| name | custom-allocators |
| description | Custom allocator skill for memory allocation strategies. Use when implementing pool/slab/arena allocators, tuning jemalloc/mimalloc, writing Rust GlobalAlloc, or benchmarking allocator performance. Activates on queries about jemalloc, mimalloc, tcmalloc, arena allocator, GlobalAlloc, or fragmentation. |
Custom Allocators
Purpose
Guide agents through memory allocator design and tuning: pool/slab/arena/buddy taxonomy, jemalloc internals and MALLOC_CONF, mimalloc design, tcmalloc thread-caching, writing a simple pool allocator in C, Rust GlobalAlloc trait, fragmentation metrics, and benchmarking.
When to Use
- Replacing malloc for latency-sensitive or embedded workloads
- Tuning jemalloc/mimalloc for server heap behavior
- Implementing arena allocation for request-scoped or frame-based lifetimes
- Writing a Rust custom global allocator for
no_std or performance
- Diagnosing heap fragmentation (internal vs external)
- Benchmarking allocator throughput and latency
Workflow
1. Allocator taxonomy
Allocator types
├── Pool/fixed-size — O(1) alloc/free, fixed block sizes
├── Slab — kernel-style, cache-friendly size classes
├── Arena/bump — fast alloc, bulk free (reset arena)
├── Buddy — power-of-two blocks, low fragmentation for large allocs
└── General (malloc) — jemalloc, mimalloc, tcmalloc
2. Simple pool allocator in C
#include <stddef.h>
#include <stdint.h>
#include <stdlib.h>
typedef struct pool_block {
struct pool_block *next;
} pool_block_t;
typedef struct {
void *memory;
size_t block_size;
size_t num_blocks;
pool_block_t *free_list;
} pool_t;
int pool_init(pool_t *p, size_t block_size, size_t num_blocks) {
p->block_size = block_size < sizeof(pool_block_t) ?
sizeof(pool_block_t) : block_size;
p->num_blocks = num_blocks;
p->memory = aligned_alloc(64, p->block_size * num_blocks);
if (!p->memory) return -1;
p->free_list = NULL;
for (size_t i = 0; i < num_blocks; i++) {
pool_block_t *blk = (pool_block_t *)((char *)p->memory + i * p->block_size);
blk->next = p->free_list;
p->free_list = blk;
}
return 0;
}
void *pool_alloc(pool_t *p) {
if (!p->free_list) return NULL;
pool_block_t *blk = p->free_list;
p->free_list = blk->next;
return blk;
}
void pool_free(pool_t *p, void *ptr) {
pool_block_t *blk = (pool_block_t *)ptr;
blk->next = p->free_list;
p->free_list = blk;
}
3. Arena allocator
typedef struct {
char *base;
size_t capacity;
size_t offset;
} arena_t;
void *arena_alloc(arena_t *a, size_t size, size_t align) {
uintptr_t cur = (uintptr_t)(a->base + a->offset);
uintptr_t aligned = (cur + align - 1) & ~(align - 1);
size_t padding = aligned - cur;
if (a->offset + padding + size > a->capacity)
return NULL;
a->offset += padding + size;
return (void *)aligned;
}
void arena_reset(arena_t *a) { a->offset = 0; }
Use per-request arenas in servers — reset after response, no per-object free.
4. jemalloc tuning
LD_PRELOAD=/usr/lib/x86_64-linux-gnu/libjemalloc.so.2 ./myapp
export MALLOC_CONF="background_thread:true,dirty_decay_ms:1000,muzzy_decay_ms:1000"
export MALLOC_CONF="prof:true,prof_active:true,lg_prof_sample:19"
jemalloc concepts:
- Size classes — rounded allocation sizes
- tcache — per-thread cache for hot sizes
- arenas — reduce contention across threads
export MALLOC_CONF="stats_print:true"
mallctl("epoch", ...); mallctl("stats.allocated", ...);
5. mimalloc
LD_PRELOAD=/usr/lib/libmimalloc.so ./myapp
export MIMALLOC_SHOW_STATS=1
export MIMALLOC_PAGE_RESET=1
mimalloc hierarchy: segment → page → block. Generally lower metadata overhead than jemalloc.
MIMALLOC_SHOW_STATS=1 ./myapp
6. tcmalloc thread-caching
LD_PRELOAD=/usr/lib/x86_64-linux-gnu/libtcmalloc.so.4 ./myapp
export TCMALLOC_SAMPLE_PARAMETER=524288
Per-thread caches for small objects; central heap for larger allocations.
7. Rust GlobalAlloc
use std::alloc::{GlobalAlloc, Layout, System};
use std::sync::atomic::{AtomicUsize, Ordering};
struct TrackingAllocator;
static ALLOCATED: AtomicUsize = AtomicUsize::new(0);
unsafe impl GlobalAlloc for TrackingAllocator {
unsafe fn alloc(&self, layout: Layout) -> *mut u8 {
let ptr = System.alloc(layout);
if !ptr.is_null() {
ALLOCATED.fetch_add(layout.size(), Ordering::Relaxed);
}
ptr
}
unsafe fn dealloc(&self, ptr: *mut u8, layout: Layout) {
System.dealloc(ptr, layout);
ALLOCATED.fetch_sub(layout.size(), Ordering::Relaxed);
}
}
#[global_allocator]
static GLOBAL: TrackingAllocator = TrackingAllocator;
For #![no_std] with alloc crate, implement GlobalAlloc without System.
8. Fragmentation metrics
| Type | Definition | Detection |
|---|
| Internal | Allocated block larger than requested | Allocator stats; size class rounding |
| External | Free memory not usable for request | mallinfo/malloc_info; RSS vs heap |
malloc_info(0, stdout);
jeprof --show_bytes ./myapp jeprof.heap
9. Benchmarking
cd mimalloc && mkdir build && cd build
cmake .. && make
./mimalloc-bench
perf stat -e cycles,instructions ./allocator_bench --threads 8 --size 64
Compare: single-thread alloc/free, multi-thread contention, mixed size distribution.
Common Problems
| Symptom | Cause | Fix |
|---|
| Pool alloc returns NULL | Free list exhausted | Increase pool size; leak check |
| jemalloc RSS won't drop | Dirty page decay slow | Lower dirty_decay_ms; madvise |
| Arena OOM | No reset between phases | arena_reset or chain arenas |
| Rust allocator UB | Wrong Layout in dealloc | Store size/align with allocation |
| Worse perf with mimalloc | Wrong workload fit | Benchmark; try jemalloc |
| High external fragmentation | Long-lived mixed sizes | Segregate by lifetime; pools |
Related Skills
skills/allocators/numa-programming — NUMA-aware allocation
skills/rust/rust-no-std — custom allocators in embedded Rust
skills/profilers/heaptrack — allocation hotspot profiling
skills/profilers/valgrind — heap leak detection
skills/low-level-programming/cpu-cache-opt — allocator alignment and false sharing
skills/kernel/kernel-internals — SLUB/buddy kernel allocators