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580e7f4fa3feae19f4939104d8a1d4c7f54fb4d0
hakmem/core/front/malloc_tiny_fast.h
Moe Charm (CI) 580e7f4fa3 Phase 5 E5-3: Candidate Analysis (All DEFERRED) + E5-4 Instructions 
E5-3 Analysis Results:
- free_tiny_fast_cold (7.14%): DEFER - cold path, low ROI
- unified_cache_push (3.39%): DEFER - already optimized
- hakmem_env_snapshot_enabled (2.97%): DEFER - low headroom

Key Insight: perf self% is time-weighted, not frequency-weighted.
Cold paths appear hot but have low total impact.

Next: E5-4 (Malloc Tiny Direct Path)
- Apply E5-1 winning pattern to malloc side
- Target: tiny_alloc_gate_fast() gate tax elimination
- ENV gate: HAKMEM_MALLOC_TINY_DIRECT=0/1

Files added:
- docs/analysis/PHASE5_E5_3_ANALYSIS_AND_RECOMMENDATIONS.md
- docs/analysis/PHASE5_E5_4_MALLOC_TINY_DIRECT_NEXT_INSTRUCTIONS.md
- core/box/free_cold_shape_env_box.{h,c} (research box, not tested)
- core/box/free_cold_shape_stats_box.{h,c} (research box, not tested)

🤖 Generated with [Claude Code](https://claude.com/claude-code)

Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com>
2025-12-14 06:44:04 +09:00

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// malloc_tiny_fast.h - Phase 26: Front Gate Unification (Tiny Fast Path)
//
// Goal: Eliminate 3-layer overhead (malloc → hak_alloc_at → wrapper → tiny_alloc_fast)
// Target: +10-15% performance (11.35M → 12.5-13.5M ops/s)
//
// Design (ChatGPT analysis):
// - Replace: malloc → hak_alloc_at (236 lines) → wrapper (diagnostics) → tiny_alloc_fast
// - With: malloc → malloc_tiny_fast (single-layer, direct to Unified Cache)
// - Preserves: Safety checks (lock depth, initializing, LD_SAFE, jemalloc block)
// - Leverages: Phase 23 Unified Cache (tcache-style, 2-3 cache misses)
//
// Performance:
// - Current overhead: malloc(8.97%) + routing + wrapper(3.63%) + tiny(5.37%) = 17.97%
// - BenchFast ceiling: 8-10 instructions (~1-2% overhead)
// - Gap: ~16%
// - Target: Close half the gap (+10-15% improvement)
//
// ENV Variables:
// HAKMEM_FRONT_GATE_UNIFIED=1 # Enable Front Gate Unification (default: 0, OFF)
#ifndef HAK_FRONT_MALLOC_TINY_FAST_H
#define HAK_FRONT_MALLOC_TINY_FAST_H
#include <stdint.h>
#include <stdlib.h>
#include <stdio.h>
#include <stdatomic.h>
#include <pthread.h> // For pthread_self() in cross-thread check
#include "../hakmem_build_flags.h"
#include "../hakmem_tiny_config.h" // For TINY_NUM_CLASSES
#include "../hakmem_super_registry.h" // For cross-thread owner check
#include "../superslab/superslab_inline.h" // For ss_fast_lookup, slab_index_for (Phase 12)
#include "../box/ss_slab_meta_box.h" // For ss_slab_meta_owner_tid_low_get
#include "../box/free_remote_box.h" // For tiny_free_remote_box
#include "tiny_unified_cache.h" // For unified_cache_pop_or_refill
#include "../tiny_region_id.h" // For tiny_region_id_write_header
#include "../hakmem_tiny.h" // For hak_tiny_size_to_class
#include "../box/tiny_env_box.h" // For tiny_env_cfg() (ENV variables)
#include "../box/tiny_front_hot_box.h" // Phase 4-Step2: Hot Path Box
#include "../box/tiny_front_cold_box.h" // Phase 4-Step2: Cold Path Box
#include "../box/tiny_c7_hotbox.h" // Optional: C7 専用ホットボックス
#include "../box/tiny_heap_box.h" // TinyHeap 汎用 Box
#include "../box/tiny_hotheap_v2_box.h" // TinyHotHeap v2 (Phase31 A/B)
#include "../box/smallobject_hotbox_v3_box.h" // SmallObject HotHeap v3 skeleton
#include "../box/smallobject_hotbox_v4_box.h" // SmallObject HotHeap v4 (C7 stub)
#include "../box/smallobject_hotbox_v5_box.h" // SmallObject HotHeap v5 (C6-only route stub, Phase v5-1)
#include "../box/smallobject_core_v6_box.h" // SmallObject Core v6 (Phase V6-HDR-2)
#include "../box/smallobject_v6_env_box.h" // SmallObject v6 ENV control (Phase V6-HDR-2)
#include "../box/smallobject_hotbox_v7_box.h" // SmallObject HotBox v7 stub (Phase v7-1)
#include "../box/smallobject_policy_v7_box.h" // Phase v7-4: Policy Box
#include "../box/tiny_static_route_box.h" // Phase 3 C3: Static routing (policy snapshot bypass)
#include "../box/smallobject_mid_v35_box.h" // Phase v11a-3: MID v3.5 HotBox
#include "../box/tiny_c7_ultra_box.h" // C7 ULTRA stub (UF-1, delegates to v3)
#include "../box/tiny_c6_ultra_free_box.h" // Phase 4-2: C6 ULTRA-free (free-only, C6-only)
#include "../box/tiny_c5_ultra_free_box.h" // Phase 5-1/5-2: C5 ULTRA-free + alloc integration
#include "../box/tiny_c4_ultra_free_box.h" // Phase 6: C4 ULTRA-free + alloc integration (cap=64)
#include "../box/tiny_ultra_tls_box.h" // Phase TLS-UNIFY-1: Unified ULTRA TLS API
#include "../box/tiny_ultra_classes_box.h" // Phase REFACTOR-1: Named constants for C4-C7
#include "../box/tiny_legacy_fallback_box.h" // Phase REFACTOR-2: Legacy fallback logic unification
#include "../box/tiny_ptr_convert_box.h" // Phase REFACTOR-3: Inline pointer macro centralization
#include "../box/tiny_front_v3_env_box.h" // Tiny front v3 snapshot gate
#include "../box/tiny_heap_env_box.h" // ENV gate for TinyHeap front (A/B)
#include "../box/tiny_route_env_box.h" // Route snapshot (Heap vs Legacy)
#include "../box/tiny_front_stats_box.h" // Front class distribution counters
#include "../box/free_path_stats_box.h" // Phase FREE-LEGACY-BREAKDOWN-1: Free path stats
#include "../box/alloc_gate_stats_box.h" // Phase ALLOC-GATE-OPT-1: Alloc gate stats
#include "../box/free_policy_fast_v2_box.h" // Phase POLICY-FAST-PATH-V2: Policy snapshot bypass
#include "../box/free_tiny_fast_hotcold_env_box.h" // Phase FREE-TINY-FAST-HOTCOLD-OPT-1: ENV control
#include "../box/free_tiny_fast_hotcold_stats_box.h" // Phase FREE-TINY-FAST-HOTCOLD-OPT-1: Stats
#include "../box/tiny_metadata_cache_hot_box.h" // Phase 3 C2: Policy hot cache (metadata cache optimization)
#include "../box/tiny_free_route_cache_env_box.h" // Phase 3 D1: Free path route cache
#include "../box/hakmem_env_snapshot_box.h" // Phase 4 E1: ENV snapshot consolidation
#include "../box/free_cold_shape_env_box.h" // Phase 5 E5-3a: Free cold path shape optimization
#include "../box/free_cold_shape_stats_box.h" // Phase 5 E5-3a: Free cold shape stats
// Helper: current thread id (low 32 bits) for owner check
#ifndef TINY_SELF_U32_LOCAL_DEFINED
#define TINY_SELF_U32_LOCAL_DEFINED
static inline uint32_t tiny_self_u32_local(void) {
return (uint32_t)(uintptr_t)pthread_self();
}
#endif
// ============================================================================
// ENV Control (cached, lazy init)
// ============================================================================
// Enable flag (default: 0, OFF)
static inline int front_gate_unified_enabled(void) {
static int g_enable = -1;
if (__builtin_expect(g_enable == -1, 0)) {
const char* e = getenv("HAKMEM_FRONT_GATE_UNIFIED");
g_enable = (e && *e && *e == '0') ? 0 : 1; // default ON
#if !HAKMEM_BUILD_RELEASE
if (g_enable) {
fprintf(stderr, "[FrontGate-INIT] front_gate_unified_enabled() = %d\n", g_enable);
fflush(stderr);
}
#endif
}
return g_enable;
}
// ============================================================================
// Phase REFACTOR-2: Legacy free helper (unified in tiny_legacy_fallback_box.h)
// ============================================================================
// Legacy free handling is encapsulated in tiny_legacy_fallback_box.h
// (Removed inline implementation to avoid duplication)
// ============================================================================
// Phase 4-Step2: malloc_tiny_fast() - Hot/Cold Path Box (ACTIVE)
// ============================================================================
// Ultra-thin Tiny allocation using Hot/Cold Path Box (Phase 4-Step2)
//
// IMPROVEMENTS over Phase 26-A:
// - Branch reduction: Hot path has only 1 branch (cache empty check)
// - Branch hints: TINY_HOT_LIKELY/UNLIKELY for better CPU prediction
// - Hot/Cold separation: Keeps hot path small (better i-cache locality)
// - Explicit fallback: Clear hot→cold transition
//
// PERFORMANCE:
// - Baseline (Phase 26-A, no PGO): 53.3 M ops/s
// - Hot/Cold Box (no PGO): 57.2 M ops/s (+7.3%)
//
// DESIGN:
// 1. size → class_idx (same as Phase 26-A)
// 2. Hot path: tiny_hot_alloc_fast() - cache hit (1 branch)
// 3. Cold path: tiny_cold_refill_and_alloc() - cache miss (noinline, cold)
//
// Preconditions:
// - Called AFTER malloc() safety checks (lock depth, initializing, LD_SAFE)
// - size <= tiny_get_max_size() (caller verified)
// Returns:
// - USER pointer on success
// - NULL on failure (caller falls back to normal path)
//
// Phase ALLOC-TINY-FAST-DUALHOT-2: Probe window ENV gate (safe from early putenv)
static inline int alloc_dualhot_enabled(void) {
static int g = -1;
static int g_probe_left = 64; // Probe window: tolerate early putenv before gate init
if (__builtin_expect(g == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_ALLOC_DUALHOT");
if (e && *e && *e != '0') {
g = 1;
} else if (g_probe_left > 0) {
g_probe_left--;
// Still probing: return "not yet set" without committing 0
if (e == NULL) {
return 0; // Env not set (yet), but keep probing
}
} else {
g = 0; // Probe window exhausted, commit to 0
}
}
return g;
}
// Phase 2 B3: tiny_alloc_route_cold() - Handle rare routes (V7, MID, ULTRA)
// NOTE: noinline to avoid code bloat in hot path, placed in cold section
__attribute__((noinline, cold))
static void* tiny_alloc_route_cold(SmallRouteKind route_kind, int class_idx, size_t size) {
switch (route_kind) {
case SMALL_ROUTE_ULTRA: {
// Phase TLS-UNIFY-1: Unified ULTRA TLS pop for C4-C6 (C7 handled above)
void* base = tiny_ultra_tls_pop((uint8_t)class_idx);
if (TINY_HOT_LIKELY(base != NULL)) {
if (class_idx == 6) FREE_PATH_STAT_INC(c6_ultra_alloc_hit);
else if (class_idx == 5) FREE_PATH_STAT_INC(c5_ultra_alloc_hit);
else if (class_idx == 4) FREE_PATH_STAT_INC(c4_ultra_alloc_hit);
return tiny_base_to_user_inline(base);
}
// ULTRA miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V35: {
// Phase v11a-3: MID v3.5 allocation
void* v35p = small_mid_v35_alloc(class_idx, size);
if (TINY_HOT_LIKELY(v35p != NULL)) {
return v35p;
}
// MID v3.5 miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_V7: {
// Phase v7: SmallObject v7 allocation (research box)
void* v7p = small_heap_alloc_fast_v7_stub(size, (uint8_t)class_idx);
if (TINY_HOT_LIKELY(v7p != NULL)) {
return v7p;
}
// V7 miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V3: {
// Phase MID-V3: MID v3 allocation (257-768B, C5-C6)
// Note: MID v3 uses same segment infrastructure as MID v3.5
// For now, delegate to MID v3.5 which handles both
void* v3p = small_mid_v35_alloc(class_idx, size);
if (TINY_HOT_LIKELY(v3p != NULL)) {
return v3p;
}
break;
}
case SMALL_ROUTE_LEGACY:
default:
break;
}
// Fallback: LEGACY unified cache hot/cold path
void* ptr = tiny_hot_alloc_fast(class_idx);
if (TINY_HOT_LIKELY(ptr != NULL)) {
return ptr;
}
return tiny_cold_refill_and_alloc(class_idx);
}
// Phase ALLOC-GATE-SSOT-1: malloc_tiny_fast_for_class() - body (class_idx already known)
__attribute__((always_inline))
static inline void* malloc_tiny_fast_for_class(size_t size, int class_idx) {
// Stats (class_idx already validated by gate)
tiny_front_alloc_stat_inc(class_idx);
ALLOC_GATE_STAT_INC_CLASS(class_idx);
// Phase v11a-5b: C7 ULTRA early-exit (skip policy snapshot for common case)
// This is the most common hot path - avoids TLS policy overhead
// Phase 4 E1: Use ENV snapshot when enabled (consolidates 3 TLS reads → 1)
bool c7_ultra_on;
if (__builtin_expect(hakmem_env_snapshot_enabled(), 0)) {
const HakmemEnvSnapshot* env = hakmem_env_snapshot();
c7_ultra_on = env->tiny_c7_ultra_enabled;
} else {
c7_ultra_on = tiny_c7_ultra_enabled_env();
}
if (class_idx == 7 && c7_ultra_on) {
void* ultra_p = tiny_c7_ultra_alloc(size);
if (TINY_HOT_LIKELY(ultra_p != NULL)) {
return ultra_p;
}
// C7 ULTRA miss → fall through to policy-based routing
}
// Phase ALLOC-TINY-FAST-DUALHOT-2: C0-C3 direct path (second hot path)
// Skip expensive policy snapshot and route determination for C0-C3.
// NOTE: Branch only taken if class_idx <= 3 (rare when OFF, frequent when ON)
if ((unsigned)class_idx <= 3u) {
if (alloc_dualhot_enabled()) {
// Direct to LEGACY unified cache (no policy snapshot)
void* ptr = tiny_hot_alloc_fast(class_idx);
if (TINY_HOT_LIKELY(ptr != NULL)) {
return ptr;
}
return tiny_cold_refill_and_alloc(class_idx);
}
}
// 2. Route selection: Static route table (Phase 3 C3) or policy hot cache (Phase 3 C2) or policy snapshot (default)
SmallRouteKind route_kind;
if (tiny_static_route_ready_fast()) {
route_kind = tiny_static_route_get_kind_fast(class_idx);
} else {
// Phase 3 C2: Use policy hot cache if enabled (eliminates policy_snapshot() call)
route_kind = tiny_policy_hot_get_route(class_idx);
}
// Phase 2 B3: Routing dispatch (ENV gate HAKMEM_TINY_ALLOC_ROUTE_SHAPE)
// Optimized: LIKELY on LEGACY (common case), cold helper for rare routes
const tiny_env_cfg_t* env_cfg = tiny_env_cfg();
if (TINY_HOT_LIKELY(env_cfg->alloc_route_shape)) {
// B3 optimized: Prioritize LEGACY with LIKELY hint
if (TINY_HOT_LIKELY(route_kind == SMALL_ROUTE_LEGACY)) {
// Phase 3 C1: TLS cache prefetch (prefetch g_unified_cache[class_idx] to L1)
if (__builtin_expect(env_cfg->tiny_prefetch, 0)) {
__builtin_prefetch(&g_unified_cache[class_idx], 0, 3);
}
// LEGACY fast path: Unified Cache hot/cold
void* ptr = tiny_hot_alloc_fast(class_idx);
if (TINY_HOT_LIKELY(ptr != NULL)) {
return ptr;
}
return tiny_cold_refill_and_alloc(class_idx);
}
// Rare routes: delegate to cold helper
return tiny_alloc_route_cold(route_kind, class_idx, size);
}
// Original dispatch (backward compatible, default)
// 3. Single switch on route_kind (all ENV checks moved to Policy init)
switch (route_kind) {
case SMALL_ROUTE_ULTRA: {
// Phase TLS-UNIFY-1: Unified ULTRA TLS pop for C4-C6 (C7 handled above)
void* base = tiny_ultra_tls_pop((uint8_t)class_idx);
if (TINY_HOT_LIKELY(base != NULL)) {
if (class_idx == 6) FREE_PATH_STAT_INC(c6_ultra_alloc_hit);
else if (class_idx == 5) FREE_PATH_STAT_INC(c5_ultra_alloc_hit);
else if (class_idx == 4) FREE_PATH_STAT_INC(c4_ultra_alloc_hit);
return tiny_base_to_user_inline(base);
}
// ULTRA miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V35: {
// Phase v11a-3: MID v3.5 allocation
void* v35p = small_mid_v35_alloc(class_idx, size);
if (TINY_HOT_LIKELY(v35p != NULL)) {
return v35p;
}
// MID v3.5 miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_V7: {
// Phase v7: SmallObject v7 allocation (research box)
void* v7p = small_heap_alloc_fast_v7_stub(size, (uint8_t)class_idx);
if (TINY_HOT_LIKELY(v7p != NULL)) {
return v7p;
}
// V7 miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V3: {
// Phase MID-V3: MID v3 allocation (257-768B, C5-C6)
// Note: MID v3 uses same segment infrastructure as MID v3.5
// For now, delegate to MID v3.5 which handles both
void* v3p = small_mid_v35_alloc(class_idx, size);
if (TINY_HOT_LIKELY(v3p != NULL)) {
return v3p;
}
break;
}
case SMALL_ROUTE_LEGACY:
default:
break;
}
// Phase 3 C1: TLS cache prefetch (prefetch g_unified_cache[class_idx] to L1)
if (__builtin_expect(env_cfg->tiny_prefetch, 0)) {
__builtin_prefetch(&g_unified_cache[class_idx], 0, 3);
}
// LEGACY fallback: Unified Cache hot/cold path
void* ptr = tiny_hot_alloc_fast(class_idx);
if (TINY_HOT_LIKELY(ptr != NULL)) {
return ptr;
}
return tiny_cold_refill_and_alloc(class_idx);
}
// Wrapper: size → class_idx conversion (SSOT)
__attribute__((always_inline))
static inline void* malloc_tiny_fast(size_t size) {
// Phase ALLOC-GATE-OPT-1: カウンタ散布 (1. 関数入口)
ALLOC_GATE_STAT_INC(total_calls);
// Phase ALLOC-GATE-SSOT-1: Single size→class conversion (SSOT)
ALLOC_GATE_STAT_INC(size_to_class_calls);
int class_idx = hak_tiny_size_to_class(size);
if (__builtin_expect(class_idx < 0 || class_idx >= TINY_NUM_CLASSES, 0)) {
return NULL;
}
// Delegate to *_for_class (stats tracked inside)
return malloc_tiny_fast_for_class(size, class_idx);
}
// ============================================================================
// Phase FREE-TINY-FAST-HOTCOLD-OPT-1: Hot/Cold split helpers
// ============================================================================
// Cold path: Cross-thread free, TinyHeap routes, and legacy fallback
// (noinline,cold to keep hot path small and I-cache clean)
__attribute__((noinline,cold))
static int free_tiny_fast_cold(void* ptr, void* base, int class_idx)
{
FREE_TINY_FAST_HOTCOLD_STAT_INC(cold_hit);
// Phase 3 D1: Free path route cache (eliminate tiny_route_for_class overhead)
tiny_route_kind_t route;
if (__builtin_expect(tiny_free_static_route_enabled(), 0)) {
// Use cached route (bypasses tiny_route_for_class())
route = g_tiny_route_class[(unsigned)class_idx & 7u];
if (__builtin_expect(route == TINY_ROUTE_LEGACY && !g_tiny_route_snapshot_done, 0)) {
// Fallback if uninitialized
route = tiny_route_for_class((uint8_t)class_idx);
}
} else {
// Standard path
route = tiny_route_for_class((uint8_t)class_idx);
}
const int use_tiny_heap = tiny_route_is_heap_kind(route);
// Phase 4 E1: Use ENV snapshot when enabled (consolidates 3 TLS reads → 1)
const TinyFrontV3Snapshot* front_snap;
if (__builtin_expect(hakmem_env_snapshot_enabled(), 0)) {
const HakmemEnvSnapshot* env = hakmem_env_snapshot();
front_snap = env->tiny_front_v3_enabled ? tiny_front_v3_snapshot_get() : NULL;
} else {
front_snap = __builtin_expect(tiny_front_v3_enabled(), 0) ? tiny_front_v3_snapshot_get() : NULL;
}
// TWO-SPEED: SuperSlab registration check is DEBUG-ONLY to keep HOT PATH fast.
// In Release builds, we trust header magic (0xA0) as sufficient validation.
#if !HAKMEM_BUILD_RELEASE
// Superslab 登録確認(誤分類防止)
SuperSlab* ss_guard = hak_super_lookup(ptr);
if (__builtin_expect(!(ss_guard && ss_guard->magic == SUPERSLAB_MAGIC), 0)) {
return 0; // hakmem 管理外 → 通常 free 経路へ
}
#endif // !HAKMEM_BUILD_RELEASE
// Phase 5 E5-3a: Optimized cold path shape
// Strategy: Handle common LEGACY path first (use_tiny_heap==0 in Mixed ~90%+)
// Defer expensive LARSON/cross-thread checks to only when heap routing needed
static __thread int g_cold_shape = -1;
if (__builtin_expect(g_cold_shape == -1, 0)) {
g_cold_shape = free_cold_shape_enabled() ? 1 : 0;
}
if (g_cold_shape == 1) {
// Optimized shape: Check use_tiny_heap FIRST
if (__builtin_expect(!use_tiny_heap, 1)) {
// Most common case in Mixed: LEGACY path, no heap routing
// Skip LARSON/cross-thread check entirely (not needed for legacy)
FREE_COLD_SHAPE_STAT_INC(legacy_fast);
FREE_COLD_SHAPE_STAT_INC(enabled_count);
goto legacy_fallback;
}
// Rare: heap routing needed, do full validation
FREE_COLD_SHAPE_STAT_INC(heap_path);
}
// Baseline shape: LARSON check first (current behavior)
// Cross-thread free detection (Larson MT crash fix, ENV gated) + TinyHeap free path
{
static __thread int g_larson_fix = -1;
if (__builtin_expect(g_larson_fix == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_LARSON_FIX");
g_larson_fix = (e && *e && *e != '0') ? 1 : 0;
#if !HAKMEM_BUILD_RELEASE
fprintf(stderr, "[LARSON_FIX_INIT] g_larson_fix=%d (env=%s)\n", g_larson_fix, e ? e : "NULL");
fflush(stderr);
#endif
}
if (__builtin_expect(g_larson_fix || use_tiny_heap, 0)) {
// Phase 12 optimization: Use fast mask-based lookup (~5-10 cycles vs 50-100)
SuperSlab* ss = ss_fast_lookup(base);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (5. super_lookup 呼び出し)
FREE_PATH_STAT_INC(super_lookup_called);
if (ss) {
int slab_idx = slab_index_for(ss, base);
if (__builtin_expect(slab_idx >= 0 && slab_idx < ss_slabs_capacity(ss), 1)) {
uint32_t self_tid = tiny_self_u32_local();
uint8_t owner_tid_low = ss_slab_meta_owner_tid_low_get(ss, slab_idx);
TinySlabMeta* meta = &ss->slabs[slab_idx];
// LARSON FIX: Use bits 8-15 for comparison (pthread TIDs aligned to 256 bytes)
uint8_t self_tid_cmp = (uint8_t)((self_tid >> 8) & 0xFFu);
#if !HAKMEM_BUILD_RELEASE
static _Atomic uint64_t g_owner_check_count = 0;
uint64_t oc = atomic_fetch_add(&g_owner_check_count, 1);
if (oc < 10) {
fprintf(stderr, "[LARSON_FIX] Owner check: ptr=%p owner_tid_low=0x%02x self_tid_cmp=0x%02x self_tid=0x%08x match=%d\n",
ptr, owner_tid_low, self_tid_cmp, self_tid, (owner_tid_low == self_tid_cmp));
fflush(stderr);
}
#endif
if (__builtin_expect(owner_tid_low != self_tid_cmp, 0)) {
// Cross-thread free → route to remote queue instead of poisoning TLS cache
FREE_TINY_FAST_HOTCOLD_STAT_INC(cold_cross_thread);
#if !HAKMEM_BUILD_RELEASE
static _Atomic uint64_t g_cross_thread_count = 0;
uint64_t ct = atomic_fetch_add(&g_cross_thread_count, 1);
if (ct < 20) {
fprintf(stderr, "[LARSON_FIX] Cross-thread free detected! ptr=%p owner_tid_low=0x%02x self_tid_cmp=0x%02x self_tid=0x%08x\n",
ptr, owner_tid_low, self_tid_cmp, self_tid);
fflush(stderr);
}
#endif
if (tiny_free_remote_box(ss, slab_idx, meta, ptr, self_tid)) {
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (6. cross-thread free)
FREE_PATH_STAT_INC(remote_free);
return 1; // handled via remote queue
}
return 0; // remote push failed; fall back to normal path
}
// Same-thread + TinyHeap route → route-based free
if (__builtin_expect(use_tiny_heap, 0)) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(cold_tinyheap);
switch (route) {
case TINY_ROUTE_SMALL_HEAP_V7: {
// Phase v7-1: C6-only v7 stub (MID v3 fallback)
if (small_heap_free_fast_v7_stub(ptr, (uint8_t)class_idx)) {
return 1;
}
break; // fallthrough to legacy
}
case TINY_ROUTE_SMALL_HEAP_V6: {
// Phase V6-HDR-2: Headerless free (ENV gated)
if (small_v6_headerless_route_enabled((uint8_t)class_idx)) {
SmallHeapCtxV6* ctx_v6 = small_heap_ctx_v6();
if (small_v6_headerless_free(ctx_v6, ptr, (uint8_t)class_idx)) {
return 1; // Handled by v6
}
// v6 returned false -> fallback to legacy
}
break; // fallthrough to legacy
}
// Phase v10: v3/v4/v5 removed - routes now handled as LEGACY
case TINY_ROUTE_HOTHEAP_V2:
tiny_hotheap_v2_free((uint8_t)class_idx, base, meta);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (v2 は tiny_heap_v1 にカウント)
FREE_PATH_STAT_INC(tiny_heap_v1_fast);
return 1;
case TINY_ROUTE_HEAP: {
tiny_heap_ctx_t* ctx = tiny_heap_ctx_for_thread();
if (class_idx == 7) {
tiny_c7_free_fast_with_meta(ss, slab_idx, base);
} else {
tiny_heap_free_class_fast_with_meta(ctx, class_idx, ss, slab_idx, base);
}
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (9. TinyHeap v1 route)
FREE_PATH_STAT_INC(tiny_heap_v1_fast);
return 1;
}
default:
break;
}
}
}
}
if (use_tiny_heap) {
// fallback: lookup failed but TinyHeap front is ON → use generic TinyHeap free
if (route == TINY_ROUTE_HOTHEAP_V2) {
tiny_hotheap_v2_record_free_fallback((uint8_t)class_idx);
}
// Phase v10: v3/v4 removed - no special fallback
tiny_heap_free_class_fast(tiny_heap_ctx_for_thread(), class_idx, ptr);
return 1;
}
}
}
// Debug: Log free operations (first 5000, all classes)
#if !HAKMEM_BUILD_RELEASE
{
extern _Atomic uint64_t g_debug_op_count;
extern __thread TinyTLSSLL g_tls_sll[];
uint64_t op = atomic_fetch_add(&g_debug_op_count, 1);
// Note: Shares g_debug_op_count with alloc logging, so bump the window.
if (op < 5000) {
fprintf(stderr, "[OP#%04lu FREE] cls=%d ptr=%p base=%p from=free_tiny_fast_cold tls_count_before=%u\n",
(unsigned long)op, class_idx, ptr, base,
g_tls_sll[class_idx].count);
fflush(stderr);
}
}
#endif
// Phase REFACTOR-2: Legacy fallback (use unified helper)
legacy_fallback:
FREE_TINY_FAST_HOTCOLD_STAT_INC(cold_legacy_fallback);
tiny_legacy_fallback_free_base(base, class_idx);
return 1;
}
// Hot path: Fast-path validation + ULTRA/MID/V7 routes
// (always_inline to minimize overhead on critical path)
__attribute__((always_inline))
static inline int free_tiny_fast_hot(void* ptr) {
if (__builtin_expect(!ptr, 0)) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(ret0_null_ptr);
return 0;
}
#if HAKMEM_TINY_HEADER_CLASSIDX
// 1. ページ境界ガード:
// ptr がページ先頭 (offset==0) の場合、ptr-1 は別ページか未マップ領域になる可能性がある。
// その場合はヘッダ読みを行わず、通常 free 経路にフォールバックする。
uintptr_t off = (uintptr_t)ptr & 0xFFFu;
if (__builtin_expect(off == 0, 0)) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(ret0_page_boundary);
return 0;
}
// 2. Fast header magic validation (必須)
// Release ビルドでは tiny_region_id_read_header() が magic を省略するため、
// ここで自前に Tiny 専用ヘッダ (0xA0) を検証しておく。
uint8_t* header_ptr = (uint8_t*)ptr - 1;
uint8_t header = *header_ptr;
uint8_t magic = header & 0xF0u;
if (__builtin_expect(magic != HEADER_MAGIC, 0)) {
// Tiny ヘッダではない → Mid/Large/外部ポインタなので通常 free 経路へ
FREE_TINY_FAST_HOTCOLD_STAT_INC(ret0_bad_magic);
return 0;
}
// 3. class_idx 抽出下位4bit
int class_idx = (int)(header & HEADER_CLASS_MASK);
if (__builtin_expect(class_idx < 0 || class_idx >= TINY_NUM_CLASSES, 0)) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(ret0_bad_class);
return 0;
}
// 4. BASE を計算して Unified Cache に push
void* base = tiny_user_to_base_inline(ptr);
tiny_front_free_stat_inc(class_idx);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (1. 関数入口)
FREE_PATH_STAT_INC(total_calls);
// Phase v11b-1: C7 ULTRA early-exit (skip policy snapshot for most common case)
// Phase 4 E1: Use ENV snapshot when enabled (consolidates 3 TLS reads → 1)
bool c7_ultra_free;
if (__builtin_expect(hakmem_env_snapshot_enabled(), 0)) {
const HakmemEnvSnapshot* env = hakmem_env_snapshot();
c7_ultra_free = env->tiny_c7_ultra_enabled;
} else {
c7_ultra_free = tiny_c7_ultra_enabled_env();
}
if (class_idx == 7 && c7_ultra_free) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_c7_ultra);
tiny_c7_ultra_free(ptr);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
// Phase FREE-TINY-FAST-DUALHOT-1: C0-C3 direct path (48% of calls)
// Skip expensive policy snapshot and route determination, direct to legacy fallback.
// Safety: Check Larson mode (cross-thread free handling requires full validation path)
{
static __thread int g_larson_fix = -1;
if (__builtin_expect(g_larson_fix == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_LARSON_FIX");
g_larson_fix = (e && *e && *e != '0') ? 1 : 0;
}
if (__builtin_expect(class_idx <= 3 && !g_larson_fix, 1)) {
// C0-C3 + Larson mode OFF → Direct to legacy (no policy snapshot overhead)
tiny_legacy_fallback_free_base(base, class_idx);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
}
// Phase POLICY-FAST-PATH-V2: Skip policy snapshot for known-legacy classes
if (free_policy_fast_v2_can_skip((uint8_t)class_idx)) {
FREE_PATH_STAT_INC(policy_fast_v2_skip);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_policy_fast_skip);
goto cold_path; // Delegate to cold path for legacy handling
}
// Phase v11b-1: Policy-based single switch (replaces serial ULTRA checks)
const SmallPolicyV7* policy_free = small_policy_v7_snapshot();
SmallRouteKind route_kind_free = policy_free->route_kind[class_idx];
switch (route_kind_free) {
case SMALL_ROUTE_ULTRA: {
// Phase TLS-UNIFY-1: Unified ULTRA TLS push for C4-C6 (C7 handled above)
if (class_idx >= 4 && class_idx <= 6) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_ultra_tls);
tiny_ultra_tls_push((uint8_t)class_idx, base);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
// ULTRA for other classes → fallback to cold path
break;
}
case SMALL_ROUTE_MID_V35: {
// Phase v11a-3: MID v3.5 free
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_mid_v35);
small_mid_v35_free(ptr, class_idx);
FREE_PATH_STAT_INC(smallheap_v7_fast);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
case SMALL_ROUTE_V7: {
// Phase v7: SmallObject v7 free (research box)
if (small_heap_free_fast_v7_stub(ptr, (uint8_t)class_idx)) {
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_v7);
FREE_PATH_STAT_INC(smallheap_v7_fast);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
// V7 miss → fallback to cold path
break;
}
case SMALL_ROUTE_MID_V3: {
// Phase MID-V3: delegate to MID v3.5
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_mid_v35);
small_mid_v35_free(ptr, class_idx);
FREE_PATH_STAT_INC(smallheap_v7_fast);
FREE_TINY_FAST_HOTCOLD_STAT_INC(hot_hit);
return 1;
}
case SMALL_ROUTE_LEGACY:
default:
break;
}
cold_path:
// Delegate to cold path for cross-thread, TinyHeap, and legacy handling
return free_tiny_fast_cold(ptr, base, class_idx);
#else
// No header mode - fall back to normal free
return 0;
#endif
}
// ============================================================================
// Phase 26-B: free_tiny_fast() - Ultra-thin Tiny deallocation
// ============================================================================
// Single-layer Tiny deallocation (bypasses hak_free_at + wrapper + diagnostics)
// Preconditions:
// - ptr is from malloc_tiny_fast() (has valid header)
// - Front Gate Unified is enabled
// Returns:
// - 1 on success (pushed to Unified Cache)
// - 0 on failure (caller falls back to normal free path)
__attribute__((always_inline))
static inline int free_tiny_fast(void* ptr) {
if (__builtin_expect(!ptr, 0)) return 0;
#if HAKMEM_TINY_HEADER_CLASSIDX
// 1. ページ境界ガード:
// ptr がページ先頭 (offset==0) の場合、ptr-1 は別ページか未マップ領域になる可能性がある。
// その場合はヘッダ読みを行わず、通常 free 経路にフォールバックする。
uintptr_t off = (uintptr_t)ptr & 0xFFFu;
if (__builtin_expect(off == 0, 0)) {
return 0;
}
// 2. Fast header magic validation (必須)
// Release ビルドでは tiny_region_id_read_header() が magic を省略するため、
// ここで自前に Tiny 専用ヘッダ (0xA0) を検証しておく。
uint8_t* header_ptr = (uint8_t*)ptr - 1;
uint8_t header = *header_ptr;
uint8_t magic = header & 0xF0u;
if (__builtin_expect(magic != HEADER_MAGIC, 0)) {
// Tiny ヘッダではない → Mid/Large/外部ポインタなので通常 free 経路へ
return 0;
}
// 3. class_idx 抽出下位4bit
int class_idx = (int)(header & HEADER_CLASS_MASK);
if (__builtin_expect(class_idx < 0 || class_idx >= TINY_NUM_CLASSES, 0)) {
return 0;
}
// 4. BASE を計算して Unified Cache に push
void* base = tiny_user_to_base_inline(ptr);
tiny_front_free_stat_inc(class_idx);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (1. 関数入口)
FREE_PATH_STAT_INC(total_calls);
// Phase v11b-1: C7 ULTRA early-exit (skip policy snapshot for most common case)
// Phase 4 E1: Use ENV snapshot when enabled (consolidates 3 TLS reads → 1)
bool c7_ultra_free;
if (__builtin_expect(hakmem_env_snapshot_enabled(), 0)) {
const HakmemEnvSnapshot* env = hakmem_env_snapshot();
c7_ultra_free = env->tiny_c7_ultra_enabled;
} else {
c7_ultra_free = tiny_c7_ultra_enabled_env();
}
if (class_idx == 7 && c7_ultra_free) {
tiny_c7_ultra_free(ptr);
return 1;
}
// Phase POLICY-FAST-PATH-V2: Skip policy snapshot for known-legacy classes
if (free_policy_fast_v2_can_skip((uint8_t)class_idx)) {
FREE_PATH_STAT_INC(policy_fast_v2_skip);
goto legacy_fallback;
}
// Phase v11b-1: Policy-based single switch (replaces serial ULTRA checks)
const SmallPolicyV7* policy_free = small_policy_v7_snapshot();
SmallRouteKind route_kind_free = policy_free->route_kind[class_idx];
switch (route_kind_free) {
case SMALL_ROUTE_ULTRA: {
// Phase TLS-UNIFY-1: Unified ULTRA TLS push for C4-C6 (C7 handled above)
if (class_idx >= 4 && class_idx <= 6) {
tiny_ultra_tls_push((uint8_t)class_idx, base);
return 1;
}
// ULTRA for other classes → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V35: {
// Phase v11a-3: MID v3.5 free
small_mid_v35_free(ptr, class_idx);
FREE_PATH_STAT_INC(smallheap_v7_fast);
return 1;
}
case SMALL_ROUTE_V7: {
// Phase v7: SmallObject v7 free (research box)
if (small_heap_free_fast_v7_stub(ptr, (uint8_t)class_idx)) {
FREE_PATH_STAT_INC(smallheap_v7_fast);
return 1;
}
// V7 miss → fallback to LEGACY
break;
}
case SMALL_ROUTE_MID_V3: {
// Phase MID-V3: delegate to MID v3.5
small_mid_v35_free(ptr, class_idx);
FREE_PATH_STAT_INC(smallheap_v7_fast);
return 1;
}
case SMALL_ROUTE_LEGACY:
default:
break;
}
legacy_fallback:
// LEGACY fallback path
// Phase 3 D1: Free path route cache (eliminate tiny_route_for_class overhead)
tiny_route_kind_t route;
if (__builtin_expect(tiny_free_static_route_enabled(), 0)) {
// Use cached route (bypasses tiny_route_for_class())
route = g_tiny_route_class[(unsigned)class_idx & 7u];
if (__builtin_expect(route == TINY_ROUTE_LEGACY && !g_tiny_route_snapshot_done, 0)) {
// Fallback if uninitialized
route = tiny_route_for_class((uint8_t)class_idx);
}
} else {
// Standard path
route = tiny_route_for_class((uint8_t)class_idx);
}
const int use_tiny_heap = tiny_route_is_heap_kind(route);
// Phase 4 E1: Use ENV snapshot when enabled (consolidates 3 TLS reads → 1)
const TinyFrontV3Snapshot* front_snap;
if (__builtin_expect(hakmem_env_snapshot_enabled(), 0)) {
const HakmemEnvSnapshot* env = hakmem_env_snapshot();
front_snap = env->tiny_front_v3_enabled ? tiny_front_v3_snapshot_get() : NULL;
} else {
front_snap = __builtin_expect(tiny_front_v3_enabled(), 0) ? tiny_front_v3_snapshot_get() : NULL;
}
// TWO-SPEED: SuperSlab registration check is DEBUG-ONLY to keep HOT PATH fast.
// In Release builds, we trust header magic (0xA0) as sufficient validation.
#if !HAKMEM_BUILD_RELEASE
// 5. Superslab 登録確認(誤分類防止)
SuperSlab* ss_guard = hak_super_lookup(ptr);
if (__builtin_expect(!(ss_guard && ss_guard->magic == SUPERSLAB_MAGIC), 0)) {
return 0; // hakmem 管理外 → 通常 free 経路へ
}
#endif // !HAKMEM_BUILD_RELEASE
// Cross-thread free detection (Larson MT crash fix, ENV gated) + TinyHeap free path
{
static __thread int g_larson_fix = -1;
if (__builtin_expect(g_larson_fix == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_LARSON_FIX");
g_larson_fix = (e && *e && *e != '0') ? 1 : 0;
#if !HAKMEM_BUILD_RELEASE
fprintf(stderr, "[LARSON_FIX_INIT] g_larson_fix=%d (env=%s)\n", g_larson_fix, e ? e : "NULL");
fflush(stderr);
#endif
}
if (__builtin_expect(g_larson_fix || use_tiny_heap, 0)) {
// Phase 12 optimization: Use fast mask-based lookup (~5-10 cycles vs 50-100)
SuperSlab* ss = ss_fast_lookup(base);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (5. super_lookup 呼び出し)
FREE_PATH_STAT_INC(super_lookup_called);
if (ss) {
int slab_idx = slab_index_for(ss, base);
if (__builtin_expect(slab_idx >= 0 && slab_idx < ss_slabs_capacity(ss), 1)) {
uint32_t self_tid = tiny_self_u32_local();
uint8_t owner_tid_low = ss_slab_meta_owner_tid_low_get(ss, slab_idx);
TinySlabMeta* meta = &ss->slabs[slab_idx];
// LARSON FIX: Use bits 8-15 for comparison (pthread TIDs aligned to 256 bytes)
uint8_t self_tid_cmp = (uint8_t)((self_tid >> 8) & 0xFFu);
#if !HAKMEM_BUILD_RELEASE
static _Atomic uint64_t g_owner_check_count = 0;
uint64_t oc = atomic_fetch_add(&g_owner_check_count, 1);
if (oc < 10) {
fprintf(stderr, "[LARSON_FIX] Owner check: ptr=%p owner_tid_low=0x%02x self_tid_cmp=0x%02x self_tid=0x%08x match=%d\n",
ptr, owner_tid_low, self_tid_cmp, self_tid, (owner_tid_low == self_tid_cmp));
fflush(stderr);
}
#endif
if (__builtin_expect(owner_tid_low != self_tid_cmp, 0)) {
// Cross-thread free → route to remote queue instead of poisoning TLS cache
#if !HAKMEM_BUILD_RELEASE
static _Atomic uint64_t g_cross_thread_count = 0;
uint64_t ct = atomic_fetch_add(&g_cross_thread_count, 1);
if (ct < 20) {
fprintf(stderr, "[LARSON_FIX] Cross-thread free detected! ptr=%p owner_tid_low=0x%02x self_tid_cmp=0x%02x self_tid=0x%08x\n",
ptr, owner_tid_low, self_tid_cmp, self_tid);
fflush(stderr);
}
#endif
if (tiny_free_remote_box(ss, slab_idx, meta, ptr, self_tid)) {
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (6. cross-thread free)
FREE_PATH_STAT_INC(remote_free);
return 1; // handled via remote queue
}
return 0; // remote push failed; fall back to normal path
}
// Same-thread + TinyHeap route → route-based free
if (__builtin_expect(use_tiny_heap, 0)) {
switch (route) {
case TINY_ROUTE_SMALL_HEAP_V7: {
// Phase v7-1: C6-only v7 stub (MID v3 fallback)
if (small_heap_free_fast_v7_stub(ptr, (uint8_t)class_idx)) {
return 1;
}
break; // fallthrough to legacy
}
case TINY_ROUTE_SMALL_HEAP_V6: {
// Phase V6-HDR-2: Headerless free (ENV gated)
if (small_v6_headerless_route_enabled((uint8_t)class_idx)) {
SmallHeapCtxV6* ctx_v6 = small_heap_ctx_v6();
if (small_v6_headerless_free(ctx_v6, ptr, (uint8_t)class_idx)) {
return 1; // Handled by v6
}
// v6 returned false -> fallback to legacy
}
break; // fallthrough to legacy
}
// Phase v10: v3/v4/v5 removed - routes now handled as LEGACY
case TINY_ROUTE_HOTHEAP_V2:
tiny_hotheap_v2_free((uint8_t)class_idx, base, meta);
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (v2 は tiny_heap_v1 にカウント)
FREE_PATH_STAT_INC(tiny_heap_v1_fast);
return 1;
case TINY_ROUTE_HEAP: {
tiny_heap_ctx_t* ctx = tiny_heap_ctx_for_thread();
if (class_idx == 7) {
tiny_c7_free_fast_with_meta(ss, slab_idx, base);
} else {
tiny_heap_free_class_fast_with_meta(ctx, class_idx, ss, slab_idx, base);
}
// Phase FREE-LEGACY-BREAKDOWN-1: カウンタ散布 (9. TinyHeap v1 route)
FREE_PATH_STAT_INC(tiny_heap_v1_fast);
return 1;
}
default:
break;
}
}
}
}
if (use_tiny_heap) {
// fallback: lookup failed but TinyHeap front is ON → use generic TinyHeap free
if (route == TINY_ROUTE_HOTHEAP_V2) {
tiny_hotheap_v2_record_free_fallback((uint8_t)class_idx);
}
// Phase v10: v3/v4 removed - no special fallback
tiny_heap_free_class_fast(tiny_heap_ctx_for_thread(), class_idx, ptr);
return 1;
}
}
}
// Debug: Log free operations (first 5000, all classes)
#if !HAKMEM_BUILD_RELEASE
{
extern _Atomic uint64_t g_debug_op_count;
extern __thread TinyTLSSLL g_tls_sll[];
uint64_t op = atomic_fetch_add(&g_debug_op_count, 1);
// Note: Shares g_debug_op_count with alloc logging, so bump the window.
if (op < 5000) {
fprintf(stderr, "[OP#%04lu FREE] cls=%d ptr=%p base=%p from=free_tiny_fast tls_count_before=%u\n",
(unsigned long)op, class_idx, ptr, base,
g_tls_sll[class_idx].count);
fflush(stderr);
}
}
#endif
// Phase REFACTOR-2: Legacy fallback (use unified helper)
tiny_legacy_fallback_free_base(base, class_idx);
return 1;
#else
// No header mode - fall back to normal free
return 0;
#endif
}
#endif // HAK_FRONT_MALLOC_TINY_FAST_H
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