span->prev & _memory_span_mask);
atomic_add32(&cache->size, -(int32_t)span->list_size);
_memory_unmap_span_list(span);
span = skip_span;
}
assert(!atomic_load32(&cache->size));
atomic_store_ptr(&cache->cache, 0);
atomic_store32(&cache->size, 0);
}
//! Insert the given list of memory page spans in the global cache
static void
_memory_global_cache_insert(span_t* span) {
size_t span_count = span->span_count;
#if ENABLE_UNLIMITED_GLOBAL_CACHE
_memory_cache_insert(&_memory_span_cache[span_count - 1], span, 0);
#else
const size_t cache_limit = (GLOBAL_CACHE_MULTIPLIER * ((span_count == 1) ? _memory_span_release_count : _memory_span_release_count_large));
_memory_cache_insert(&_memory_span_cache[span_count - 1], span, cache_limit);
#endif
}
//! Extract a number of memory page spans from the global cache for large blocks
static span_t*
_memory_global_cache_extract(size_t span_count) {
span_t* span = _memory_cache_extract(&_memory_span_cache[span_count - 1]);
assert(!span || (span->span_count == span_count));
return span;
}
#endif
#if ENABLE_THREAD_CACHE
//! Adopt the deferred span cache list
static void
_memory_heap_cache_adopt_deferred(heap_t* heap) {
atomic_thread_fence_acquire();
span_t* span = (span_t*)atomic_load_ptr(&heap->span_cache_deferred);
if (!span)
return;
do {
span = (span_t*)atomic_load_ptr(&heap->span_cache_deferred);
} while (!atomic_cas_ptr(&heap->span_cache_deferred, 0, span));
while (span) {
span_t* next_span = span->next;
_memory_span_list_push(&heap->span_cache[0], span);
#if ENABLE_STATISTICS
atomic_decr32(&heap->span_use[span->span_count - 1].current);
++heap->size_class_use[span->size_class].spans_to_cache;
--heap->size_class_use[span->size_class].spans_current;
#endif
span = next_span;
}
}
#endif
//! Insert a single span into thread heap cache, releasing to global cache if overflow
static void
_memory_heap_cache_insert(heap_t* heap, span_t* span) {
#if ENABLE_THREAD_CACHE
size_t span_count = span->span_count;
size_t idx = span_count - 1;
_memory_statistics_inc(heap->span_use[idx].spans_to_cache, 1);
if (!idx)
_memory_heap_cache_adopt_deferred(heap);
#if ENABLE_UNLIMITED_THREAD_CACHE
_memory_span_list_push(&heap->span_cache[idx], span);
#else
const size_t release_count = (!idx ? _memory_span_release_count : _memory_span_release_count_large);
size_t current_cache_size = _memory_span_list_push(&heap->span_cache[idx], span);
if (current_cache_size <= release_count)
return;
const size_t hard_limit = release_count * THREAD_CACHE_MULTIPLIER;
if (current_cache_size <= hard_limit) {
#if ENABLE_ADAPTIVE_THREAD_CACHE
//Require 25% of high water mark to remain in cache (and at least 1, if use is 0)
const size_t high_mark = heap->span_use[idx].high;
const size_t min_limit = (high_mark >> 2) + release_count + 1;
if (current_cache_size < min_limit)
return;
#else
return;
#endif
}
heap->span_cache[idx] = _memory_span_list_split(span, release_count);
assert(span->list_size == release_count);
#if ENABLE_STATISTICS
heap->thread_to_global += (size_t)span->list_size * span_count * _memory_span_size;
heap->span_use[idx].spans_to_global += span->list_size;
#endif
#if ENABLE_GLOBAL_CACHE
_memory_global_cache_insert(span);
#else
_memory_unmap_span_list(span);
#endif
#endif
#else
(void)sizeof(heap);
_memory_unmap_span(span);
#endif
}
//! Extract the given number of spans from the different cache levels
static span_t*
_memory_heap_thread_cache_extract(heap_t* heap, size_t span_count) {
#if ENABLE_THREAD_CACHE
size_t idx = span_count - 1;
if (!idx)
_memory_heap_cache_adopt_deferred(heap);
if (heap->span_cache[idx]) {
#if ENABLE_STATISTICS
heap->span_use[idx].spans_from_cache++;
#endif
return _memory_span_list_pop(&heap->span_cache[idx]);
}
#endif
return 0;
}
static span_t*
_memory_heap_reserved_extract(heap_t* heap, size_t span_count) {
if (heap->spans_reserved >= span_count)
return _memory_map_spans(heap, span_count);
return 0;
}
//! Extract a span from the global cache
static span_t*
_memory_heap_global_cache_extract(heap_t* heap, size_t span_count) {
#if ENABLE_GLOBAL_CACHE
size_t idx = span_count - 1;
heap->span_cache[idx] = _memory_global_cache_extract(span_count);
if (heap->span_cache[idx]) {
#if ENABLE_STATISTICS
heap->global_to_thread += (size_t)heap->span_cache[idx]->list_size * span_count * _memory_span_size;
heap->span_use[idx].spans_from_global += heap->span_cache[idx]->list_size;
#endif
return _memory_span_list_pop(&heap->span_cache[idx]);
}
#endif
return 0;
}
//! Get a span from one of the cache levels (thread cache, reserved, global cache) or fallback to mapping more memory
static span_t*
_memory_heap_extract_new_span(heap_t* heap, size_t span_count, uint32_t class_idx) {
(void)sizeof(class_idx);
#if ENABLE_ADAPTIVE_THREAD_CACHE || ENABLE_STATISTICS
uint32_t idx = (uint32_t)span_count - 1;
uint32_t current_count = (uint32_t)atomic_incr32(&heap->span_use[idx].current);
if (current_count > heap->span_use[idx].high)
heap->span_use[idx].high = current_count;
#if ENABLE_STATISTICS
uint32_t spans_current = ++heap->size_class_use[class_idx].spans_current;
if (spans_current > heap->size_class_use[class_idx].spans_peak)
heap->size_class_use[class_idx].spans_peak = spans_current;
#endif
#endif
span_t* span = _memory_heap_thread_cache_extract(heap, span_count);
if (EXPECTED(span != 0)) {
_memory_statistics_inc(heap->size_class_use[class_idx].spans_from_cache, 1);
return span;
}
span = _memory_heap_reserved_extract(heap, span_count);
if (EXPECTED(span != 0)) {
_memory_statistics_inc(heap->size_class_use[class_idx].spans_from_reserved, 1);
return span;
}
span = _memory_heap_global_cache_extract(heap, span_count);
if (EXPECTED(span != 0)) {
_memory_statistics_inc(heap->size_class_use[class_idx].spans_from_cache, 1);
return span;
}
//Final fallback, map in more virtual memory
span = _memory_map_spans(heap, span_count);
_memory_statistics_inc(heap->size_class_use[class_idx].spans_map_calls, 1);
return span;
}
//! Move the span (used for small or medium allocations) to the heap thread cache
static void
_memory_span_release_to_cache(heap_t* heap, span_t* span) {
heap_class_t* heap_class = heap->span_class + span->size_class;
assert(heap_class->partial_span != span);
if (span->state == SPAN_STATE_PARTIAL)
_memory_span_partial_list_remove(&heap_class->partial_span, span);
#if ENABLE_ADAPTIVE_THREAD_CACHE || ENABLE_STATISTICS
atomic_decr32(&heap->span_use[0].current);
#endif
_memory_statistics_inc(heap->span_use[0].spans_to_cache, 1);
_memory_statistics_inc(heap->size_class_use[span->size_class].spans_to_cache, 1);
_memory_statistics_dec(heap->size_class_use[span->size_class].spans_current, 1);
_memory_heap_cache_insert(heap, span);
}
//! Initialize a (partial) free list up to next system memory page, while reserving the first block
//! as allocated, returning number of blocks in list
static uint32_t
free_list_partial_init(void** list, void** first_block, void* page_start, void* block_start,
uint32_t block_count, uint32_t block_size) {
assert(block_count);
*first_block = block_start;
if (block_count > 1) {
void* free_block = pointer_offset(block_start, block_size);
void* block_end = pointer_offset(block_start, block_size * block_count);
//If block size is less than half a memory page, bound init to next memory page boundary
if (block_size < (_memory_page_size >> 1)) {
void* page_end = pointer_offset(page_start, _memory_page_size);
if (page_end < block_end)
block_end = page_end;
}
*list = free_block;
block_count = 2;
void* next_block = pointer_offset(free_block, block_size);
while (next_block < block_end) {
*((void**)free_block) = next_block;
free_block = next_block;
++block_count;
next_block = pointer_offset(next_block, block_size);
}
*((void**)free_block) = 0;
} else {
*list = 0;
}
return block_count;
}
//! Initialize an unused span (from cache or mapped) to be new active span
static void*
_memory_span_set_new_active(heap_t* heap, heap_class_t* heap_class, span_t* span, uint32_t class_idx) {
assert(span->span_count == 1);
size_class_t* size_class = _memory_size_class + class_idx;
span->size_class = class_idx;
span->heap = heap;
span->flags &= ~SPAN_FLAG_ALIGNED_BLOCKS;
span->block_count = size_class->block_count;
span->block_size = size_class->block_size;
span->state = SPAN_STATE_ACTIVE;
span->free_list = 0;
//Setup free list. Only initialize one system page worth of free blocks in list
void* block;
span->free_list_limit = free_list_partial_init(&heap_class->free_list, &block,
span, pointer_offset(span, SPAN_HEADER_SIZE), size_class->block_count, size_class->block_size);
atomic_store_ptr(&span->free_list_deferred, 0);
span->list_size = 0;
atomic_thread_fence_release();
_memory_span_partial_list_add(&heap_class->partial_span, span);
return block;
}
//! Promote a partially used span (from heap used list) to be new active span
static void
_memory_span_set_partial_active(heap_class_t* heap_class, span_t* span) {
assert(span->state == SPAN_STATE_PARTIAL);
assert(span->block_count == _memory_size_class[span->size_class].block_count);
//Move data to heap size class and set span as active
heap_class->free_list = span->free_list;
span->state = SPAN_STATE_ACTIVE;
span->free_list = 0;
assert(heap_class->free_list);
}
//! Mark span as full (from active)
static void
_memory_span_set_active_full(heap_class_t* heap_class, span_t* span) {
assert(span->state == SPAN_STATE_ACTIVE);
assert(span == heap_class->partial_span);
_memory_span_partial_list_pop_head(&heap_class->partial_span);
span->used_count = span->block_count;
span->state = SPAN_STATE_FULL;
span->free_list = 0;
}
//! Move span from full to partial state
static void
_memory_span_set_full_partial(heap_t* heap, span_t* span) {
assert(span->state == SPAN_STATE_FULL);
heap_class_t* heap_class = &heap->span_class[span->size_class];
span->state = SPAN_STATE_PARTIAL;
_memory_span_partial_list_add_tail(&heap_class->partial_span, span);
}
static void*
_memory_span_extract_deferred(span_t* span) {
void* free_list;
do {
free_list = atomic_load_ptr(&span->free_list_deferred);
} while ((free_list == INVALID_POINTER) || !atomic_cas_ptr(&span->free_list_deferred, INVALID_POINTER, free_list));
span->list_size = 0;
atomic_store_ptr(&span->free_list_deferred, 0);
atomic_thread_fence_release();
return free_list;
}
//! Pop first block from a free list
static void*
free_list_pop(void** list) {
void* block = *list;
*list = *((void**)block);
return block;
}
//! Allocate a small/medium sized memory block from the given heap
static void*
_memory_allocate_from_heap_fallback(heap_t* heap, uint32_t class_idx) {
heap_class_t* heap_class = &heap->span_class[class_idx];
void* block;
span_t* active_span = heap_class->partial_span;
if (EXPECTED(active_span != 0)) {
assert(active_span->state == SPAN_STATE_ACTIVE);
assert(active_span->block_count == _memory_size_class[active_span->size_class].block_count);
//Swap in free list if not empty
if (active_span->free_list) {
heap_class->free_list = active_span->free_list;
active_span->free_list = 0;
return free_list_pop(&heap_class->free_list);
}
//If the span did not fully initialize free list, link up another page worth of blocks
if (active_span->free_list_limit < active_span->block_count) {
void* block_start = pointer_offset(active_span, SPAN_HEADER_SIZE + (active_span->free_list_limit * active_span->block_size));
active_span->free_list_limit += free_list_partial_init(&heap_class->free_list, &block,
(void*)((uintptr_t)block_start & ~(_memory_page_size - 1)), block_start,
active_span->block_count - active_span->free_list_limit, active_span->block_size);
return block;
}
//Swap in deferred free list
atomic_thread_fence_acquire();
if (atomic_load_ptr(&active_span->free_list_deferred)) {
heap_class->free_list = _memory_span_extract_deferred(active_span);
return free_list_pop(&heap_class->free_list);
}
//If the active span is fully allocated, mark span as free floating (fully allocated and not part of any list)
assert(!heap_class->free_list);
assert(active_span->free_list_limit >= active_span->block_count);
_memory_span_set_active_full(heap_class, active_span);
}
assert(!heap_class->free_list);
//Try promoting a semi-used span to active
active_span = heap_class->partial_span;
if (EXPECTED(active_span != 0)) {
_memory_span_set_partial_active(heap_class, active_span);
return free_list_pop(&heap_class->free_list);
}
assert(!heap_class->free_list);
assert(!heap_class->partial_span);
//Find a span in one of the cache levels
active_span = _memory_heap_extract_new_span(heap, 1, class_idx);
//Mark span as owned by this heap and set base data, return first block
return _memory_span_set_new_active(heap, heap_class, active_span, class_idx);
}
//! Allocate a small sized memory block from the given heap
static void*
_memory_allocate_small(heap_t* heap, size_t size) {
//Small sizes have unique size classes
const uint32_t class_idx = (uint32_t)((size + (SMALL_GRANULARITY - 1)) >> SMALL_GRANULARITY_SHIFT);
_memory_statistics_inc_alloc(heap, class_idx);
if (EXPECTED(heap->span_class[class_idx].free_list != 0))
return free_list_pop(&heap->span_class[class_idx].free_list);
return _memory_allocate_from_heap_fallback(heap, class_idx);
}
//! Allocate a medium sized memory block from the given heap
static void*
_memory_allocate_medium(heap_t* heap, size_t size) {
//Calculate the size class index and do a dependent lookup of the final class index (in case of merged classes)
const uint32_t base_idx = (uint32_t)(SMALL_CLASS_COUNT + ((size - (SMALL_SIZE_LIMIT + 1)) >> MEDIUM_GRANULARITY_SHIFT));
const uint32_t class_idx = _memory_size_class[base_idx].class_idx;
_memory_statistics_inc_alloc(heap, class_idx);
if (EXPECTED(heap->span_class[class_idx].free_list != 0))
return free_list_pop(&heap->span_class[class_idx].free_list);
return _memory_allocate_from_heap_fallback(heap, class_idx);
}
//! Allocate a large sized memory block from the given heap
static void*
_memory_allocate_large(heap_t* heap, size_t size) {
//Calculate number of needed max sized spans (including header)
//Since this function is never called if size > LARGE_SIZE_LIMIT
//the span_count is guaranteed to be <= LARGE_CLASS_COUNT
size += SPAN_HEADER_SIZE;
size_t span_count = size >> _memory_span_size_shift;
if (size & (_memory_span_size - 1))
++span_count;
size_t idx = span_count - 1;
//Find a span in one of the cache levels
span_t* span = _memory_heap_extract_new_span(heap, span_count, SIZE_CLASS_COUNT);
//Mark span as owned by this heap and set base data
assert(span->span_count == span_count);
span->size_class = (uint32_t)(SIZE_CLASS_COUNT + idx);
span->heap = heap;
atomic_thread_fence_release();
return pointer_offset(span, SPAN_HEADER_SIZE);
}
//! Allocate a huge block by mapping memory pages directly
static void*
_memory_allocate_huge(size_t size) {
size += SPAN_HEADER_SIZE;
size_t num_pages = size >> _memory_page_size_shift;
if (size & (_memory_page_size - 1))
++num_pages;
size_t align_offset = 0;
span_t* span = (span_t*)_memory_map(num_pages * _memory_page_size, &align_offset);
if (!span)
return span;
//Store page count in span_count
span->size_class = (uint32_t)-1;
span->span_count = (uint32_t)num_pages;
span->align_offset = (uint32_t)align_offset;
_memory_statistics_add_peak(&_huge_pages_current, num_pages, _huge_pages_peak);
return pointer_offset(span, SPAN_HEADER_SIZE);
}
//! Allocate a block larger than medium size
static void*
_memory_allocate_oversized(heap_t* heap, size_t size) {
if (size <= LARGE_SIZE_LIMIT)
return _memory_allocate_large(heap, size);
return _memory_allocate_huge(size);
}
//! Allocate a block of the given size
static void*
_memory_allocate(heap_t* heap, size_t size) {
if (EXPECTED(size <= SMALL_SIZE_LIMIT))
return _memory_allocate_small(heap, size);
else if (size <= _memory_medium_size_limit)
return _memory_allocate_medium(heap, size);
return _memory_allocate_oversized(heap, size);
}
//! Allocate a new heap
static heap_t*
_memory_allocate_heap(void) {
void* raw_heap;
void* next_raw_heap;
uintptr_t orphan_counter;
heap_t* heap;
heap_t* next_heap;
//Try getting an orphaned heap
atomic_thread_fence_acquire();
do {
raw_heap = atomic_load_ptr(&_memory_orphan_heaps);
heap = (heap_t*)((uintptr_t)raw_heap & ~(uintptr_t)0x1FF);
if (!heap)
break;
next_heap = heap->next_orphan;
orphan_counter = (uintptr_t)atomic_incr32(&_memory_orphan_counter);
next_raw_heap = (void*)((uintptr_t)next_heap | (orphan_counter & (uintptr_t)0x1FF));
} while (!atomic_cas_ptr(&_memory_orphan_heaps, next_raw_heap, raw_heap));
if (!heap) {
//Map in pages for a new heap
size_t align_offset = 0;
heap = (heap_t*)_memory_map((1 + (sizeof(heap_t) >> _memory_page_size_shift)) * _memory_page_size, &align_offset);
if (!heap)
return heap;
memset((char*)heap, 0, sizeof(heap_t));
heap->align_offset = align_offset;
//Get a new heap ID
do {
heap->id = atomic_incr32(&_memory_heap_id);
if (_memory_heap_lookup(heap->id))
heap->id = 0;
} while (!heap->id);
//Link in heap in heap ID map
size_t list_idx = heap->id % HEAP_ARRAY_SIZE;
do {
next_heap = (heap_t*)atomic_load_ptr(&_memory_heaps[list_idx]);
heap->next_heap = next_heap;
} while (!atomic_cas_ptr(&_memory_heaps[list_idx], heap, next_heap));
}
return heap;
}
//! Deallocate the given small/medium memory block in the current thread local heap
static void
_memory_deallocate_direct(span_t* span, void* block) {
assert(span->heap == get_thread_heap_raw());
uint32_t state = span->state;
//Add block to free list
*((void**)block) = span->free_list;
span->free_list = block;
if (UNEXPECTED(state == SPAN_STATE_ACTIVE))
return;
uint32_t used = --span->used_count;
uint32_t free = span->list_size;
if (UNEXPECTED(used == free))
_memory_span_release_to_cache(span->heap, span);
else if (UNEXPECTED(state == SPAN_STATE_FULL))
_memory_span_set_full_partial(span->heap, span);
}
//! Put the block in the deferred free list of the owning span
static void
_memory_deallocate_defer(span_t* span, void* block) {
atomic_thread_fence_acquire();
if (span->state == SPAN_STATE_FULL) {
if ((span->list_size + 1) == span->block_count) {
//Span will be completely freed by deferred deallocations, no other thread can
//currently touch it. Safe to move to owner heap deferred cache
span_t* last_head;
heap_t* heap = span->heap;
do {
last_head = (span_t*)atomic_load_ptr(&heap->span_cache_deferred);
span->next = last_head;
} while (!atomic_cas_ptr(&heap->span_cache_deferred, span, last_head));
return;
}
}
void* free_list;
do {
atomic_thread_fence_acquire();
free_list = atomic_load_ptr(&span->free_list_deferred);
*((void**)block) = free_list;
} while ((free_list == INVALID_POINTER) || !atomic_cas_ptr(&span->free_list_deferred, INVALID_POINTER, free_list));
++span->list_size;
atomic_store_ptr(&span->free_list_deferred, block);
}
static void
_memory_deallocate_small_or_medium(span_t* span, void* p) {
_memory_statistics_inc_free(span->heap, span->size_class);
if (span->flags & SPAN_FLAG_ALIGNED_BLOCKS) {
//Realign pointer to block start
void* blocks_start = pointer_offset(span, SPAN_HEADER_SIZE);
uint32_t block_offset = (uint32_t)pointer_diff(p, blocks_start);
p = pointer_offset(p, -(int32_t)(block_offset % span->block_size));
}
//Check if block belongs to this heap or if deallocation should be deferred
if (span->heap == get_thread_heap_raw())
_memory_deallocate_direct(span, p);
else
_memory_deallocate_defer(span, p);
}
//! Deallocate the given large memory block to the current heap
static void
_memory_deallocate_large(span_t* span) {
//Decrease counter
assert(span->span_count == ((size_t)span->size_class - SIZE_CLASS_COUNT + 1));
assert(span->size_class >= SIZE_CLASS_COUNT);
assert(span->size_class - SIZE_CLASS_COUNT < LARGE_CLASS_COUNT);
assert(!(span->flags & SPAN_FLAG_MASTER) || !(span->flags & SPAN_FLAG_SUBSPAN));
assert((span->flags & SPAN_FLAG_MASTER) || (span->flags & SPAN_FLAG_SUBSPAN));
//Large blocks can always be deallocated and transferred between heaps
//Investigate if it is better to defer large spans as well through span_cache_deferred,
//possibly with some heuristics to pick either scheme at runtime per deallocation
heap_t* heap = get_thread_heap();
if (!heap) return;
#if ENABLE_ADAPTIVE_THREAD_CACHE || ENABLE_STATISTICS
size_t idx = span->span_count - 1;
atomic_decr32(&span->heap->span_use[idx].current);
#endif
if ((span->span_count > 1) && !heap->spans_reserved) {
heap->span_reserve = span;
heap->spans_reserved = span->span_count;
if (span->flags & SPAN_FLAG_MASTER) {
heap->span_reserve_master = span;
} else { //SPAN_FLAG_SUBSPAN
uint32_t distance = span->total_spans_or_distance;
span_t* master = (span_t*)pointer_offset(span, -(int32_t)(distance * _memory_span_size));
heap->span_reserve_master = master;
assert(master->flags & SPAN_FLAG_MASTER);
assert(atomic_load32(&master->remaining_spans) >= (int32_t)span->span_count);
}
_memory_statistics_inc(heap->span_use[idx].spans_to_reserved, 1);
} else {
//Insert into cache list
_memory_heap_cache_insert(heap, span);
}
}
//! Deallocate the given huge span
static void
_memory_deallocate_huge(span_t* span) {
//Oversized allocation, page count is stored in span_count
size_t num_pages = span->span_count;
_memory_unmap(span, num_pages * _memory_page_size, span->align_offset, num_pages * _memory_page_size);
_memory_statistics_sub(&_huge_pages_current, num_pages);
}
//! Deallocate the given block
static void
_memory_deallocate(void* p) {
//Grab the span (always at start of span, using span alignment)
span_t* span = (span_t*)((uintptr_t)p & _memory_span_mask);
if (UNEXPECTED(!span))
return;
if (EXPECTED(span->size_class < SIZE_CLASS_COUNT))
_memory_deallocate_small_or_medium(span, p);
else if (span->size_class != (uint32_t)-1)
_memory_deallocate_large(span);
else
_memory_deallocate_huge(span);
}
//! Reallocate the given block to the given size
static void*
_memory_reallocate(void* p, size_t size, size_t oldsize, unsigned int flags) {
if (p) {
//Grab the span using guaranteed span alignment
span_t* span = (span_t*)((uintptr_t)p & _memory_span_mask);
if (span->heap) {
if (span->size_class < SIZE_CLASS_COUNT) {
//Small/medium sized block
assert(span->span_count == 1);
void* blocks_start = pointer_offset(span, SPAN_HEADER_SIZE);
uint32_t block_offset = (uint32_t)pointer_diff(p, blocks_start);
uint32_t block_idx = block_offset / span->block_size;
void* block = pointer_offset(blocks_start, block_idx * span->block_size);
if (!oldsize)
oldsize = span->block_size - (uint32_t)pointer_diff(p, block);
if ((size_t)span->block_size >= size) {
//Still fits in block, never mind trying to save memory, but preserve data if alignment changed
if ((p != block) && !(flags & RPMALLOC_NO_PRESERVE))
memmove(block, p, oldsize);
return block;
}
} else {
//Large block
size_t total_size = size + SPAN_HEADER_SIZE;
size_t num_spans = total_size >> _memory_span_size_shift;
if (total_size & (_memory_span_mask - 1))
++num_spans;
size_t current_spans = span->span_count;
assert(current_spans == ((span->size_class - SIZE_CLASS_COUNT) + 1));
void* block = pointer_offset(span, SPAN_HEADER_SIZE);
if (!oldsize)
oldsize = (current_spans * _memory_span_size) - (size_t)pointer_diff(p, block) - SPAN_HEADER_SIZE;
if ((current_spans >= num_spans) && (num_spans >= (current_spans / 2))) {
//Still fits in block, never mind trying to save memory, but preserve data if alignment changed
if ((p != block) && !(flags & RPMALLOC_NO_PRESERVE))
memmove(block, p, oldsize);
return block;
}
}
} else {
//Oversized block
size_t total_size = size + SPAN_HEADER_SIZE;
size_t num_pages = total_size >> _memory_page_size_shift;
if (total_size & (_memory_page_size - 1))
++num_pages;
//Page count is stored in span_count
size_t current_pages = span->span_count;
void* block = pointer_offset(span, SPAN_HEADER_SIZE);
if (!oldsize)
oldsize = (current_pages * _memory_page_size) - (size_t)pointer_diff(p, block) - SPAN_HEADER_SIZE;
if ((current_pages >= num_pages) && (num_pages >= (current_pages / 2))) {
//Still fits in block, never mind trying to save memory, but preserve data if alignment changed
if ((p != block) && !(flags & RPMALLOC_NO_PRESERVE))
memmove(block, p, oldsize);
return block;
}
}
} else {
oldsize = 0;
}
//Size is greater than block size, need to allocate a new block and deallocate the old
heap_t* heap = get_thread_heap();
//Avoid hysteresis by overallocating if increase is small (below 37%)
size_t lower_bound = oldsize + (oldsize >> 2) + (oldsize >> 3);
size_t new_size = (size > lower_bound) ? size : ((size > oldsize) ? lower_bound : size);
void* block = _memory_allocate(heap, new_size);
if (p && block) {
if (!(flags & RPMALLOC_NO_PRESERVE))
memcpy(block, p, oldsize < new_size ? oldsize : new_size);
_memory_deallocate(p);
}
return block;
}
//! Get the usable size of the given block
static size_t
_memory_usable_size(void* p) {
//Grab the span using guaranteed span alignment
span_t* span = (span_t*)((uintptr_t)p & _memory_span_mask);
if (span->heap) {
//Small/medium block
if (span->size_class < SIZE_CLASS_COUNT) {
void* blocks_start = pointer_offset(span, SPAN_HEADER_SIZE);
return span->block_size - ((size_t)pointer_diff(p, blocks_start) % span->block_size);
}
//Large block
size_t current_spans = (span->size_class - SIZE_CLASS_COUNT) + 1;
return (current_spans * _memory_span_size) - (size_t)pointer_diff(p, span);
}
//Oversized block, page count is stored in span_count
size_t current_pages = span->span_count;
return (current_pages * _memory_page_size) - (size_t)pointer_diff(p, span);
}
//! Adjust and optimize the size class properties for the given class
static void
_memory_adjust_size_class(size_t iclass) {
size_t block_size = _memory_size_class[iclass].block_size;
size_t block_count = (_memory_span_size - SPAN_HEADER_SIZE) / block_size;
_memory_size_class[iclass].block_count = (uint16_t)block_count;
_memory_size_class[iclass].class_idx = (uint16_t)iclass;
//Check if previous size classes can be merged
size_t prevclass = iclass;
while (prevclass > 0) {
--prevclass;
//A class can be merged if number of pages and number of blocks are equal
if (_memory_size_class[prevclass].block_count == _memory_size_class[iclass].block_count)
memcpy(_memory_size_class + prevclass, _memory_size_class + iclass, sizeof(_memory_size_class[iclass]));
else
break;
}
}
static void
_memory_heap_finalize(void* heapptr) {
heap_t* heap = (heap_t*)heapptr;
if (!heap)
return;
//Release thread cache spans back to global cache
#if ENABLE_THREAD_CACHE
_memory_heap_cache_adopt_deferred(heap);
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
span_t* span = heap->span_cache[iclass];
#if ENABLE_GLOBAL_CACHE
while (span) {
assert(span->span_count == (iclass + 1));
size_t release_count = (!iclass ? _memory_span_release_count : _memory_span_release_count_large);
span_t* next = _memory_span_list_split(span, (uint32_t)release_count);
#if ENABLE_STATISTICS
heap->thread_to_global += (size_t)span->list_size * span->span_count * _memory_span_size;
heap->span_use[iclass].spans_to_global += span->list_size;
#endif
_memory_global_cache_insert(span);
span = next;
}
#else
if (span)
_memory_unmap_span_list(span);
#endif
heap->span_cache[iclass] = 0;
}
#endif
//Orphan the heap
void* raw_heap;
uintptr_t orphan_counter;
heap_t* last_heap;
do {
last_heap = (heap_t*)atomic_load_ptr(&_memory_orphan_heaps);
heap->next_orphan = (heap_t*)((uintptr_t)last_heap & ~(uintptr_t)0x1FF);
orphan_counter = (uintptr_t)atomic_incr32(&_memory_orphan_counter);
raw_heap = (void*)((uintptr_t)heap | (orphan_counter & (uintptr_t)0x1FF));
} while (!atomic_cas_ptr(&_memory_orphan_heaps, raw_heap, last_heap));
set_thread_heap(0);
#if ENABLE_STATISTICS
atomic_decr32(&_memory_active_heaps);
assert(atomic_load32(&_memory_active_heaps) >= 0);
#endif
}
#if defined(_MSC_VER) && !defined(__clang__) && (!defined(BUILD_DYNAMIC_LINK) || !BUILD_DYNAMIC_LINK)
#include <fibersapi.h>
static DWORD fls_key;
static void NTAPI
rp_thread_destructor(void* value) {
if (value)
rpmalloc_thread_finalize();
}
#endif
#if PLATFORM_POSIX
# include <sys/mman.h>
# include <sched.h>
# ifdef __FreeBSD__
# include <sys/sysctl.h>
# define MAP_HUGETLB MAP_ALIGNED_SUPER
# endif
# ifndef MAP_UNINITIALIZED
# define MAP_UNINITIALIZED 0
# endif
#endif
#include <errno.h>
//! Initialize the allocator and setup global data
extern inline int
rpmalloc_initialize(void) {
if (_rpmalloc_initialized) {
rpmalloc_thread_initialize();
return 0;
}
memset(&_memory_config, 0, sizeof(rpmalloc_config_t));
return rpmalloc_initialize_config(0);
}
int
rpmalloc_initialize_config(const rpmalloc_config_t* config) {
if (_rpmalloc_initialized) {
rpmalloc_thread_initialize();
return 0;
}
_rpmalloc_initialized = 1;
if (config)
memcpy(&_memory_config, config, sizeof(rpmalloc_config_t));
if (!_memory_config.memory_map || !_memory_config.memory_unmap) {
_memory_config.memory_map = _memory_map_os;
_memory_config.memory_unmap = _memory_unmap_os;
}
#if RPMALLOC_CONFIGURABLE
_memory_page_size = _memory_config.page_size;
#else
_memory_page_size = 0;
#endif
_memory_huge_pages = 0;
_memory_map_granularity = _memory_page_size;
if (!_memory_page_size) {
#if PLATFORM_WINDOWS
SYSTEM_INFO system_info;
memset(&system_info, 0, sizeof(system_info));
GetSystemInfo(&system_info);
_memory_page_size = system_info.dwPageSize;
_memory_map_granularity = system_info.dwAllocationGranularity;
if (config && config->enable_huge_pages) {
HANDLE token = 0;
size_t large_page_minimum = GetLargePageMinimum();
if (large_page_minimum)
OpenProcessToken(GetCurrentProcess(), TOKEN_ADJUST_PRIVILEGES | TOKEN_QUERY, &token);
if (token) {
LUID luid;
if (LookupPrivilegeValue(0, SE_LOCK_MEMORY_NAME, &luid)) {
TOKEN_PRIVILEGES token_privileges;
memset(&token_privileges, 0, sizeof(token_privileges));
token_privileges.PrivilegeCount = 1;
token_privileges.Privileges[0].Luid = luid;
token_privileges.Privileges[0].Attributes = SE_PRIVILEGE_ENABLED;
if (AdjustTokenPrivileges(token, FALSE, &token_privileges, 0, 0, 0)) {
DWORD err = GetLastError();
if (err == ERROR_SUCCESS) {
_memory_huge_pages = 1;
_memory_page_size = large_page_minimum;
_memory_map_granularity = large_page_minimum;
}
}
}
CloseHandle(token);
}
}
#else
_memory_page_size = (size_t)sysconf(_SC_PAGESIZE);
_memory_map_granularity = _memory_page_size;
if (config && config->enable_huge_pages) {
#if defined(__linux__)
size_t huge_page_size = 0;
FILE* meminfo = fopen("/proc/meminfo", "r");
if (meminfo) {
char line[128];
while (!huge_page_size && fgets(line, sizeof(line) - 1, meminfo)) {
line[sizeof(line) - 1] = 0;
if (strstr(line, "Hugepagesize:"))
huge_page_size = (size_t)strtol(line + 13, 0, 10) * 1024;
}
fclose(meminfo);
}
if (huge_page_size) {
_memory_huge_pages = 1;
_memory_page_size = huge_page_size;
_memory_map_granularity = huge_page_size;
}
#elif defined(__FreeBSD__)
int rc;
size_t sz = sizeof(rc);
if (sysctlbyname("vm.pmap.pg_ps_enabled", &rc, &sz, NULL, 0) == 0 && rc == 1) {
_memory_huge_pages = 1;
_memory_page_size = 2 * 1024 * 1024;
_memory_map_granularity = _memory_page_size;
}
#elif defined(__APPLE__)
_memory_huge_pages = 1;
_memory_page_size = 2 * 1024 * 1024;
_memory_map_granularity = _memory_page_size;
#endif
}
#endif
} else {
if (config && config->enable_huge_pages)
_memory_huge_pages = 1;
}
//The ABA counter in heap orphan list is tied to using 512 (bitmask 0x1FF)
if (_memory_page_size < 512)
_memory_page_size = 512;
if (_memory_page_size > (64 * 1024 * 1024))
_memory_page_size = (64 * 1024 * 1024);
_memory_page_size_shift = 0;
size_t page_size_bit = _memory_page_size;
while (page_size_bit != 1) {
++_memory_page_size_shift;
page_size_bit >>= 1;
}
_memory_page_size = ((size_t)1 << _memory_page_size_shift);
#if RPMALLOC_CONFIGURABLE
size_t span_size = _memory_config.span_size;
if (!span_size)
span_size = (64 * 1024);
if (span_size > (256 * 1024))
span_size = (256 * 1024);
_memory_span_size = 4096;
_memory_span_size_shift = 12;
while (_memory_span_size < span_size) {
_memory_span_size <<= 1;
++_memory_span_size_shift;
}
_memory_span_mask = ~(uintptr_t)(_memory_span_size - 1);
#endif
_memory_span_map_count = ( _memory_config.span_map_count ? _memory_config.span_map_count : DEFAULT_SPAN_MAP_COUNT);
if ((_memory_span_size * _memory_span_map_count) < _memory_page_size)
_memory_span_map_count = (_memory_page_size / _memory_span_size);
if ((_memory_page_size >= _memory_span_size) && ((_memory_span_map_count * _memory_span_size) % _memory_page_size))
_memory_span_map_count = (_memory_page_size / _memory_span_size);
_memory_config.page_size = _memory_page_size;
_memory_config.span_size = _memory_span_size;
_memory_config.span_map_count = _memory_span_map_count;
_memory_config.enable_huge_pages = _memory_huge_pages;
_memory_span_release_count = (_memory_span_map_count > 4 ? ((_memory_span_map_count < 64) ? _memory_span_map_count : 64) : 4);
_memory_span_release_count_large = (_memory_span_release_count > 8 ? (_memory_span_release_count / 4) : 2);
#if (defined(__APPLE__) || defined(__HAIKU__)) && ENABLE_PRELOAD
if (pthread_key_create(&_memory_thread_heap, _memory_heap_finalize))
return -1;
#endif
#if defined(_MSC_VER) && !defined(__clang__) && (!defined(BUILD_DYNAMIC_LINK) || !BUILD_DYNAMIC_LINK)
fls_key = FlsAlloc(&rp_thread_destructor);
#endif
atomic_store32(&_memory_heap_id, 0);
atomic_store32(&_memory_orphan_counter, 0);
#if ENABLE_STATISTICS
atomic_store32(&_memory_active_heaps, 0);
atomic_store32(&_reserved_spans, 0);
atomic_store32(&_mapped_pages, 0);
_mapped_pages_peak = 0;
atomic_store32(&_mapped_total, 0);
atomic_store32(&_unmapped_total, 0);
atomic_store32(&_mapped_pages_os, 0);
atomic_store32(&_huge_pages_current, 0);
_huge_pages_peak = 0;
#endif
//Setup all small and medium size classes
size_t iclass = 0;
_memory_size_class[iclass].block_size = SMALL_GRANULARITY;
_memory_adjust_size_class(iclass);
for (iclass = 1; iclass < SMALL_CLASS_COUNT; ++iclass) {
size_t size = iclass * SMALL_GRANULARITY;
_memory_size_class[iclass].block_size = (uint32_t)size;
_memory_adjust_size_class(iclass);
}
//At least two blocks per span, then fall back to large allocations
_memory_medium_size_limit = (_memory_span_size - SPAN_HEADER_SIZE) >> 1;
if (_memory_medium_size_limit > MEDIUM_SIZE_LIMIT)
_memory_medium_size_limit = MEDIUM_SIZE_LIMIT;
for (iclass = 0; iclass < MEDIUM_CLASS_COUNT; ++iclass) {
size_t size = SMALL_SIZE_LIMIT + ((iclass + 1) * MEDIUM_GRANULARITY);
if (size > _memory_medium_size_limit)
break;
_memory_size_class[SMALL_CLASS_COUNT + iclass].block_size = (uint32_t)size;
_memory_adjust_size_class(SMALL_CLASS_COUNT + iclass);
}
for (size_t list_idx = 0; list_idx < HEAP_ARRAY_SIZE; ++list_idx)
atomic_store_ptr(&_memory_heaps[list_idx], 0);
//Initialize this thread
rpmalloc_thread_initialize();
return 0;
}
//! Finalize the allocator
void
rpmalloc_finalize(void) {
atomic_thread_fence_acquire();
rpmalloc_thread_finalize();
//rpmalloc_dump_statistics(stderr);
//Free all thread caches
for (size_t list_idx = 0; list_idx < HEAP_ARRAY_SIZE; ++list_idx) {
heap_t* heap = (heap_t*)atomic_load_ptr(&_memory_heaps[list_idx]);
while (heap) {
if (heap->spans_reserved) {
span_t* span = _memory_map_spans(heap, heap->spans_reserved);
_memory_unmap_span(span);
}
for (size_t iclass = 0; iclass < SIZE_CLASS_COUNT; ++iclass) {
heap_class_t* heap_class = heap->span_class + iclass;
span_t* span = heap_class->partial_span;
while (span) {
span_t* next = span->next;
if (span->state == SPAN_STATE_ACTIVE) {
uint32_t used_blocks = span->block_count;
if (span->free_list_limit < span->block_count)
used_blocks = span->free_list_limit;
uint32_t free_blocks = 0;
void* block = heap_class->free_list;
while (block) {
++free_blocks;
block = *((void**)block);
}
block = span->free_list;
while (block) {
++free_blocks;
block = *((void**)block);
}
if (used_blocks == (free_blocks + span->list_size))
_memory_heap_cache_insert(heap, span);
} else {
if (span->used_count == span->list_size)
_memory_heap_cache_insert(heap, span);
}
span = next;
}
}
#if ENABLE_THREAD_CACHE
//Free span caches (other thread might have deferred after the thread using this heap finalized)
_memory_heap_cache_adopt_deferred(heap);
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
if (heap->span_cache[iclass])
_memory_unmap_span_list(heap->span_cache[iclass]);
}
#endif
heap_t* next_heap = heap->next_heap;
size_t heap_size = (1 + (sizeof(heap_t) >> _memory_page_size_shift)) * _memory_page_size;
_memory_unmap(heap, heap_size, heap->align_offset, heap_size);
heap = next_heap;
}
}
#if ENABLE_GLOBAL_CACHE
//Free global caches
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass)
_memory_cache_finalize(&_memory_span_cache[iclass]);
#endif
atomic_store_ptr(&_memory_orphan_heaps, 0);
atomic_thread_fence_release();
#if (defined(__APPLE__) || defined(__HAIKU__)) && ENABLE_PRELOAD
pthread_key_delete(_memory_thread_heap);
#endif
#if defined(_MSC_VER) && !defined(__clang__) && (!defined(BUILD_DYNAMIC_LINK) || !BUILD_DYNAMIC_LINK)
FlsFree(fls_key);
#endif
#if ENABLE_STATISTICS
//If you hit these asserts you probably have memory leaks or double frees in your code
assert(!atomic_load32(&_mapped_pages));
assert(!atomic_load32(&_reserved_spans));
assert(!atomic_load32(&_mapped_pages_os));
#endif
_rpmalloc_initialized = 0;
}
//! Initialize thread, assign heap
extern inline void
rpmalloc_thread_initialize(void) {
if (!get_thread_heap_raw()) {
heap_t* heap = _memory_allocate_heap();
if (heap) {
atomic_thread_fence_acquire();
#if ENABLE_STATISTICS
atomic_incr32(&_memory_active_heaps);
#endif
set_thread_heap(heap);
#if defined(_MSC_VER) && !defined(__clang__) && (!defined(BUILD_DYNAMIC_LINK) || !BUILD_DYNAMIC_LINK)
FlsSetValue(fls_key, heap);
#endif
}
}
}
//! Finalize thread, orphan heap
void
rpmalloc_thread_finalize(void) {
heap_t* heap = get_thread_heap_raw();
if (heap)
_memory_heap_finalize(heap);
}
int
rpmalloc_is_thread_initialized(void) {
return (get_thread_heap_raw() != 0) ? 1 : 0;
}
const rpmalloc_config_t*
rpmalloc_config(void) {
return &_memory_config;
}
//! Map new pages to virtual memory
static void*
_memory_map_os(size_t size, size_t* offset) {
//Either size is a heap (a single page) or a (multiple) span - we only need to align spans, and only if larger than map granularity
size_t padding = ((size >= _memory_span_size) && (_memory_span_size > _memory_map_granularity)) ? _memory_span_size : 0;
assert(size >= _memory_page_size);
#if PLATFORM_WINDOWS
//Ok to MEM_COMMIT - according to MSDN, "actual physical pages are not allocated unless/until the virtual addresses are actually accessed"
void* ptr = VirtualAlloc(0, size + padding, (_memory_huge_pages ? MEM_LARGE_PAGES : 0) | MEM_RESERVE | MEM_COMMIT, PAGE_READWRITE);
if (!ptr) {
assert(!"Failed to map virtual memory block");
return 0;
}
#else
int flags = MAP_PRIVATE | MAP_ANONYMOUS | MAP_UNINITIALIZED;
# if defined(__APPLE__)
int fd = (int)VM_MAKE_TAG(240U);
if (_memory_huge_pages)
fd |= VM_FLAGS_SUPERPAGE_SIZE_2MB;
void* ptr = mmap(0, size + padding, PROT_READ | PROT_WRITE, flags, fd, 0);
# elif defined(MAP_HUGETLB)
void* ptr = mmap(0, size + padding, PROT_READ | PROT_WRITE, (_memory_huge_pages ? MAP_HUGETLB : 0) | flags, -1, 0);
# else
void* ptr = mmap(0, size + padding, PROT_READ | PROT_WRITE, flags, -1, 0);
# endif
if ((ptr == MAP_FAILED) || !ptr) {
assert("Failed to map virtual memory block" == 0);
return 0;
}
#endif
#if ENABLE_STATISTICS
atomic_add32(&_mapped_pages_os, (int32_t)((size + padding) >> _memory_page_size_shift));
#endif
if (padding) {
size_t final_padding = padding - ((uintptr_t)ptr & ~_memory_span_mask);
assert(final_padding <= _memory_span_size);
assert(final_padding <= padding);
assert(!(final_padding % 8));
ptr = pointer_offset(ptr, final_padding);
*offset = final_padding >> 3;
}
assert((size < _memory_span_size) || !((uintptr_t)ptr & ~_memory_span_mask));
return ptr;
}
//! Unmap pages from virtual memory
static void
_memory_unmap_os(void* address, size_t size, size_t offset, size_t release) {
assert(release || (offset == 0));
assert(!release || (release >= _memory_page_size));
assert(size >= _memory_page_size);
if (release && offset) {
offset <<= 3;
address = pointer_offset(address, -(int32_t)offset);
#if PLATFORM_POSIX
//Padding is always one span size
release += _memory_span_size;
#endif
}
#if !DISABLE_UNMAP
#if PLATFORM_WINDOWS
if (!VirtualFree(address, release ? 0 : size, release ? MEM_RELEASE : MEM_DECOMMIT)) {
assert(!"Failed to unmap virtual memory block");
}
#else
if (release) {
if (munmap(address, release)) {
assert("Failed to unmap virtual memory block" == 0);
}
}
else {
#if defined(POSIX_MADV_FREE)
if (posix_madvise(address, size, POSIX_MADV_FREE))
#endif
#if defined(POSIX_MADV_DONTNEED)
if (posix_madvise(address, size, POSIX_MADV_DONTNEED)) {
assert("Failed to madvise virtual memory block as free" == 0);
}
#endif
}
#endif
#endif
#if ENABLE_STATISTICS
if (release)
atomic_add32(&_mapped_pages_os, -(int32_t)(release >> _memory_page_size_shift));
#endif
}
// Extern interface
TRACY_API RPMALLOC_ALLOCATOR void*
rpmalloc(size_t size) {
#if ENABLE_VALIDATE_ARGS
if (size >= MAX_ALLOC_SIZE) {
errno = EINVAL;
return 0;
}
#endif
heap_t* heap = get_thread_heap();
return _memory_allocate(heap, size);
}
TRACY_API void
rpfree(void* ptr) {
_memory_deallocate(ptr);
}
extern inline RPMALLOC_ALLOCATOR void*
rpcalloc(size_t num, size_t size) {
size_t total;
#if ENABLE_VALIDATE_ARGS
#if PLATFORM_WINDOWS
int err = SizeTMult(num, size, &total);
if ((err != S_OK) || (total >= MAX_ALLOC_SIZE)) {
errno = EINVAL;
return 0;
}
#else
int err = __builtin_umull_overflow(num, size, &total);
if (err || (total >= MAX_ALLOC_SIZE)) {
errno = EINVAL;
return 0;
}
#endif
#else
total = num * size;
#endif
heap_t* heap = get_thread_heap();
void* block = _memory_allocate(heap, total);
memset(block, 0, total);
return block;
}
extern inline RPMALLOC_ALLOCATOR void*
rprealloc(void* ptr, size_t size) {
#if ENABLE_VALIDATE_ARGS
if (size >= MAX_ALLOC_SIZE) {
errno = EINVAL;
return ptr;
}
#endif
return _memory_reallocate(ptr, size, 0, 0);
}
extern RPMALLOC_ALLOCATOR void*
rpaligned_realloc(void* ptr, size_t alignment, size_t size, size_t oldsize,
unsigned int flags) {
#if ENABLE_VALIDATE_ARGS
if ((size + alignment < size) || (alignment > _memory_page_size)) {
errno = EINVAL;
return 0;
}
#endif
void* block;
if (alignment > 32) {
size_t usablesize = _memory_usable_size(ptr);
if ((usablesize >= size) && (size >= (usablesize / 2)) && !((uintptr_t)ptr & (alignment - 1)))
return ptr;
block = rpaligned_alloc(alignment, size);
if (ptr) {
if (!oldsize)
oldsize = usablesize;
if (!(flags & RPMALLOC_NO_PRESERVE))
memcpy(block, ptr, oldsize < size ? oldsize : size);
rpfree(ptr);
}
//Mark as having aligned blocks
span_t* span = (span_t*)((uintptr_t)block & _memory_span_mask);
span->flags |= SPAN_FLAG_ALIGNED_BLOCKS;
} else {
block = _memory_reallocate(ptr, size, oldsize, flags);
}
return block;
}
extern RPMALLOC_ALLOCATOR void*
rpaligned_alloc(size_t alignment, size_t size) {
if (alignment <= 16)
return rpmalloc(size);
#if ENABLE_VALIDATE_ARGS
if ((size + alignment) < size) {
errno = EINVAL;
return 0;
}
if (alignment & (alignment - 1)) {
errno = EINVAL;
return 0;
}
#endif
void* ptr = 0;
size_t align_mask = alignment - 1;
if (alignment < _memory_page_size) {
ptr = rpmalloc(size + alignment);
if ((uintptr_t)ptr & align_mask)
ptr = (void*)(((uintptr_t)ptr & ~(uintptr_t)align_mask) + alignment);
//Mark as having aligned blocks
span_t* span = (span_t*)((uintptr_t)ptr & _memory_span_mask);
span->flags |= SPAN_FLAG_ALIGNED_BLOCKS;
return ptr;
}
// Fallback to mapping new pages for this request. Since pointers passed
// to rpfree must be able to reach the start of the span by bitmasking of
// the address with the span size, the returned aligned pointer from this
// function must be with a span size of the start of the mapped area.
// In worst case this requires us to loop and map pages until we get a
// suitable memory address. It also means we can never align to span size
// or greater, since the span header will push alignment more than one
// span size away from span start (thus causing pointer mask to give us
// an invalid span start on free)
if (alignment & align_mask) {
errno = EINVAL;
return 0;
}
if (alignment >= _memory_span_size) {
errno = EINVAL;
return 0;
}
size_t extra_pages = alignment / _memory_page_size;
// Since each span has a header, we will at least need one extra memory page
size_t num_pages = 1 + (size / _memory_page_size);
if (size & (_memory_page_size - 1))
++num_pages;
if (extra_pages > num_pages)
num_pages = 1 + extra_pages;
size_t original_pages = num_pages;
size_t limit_pages = (_memory_span_size / _memory_page_size) * 2;
if (limit_pages < (original_pages * 2))
limit_pages = original_pages * 2;
size_t mapped_size, align_offset;
span_t* span;
retry:
align_offset = 0;
mapped_size = num_pages * _memory_page_size;
span = (span_t*)_memory_map(mapped_size, &align_offset);
if (!span) {
errno = ENOMEM;
return 0;
}
ptr = pointer_offset(span, SPAN_HEADER_SIZE);
if ((uintptr_t)ptr & align_mask)
ptr = (void*)(((uintptr_t)ptr & ~(uintptr_t)align_mask) + alignment);
if (((size_t)pointer_diff(ptr, span) >= _memory_span_size) ||
(pointer_offset(ptr, size) > pointer_offset(span, mapped_size)) ||
(((uintptr_t)ptr & _memory_span_mask) != (uintptr_t)span)) {
_memory_unmap(span, mapped_size, align_offset, mapped_size);
++num_pages;
if (num_pages > limit_pages) {
errno = EINVAL;
return 0;
}
goto retry;
}
//Store page count in span_count
span->size_class = (uint32_t)-1;
span->span_count = (uint32_t)num_pages;
span->align_offset = (uint32_t)align_offset;
_memory_statistics_add_peak(&_huge_pages_current, num_pages, _huge_pages_peak);
return ptr;
}
extern inline RPMALLOC_ALLOCATOR void*
rpmemalign(size_t alignment, size_t size) {
return rpaligned_alloc(alignment, size);
}
extern inline int
rpposix_memalign(void **memptr, size_t alignment, size_t size) {
if (memptr)
*memptr = rpaligned_alloc(alignment, size);
else
return EINVAL;
return *memptr ? 0 : ENOMEM;
}
extern inline size_t
rpmalloc_usable_size(void* ptr) {
return (ptr ? _memory_usable_size(ptr) : 0);
}
extern inline void
rpmalloc_thread_collect(void) {
}
void
rpmalloc_thread_statistics(rpmalloc_thread_statistics_t* stats) {
memset(stats, 0, sizeof(rpmalloc_thread_statistics_t));
heap_t* heap = get_thread_heap_raw();
if (!heap)
return;
for (size_t iclass = 0; iclass < SIZE_CLASS_COUNT; ++iclass) {
size_class_t* size_class = _memory_size_class + iclass;
heap_class_t* heap_class = heap->span_class + iclass;
span_t* span = heap_class->partial_span;
while (span) {
atomic_thread_fence_acquire();
size_t free_count = span->list_size;
if (span->state == SPAN_STATE_PARTIAL)
free_count += (size_class->block_count - span->used_count);
stats->sizecache = free_count * size_class->block_size;
span = span->next;
}
}
#if ENABLE_THREAD_CACHE
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
if (heap->span_cache[iclass])
stats->spancache = (size_t)heap->span_cache[iclass]->list_size * (iclass + 1) * _memory_span_size;
span_t* deferred_list = !iclass ? (span_t*)atomic_load_ptr(&heap->span_cache_deferred) : 0;
//TODO: Incorrect, for deferred lists the size is NOT stored in list_size
if (deferred_list)
stats->spancache = (size_t)deferred_list->list_size * (iclass + 1) * _memory_span_size;
}
#endif
#if ENABLE_STATISTICS
stats->thread_to_global = heap->thread_to_global;
stats->global_to_thread = heap->global_to_thread;
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
stats->span_use[iclass].current = (size_t)atomic_load32(&heap->span_use[iclass].current);
stats->span_use[iclass].peak = (size_t)heap->span_use[iclass].high;
stats->span_use[iclass].to_global = (size_t)heap->span_use[iclass].spans_to_global;
stats->span_use[iclass].from_global = (size_t)heap->span_use[iclass].spans_from_global;
stats->span_use[iclass].to_cache = (size_t)heap->span_use[iclass].spans_to_cache;
stats->span_use[iclass].from_cache = (size_t)heap->span_use[iclass].spans_from_cache;
stats->span_use[iclass].to_reserved = (size_t)heap->span_use[iclass].spans_to_reserved;
stats->span_use[iclass].from_reserved = (size_t)heap->span_use[iclass].spans_from_reserved;
stats->span_use[iclass].map_calls = (size_t)heap->span_use[iclass].spans_map_calls;
}
for (size_t iclass = 0; iclass < SIZE_CLASS_COUNT; ++iclass) {
stats->size_use[iclass].alloc_current = (size_t)atomic_load32(&heap->size_class_use[iclass].alloc_current);
stats->size_use[iclass].alloc_peak = (size_t)heap->size_class_use[iclass].alloc_peak;
stats->size_use[iclass].alloc_total = (size_t)heap->size_class_use[iclass].alloc_total;
stats->size_use[iclass].free_total = (size_t)atomic_load32(&heap->size_class_use[iclass].free_total);
stats->size_use[iclass].spans_to_cache = (size_t)heap->size_class_use[iclass].spans_to_cache;
stats->size_use[iclass].spans_from_cache = (size_t)heap->size_class_use[iclass].spans_from_cache;
stats->size_use[iclass].spans_from_reserved = (size_t)heap->size_class_use[iclass].spans_from_reserved;
stats->size_use[iclass].map_calls = (size_t)heap->size_class_use[iclass].spans_map_calls;
}
#endif
}
void
rpmalloc_global_statistics(rpmalloc_global_statistics_t* stats) {
memset(stats, 0, sizeof(rpmalloc_global_statistics_t));
#if ENABLE_STATISTICS
stats->mapped = (size_t)atomic_load32(&_mapped_pages) * _memory_page_size;
stats->mapped_peak = (size_t)_mapped_pages_peak * _memory_page_size;
stats->mapped_total = (size_t)atomic_load32(&_mapped_total) * _memory_page_size;
stats->unmapped_total = (size_t)atomic_load32(&_unmapped_total) * _memory_page_size;
stats->huge_alloc = (size_t)atomic_load32(&_huge_pages_current) * _memory_page_size;
stats->huge_alloc_peak = (size_t)_huge_pages_peak * _memory_page_size;
#endif
#if ENABLE_GLOBAL_CACHE
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
stats->cached += (size_t)atomic_load32(&_memory_span_cache[iclass].size) * (iclass + 1) * _memory_span_size;
}
#endif
}
void
rpmalloc_dump_statistics(void* file) {
#if ENABLE_STATISTICS
//If you hit this assert, you still have active threads or forgot to finalize some thread(s)
assert(atomic_load32(&_memory_active_heaps) == 0);
for (size_t list_idx = 0; list_idx < HEAP_ARRAY_SIZE; ++list_idx) {
heap_t* heap = atomic_load_ptr(&_memory_heaps[list_idx]);
while (heap) {
fprintf(file, "Heap %d stats:\n", heap->id);
fprintf(file, "Class CurAlloc PeakAlloc TotAlloc TotFree BlkSize BlkCount SpansCur SpansPeak PeakAllocMiB ToCacheMiB FromCacheMiB FromReserveMiB MmapCalls\n");
for (size_t iclass = 0; iclass < SIZE_CLASS_COUNT; ++iclass) {
if (!heap->size_class_use[iclass].alloc_total) {
assert(!atomic_load32(&heap->size_class_use[iclass].free_total));
assert(!heap->size_class_use[iclass].spans_map_calls);
continue;
}
fprintf(file, "%3u: %10u %10u %10u %10u %8u %8u %8d %9d %13zu %11zu %12zu %14zu %9u\n", (uint32_t)iclass,
atomic_load32(&heap->size_class_use[iclass].alloc_current),
heap->size_class_use[iclass].alloc_peak,
heap->size_class_use[iclass].alloc_total,
atomic_load32(&heap->size_class_use[iclass].free_total),
_memory_size_class[iclass].block_size,
_memory_size_class[iclass].block_count,
heap->size_class_use[iclass].spans_current,
heap->size_class_use[iclass].spans_peak,
((size_t)heap->size_class_use[iclass].alloc_peak * (size_t)_memory_size_class[iclass].block_size) / (size_t)(1024 * 1024),
((size_t)heap->size_class_use[iclass].spans_to_cache * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->size_class_use[iclass].spans_from_cache * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->size_class_use[iclass].spans_from_reserved * _memory_span_size) / (size_t)(1024 * 1024),
heap->size_class_use[iclass].spans_map_calls);
}
fprintf(file, "Spans Current Peak PeakMiB Cached ToCacheMiB FromCacheMiB ToReserveMiB FromReserveMiB ToGlobalMiB FromGlobalMiB MmapCalls\n");
for (size_t iclass = 0; iclass < LARGE_CLASS_COUNT; ++iclass) {
if (!heap->span_use[iclass].high && !heap->span_use[iclass].spans_map_calls)
continue;
fprintf(file, "%4u: %8d %8u %8zu %7u %11zu %12zu %12zu %14zu %11zu %13zu %10u\n", (uint32_t)(iclass + 1),
atomic_load32(&heap->span_use[iclass].current),
heap->span_use[iclass].high,
((size_t)heap->span_use[iclass].high * (size_t)_memory_span_size * (iclass + 1)) / (size_t)(1024 * 1024),
heap->span_cache[iclass] ? heap->span_cache[iclass]->list_size : 0,
((size_t)heap->span_use[iclass].spans_to_cache * (iclass + 1) * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->span_use[iclass].spans_from_cache * (iclass + 1) * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->span_use[iclass].spans_to_reserved * (iclass + 1) * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->span_use[iclass].spans_from_reserved * (iclass + 1) * _memory_span_size) / (size_t)(1024 * 1024),
((size_t)heap->span_use[iclass].spans_to_global * (size_t)_memory_span_size * (iclass + 1)) / (size_t)(1024 * 1024),
((size_t)heap->span_use[iclass].spans_from_global * (size_t)_memory_span_size * (iclass + 1)) / (size_t)(1024 * 1024),
heap->span_use[iclass].spans_map_calls);
}
fprintf(file, "ThreadToGlobalMiB GlobalToThreadMiB\n");
fprintf(file, "%17zu %17zu\n", (size_t)heap->thread_to_global / (size_t)(1024 * 1024), (size_t)heap->global_to_thread / (size_t)(1024 * 1024));
heap = heap->next_heap;
}
}
fprintf(file, "Global stats:\n");
size_t huge_current = (size_t)atomic_load32(&_huge_pages_current) * _memory_page_size;
size_t huge_peak = (size_t)_huge_pages_peak * _memory_page_size;
fprintf(file, "HugeCurrentMiB HugePeakMiB\n");
fprintf(file, "%14zu %11zu\n", huge_current / (size_t)(1024 * 1024), huge_peak / (size_t)(1024 * 1024));
size_t mapped = (size_t)atomic_load32(&_mapped_pages) * _memory_page_size;
size_t mapped_os = (size_t)atomic_load32(&_mapped_pages_os) * _memory_page_size;
size_t mapped_peak = (size_t)_mapped_pages_peak * _memory_page_size;
size_t mapped_total = (size_t)atomic_load32(&_mapped_total) * _memory_page_size;
size_t unmapped_total = (size_t)atomic_load32(&_unmapped_total) * _memory_page_size;
size_t reserved_total = (size_t)atomic_load32(&_reserved_spans) * _memory_span_size;
fprintf(file, "MappedMiB MappedOSMiB MappedPeakMiB MappedTotalMiB UnmappedTotalMiB ReservedTotalMiB\n");
fprintf(file, "%9zu %11zu %13zu %14zu %16zu %16zu\n",
mapped / (size_t)(1024 * 1024),
mapped_os / (size_t)(1024 * 1024),
mapped_peak / (size_t)(1024 * 1024),
mapped_total / (size_t)(1024 * 1024),
unmapped_total / (size_t)(1024 * 1024),
reserved_total / (size_t)(1024 * 1024));
fprintf(file, "\n");
#else
(void)sizeof(file);
#endif
}
}
#endif
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