cpython/Objects/mimalloc/segment-map.c

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/* ----------------------------------------------------------------------------
Copyright (c) 2019-2023, Microsoft Research, Daan Leijen
This is free software; you can redistribute it and/or modify it under the
terms of the MIT license. A copy of the license can be found in the file
"LICENSE" at the root of this distribution.
-----------------------------------------------------------------------------*/
/* -----------------------------------------------------------
The following functions are to reliably find the segment or
block that encompasses any pointer p (or NULL if it is not
in any of our segments).
We maintain a bitmap of all memory with 1 bit per MI_SEGMENT_SIZE (64MiB)
set to 1 if it contains the segment meta data.
----------------------------------------------------------- */
#include "mimalloc.h"
#include "mimalloc/internal.h"
#include "mimalloc/atomic.h"
#if (MI_INTPTR_SIZE==8)
#define MI_MAX_ADDRESS ((size_t)40 << 40) // 40TB (to include huge page areas)
#else
#define MI_MAX_ADDRESS ((size_t)2 << 30) // 2Gb
#endif
#define MI_SEGMENT_MAP_BITS (MI_MAX_ADDRESS / MI_SEGMENT_SIZE)
#define MI_SEGMENT_MAP_SIZE (MI_SEGMENT_MAP_BITS / 8)
#define MI_SEGMENT_MAP_WSIZE (MI_SEGMENT_MAP_SIZE / MI_INTPTR_SIZE)
static _Atomic(uintptr_t) mi_segment_map[MI_SEGMENT_MAP_WSIZE + 1]; // 2KiB per TB with 64MiB segments
static size_t mi_segment_map_index_of(const mi_segment_t* segment, size_t* bitidx) {
mi_assert_internal(_mi_ptr_segment(segment + 1) == segment); // is it aligned on MI_SEGMENT_SIZE?
if ((uintptr_t)segment >= MI_MAX_ADDRESS) {
*bitidx = 0;
return MI_SEGMENT_MAP_WSIZE;
}
else {
const uintptr_t segindex = ((uintptr_t)segment) / MI_SEGMENT_SIZE;
*bitidx = segindex % MI_INTPTR_BITS;
const size_t mapindex = segindex / MI_INTPTR_BITS;
mi_assert_internal(mapindex < MI_SEGMENT_MAP_WSIZE);
return mapindex;
}
}
void _mi_segment_map_allocated_at(const mi_segment_t* segment) {
size_t bitidx;
size_t index = mi_segment_map_index_of(segment, &bitidx);
mi_assert_internal(index <= MI_SEGMENT_MAP_WSIZE);
if (index==MI_SEGMENT_MAP_WSIZE) return;
uintptr_t mask = mi_atomic_load_relaxed(&mi_segment_map[index]);
uintptr_t newmask;
do {
newmask = (mask | ((uintptr_t)1 << bitidx));
} while (!mi_atomic_cas_weak_release(&mi_segment_map[index], &mask, newmask));
}
void _mi_segment_map_freed_at(const mi_segment_t* segment) {
size_t bitidx;
size_t index = mi_segment_map_index_of(segment, &bitidx);
mi_assert_internal(index <= MI_SEGMENT_MAP_WSIZE);
if (index == MI_SEGMENT_MAP_WSIZE) return;
uintptr_t mask = mi_atomic_load_relaxed(&mi_segment_map[index]);
uintptr_t newmask;
do {
newmask = (mask & ~((uintptr_t)1 << bitidx));
} while (!mi_atomic_cas_weak_release(&mi_segment_map[index], &mask, newmask));
}
// Determine the segment belonging to a pointer or NULL if it is not in a valid segment.
static mi_segment_t* _mi_segment_of(const void* p) {
if (p == NULL) return NULL;
mi_segment_t* segment = _mi_ptr_segment(p);
mi_assert_internal(segment != NULL);
size_t bitidx;
size_t index = mi_segment_map_index_of(segment, &bitidx);
// fast path: for any pointer to valid small/medium/large object or first MI_SEGMENT_SIZE in huge
const uintptr_t mask = mi_atomic_load_relaxed(&mi_segment_map[index]);
if mi_likely((mask & ((uintptr_t)1 << bitidx)) != 0) {
return segment; // yes, allocated by us
}
if (index==MI_SEGMENT_MAP_WSIZE) return NULL;
// TODO: maintain max/min allocated range for efficiency for more efficient rejection of invalid pointers?
// search downwards for the first segment in case it is an interior pointer
2024-09-09 09:58:26 -03:00
// could be slow but searches in MI_INTPTR_SIZE * MI_SEGMENT_SIZE (512MiB) steps through
// valid huge objects
// note: we could maintain a lowest index to speed up the path for invalid pointers?
size_t lobitidx;
size_t loindex;
uintptr_t lobits = mask & (((uintptr_t)1 << bitidx) - 1);
if (lobits != 0) {
loindex = index;
lobitidx = mi_bsr(lobits); // lobits != 0
}
else if (index == 0) {
return NULL;
}
else {
mi_assert_internal(index > 0);
uintptr_t lomask = mask;
loindex = index;
do {
loindex--;
lomask = mi_atomic_load_relaxed(&mi_segment_map[loindex]);
} while (lomask != 0 && loindex > 0);
if (lomask == 0) return NULL;
lobitidx = mi_bsr(lomask); // lomask != 0
}
mi_assert_internal(loindex < MI_SEGMENT_MAP_WSIZE);
// take difference as the addresses could be larger than the MAX_ADDRESS space.
size_t diff = (((index - loindex) * (8*MI_INTPTR_SIZE)) + bitidx - lobitidx) * MI_SEGMENT_SIZE;
segment = (mi_segment_t*)((uint8_t*)segment - diff);
if (segment == NULL) return NULL;
mi_assert_internal((void*)segment < p);
bool cookie_ok = (_mi_ptr_cookie(segment) == segment->cookie);
mi_assert_internal(cookie_ok);
if mi_unlikely(!cookie_ok) return NULL;
if (((uint8_t*)segment + mi_segment_size(segment)) <= (uint8_t*)p) return NULL; // outside the range
mi_assert_internal(p >= (void*)segment && (uint8_t*)p < (uint8_t*)segment + mi_segment_size(segment));
return segment;
}
// Is this a valid pointer in our heap?
static bool mi_is_valid_pointer(const void* p) {
return ((_mi_segment_of(p) != NULL) || (_mi_arena_contains(p)));
}
mi_decl_nodiscard mi_decl_export bool mi_is_in_heap_region(const void* p) mi_attr_noexcept {
return mi_is_valid_pointer(p);
}
/*
// Return the full segment range belonging to a pointer
static void* mi_segment_range_of(const void* p, size_t* size) {
mi_segment_t* segment = _mi_segment_of(p);
if (segment == NULL) {
if (size != NULL) *size = 0;
return NULL;
}
else {
if (size != NULL) *size = segment->segment_size;
return segment;
}
mi_assert_expensive(page == NULL || mi_segment_is_valid(_mi_page_segment(page),tld));
mi_assert_internal(page == NULL || (mi_segment_page_size(_mi_page_segment(page)) - (MI_SECURE == 0 ? 0 : _mi_os_page_size())) >= block_size);
mi_reset_delayed(tld);
mi_assert_internal(page == NULL || mi_page_not_in_queue(page, tld));
return page;
}
*/