hakmem/core/hakmem_tiny_slow.inc

// hakmem_tiny_slow.inc
// Slow path allocation implementation

// Slow path allocation function
// Phase 6-1.7: Export for box refactor (Box 5 needs access from hakmem.c)
#ifdef HAKMEM_TINY_PHASE6_BOX_REFACTOR
void* __attribute__((cold, noinline)) hak_tiny_alloc_slow(size_t size, int class_idx) {
#else
static void* __attribute__((cold, noinline)) hak_tiny_alloc_slow(size_t size, int class_idx) {
#endif
    (void)size; // size is already validated by caller

    if (class_idx < 0 || class_idx >= TINY_NUM_CLASSES) {
        return NULL;
    }

    // Try refilling from HotMag
    if (g_hotmag_enable && class_idx <= 3) {
        TinyHotMag* hm = &g_tls_hot_mag[class_idx];
        hotmag_try_refill(class_idx, hm);
        void* ptr = hotmag_pop(class_idx);
        if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }
    }

    // Try TLS list refill
    if (g_tls_list_enable) {
        TinyTLSList* tls = &g_tls_lists[class_idx];
        if (tls->count > 0) {
            void* ptr = tls_list_pop(tls);
            if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }
            // ptr が NULL の場合でも、ここで終了せず後段の Superslab 経路へフォールバックする
        }

        // Try refilling TLS list from slab
        uint32_t want = tls->refill_low > 0 ? tls->refill_low : 32;
        if (tls_refill_from_tls_slab(class_idx, tls, want) > 0) {
            void* ptr = tls_list_pop(tls);
            if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }
            // ここでも NULL の場合は続行（後段へフォールバック）
        }
    }

    // Final fallback: allocate from superslab
    void* ss_ptr = hak_tiny_alloc_superslab(class_idx);
    if (ss_ptr) { HAK_RET_ALLOC(class_idx, ss_ptr); }
    tiny_alloc_dump_tls_state(class_idx, "slow_fail", &g_tls_slabs[class_idx]);
    // Optional one-shot debug when final slow path fails
    static int g_alloc_dbg = -1; if (__builtin_expect(g_alloc_dbg == -1, 0)) { const char* e=getenv("HAKMEM_TINY_ALLOC_DEBUG"); g_alloc_dbg = (e && atoi(e)!=0)?1:0; }
    if (g_alloc_dbg) {
        static _Atomic int printed[8]; int exp=0;
        if (atomic_compare_exchange_strong(&printed[class_idx], &exp, 1)) {
            fprintf(stderr, "[ALLOC-SLOW] hak_tiny_alloc_superslab returned NULL class=%d size=%zu\n", class_idx, size);
        }
    }
    return ss_ptr;
}
Debug Counters Implementation - Clean History Major Features: - Debug counter infrastructure for Refill Stage tracking - Free Pipeline counters (ss_local, ss_remote, tls_sll) - Diagnostic counters for early return analysis - Unified larson.sh benchmark runner with profiles - Phase 6-3 regression analysis documentation Bug Fixes: - Fix SuperSlab disabled by default (HAKMEM_TINY_USE_SUPERSLAB) - Fix profile variable naming consistency - Add .gitignore patterns for large files Performance: - Phase 6-3: 4.79 M ops/s (has OOM risk) - With SuperSlab: 3.13 M ops/s (+19% improvement) This is a clean repository without large log files. 🤖 Generated with [Claude Code](https://claude.com/claude-code) Co-Authored-By: Claude <noreply@anthropic.com> 2025-11-05 12:31:14 +09:00			`// hakmem_tiny_slow.inc`
			`// Slow path allocation implementation`

			`// Slow path allocation function`
			`// Phase 6-1.7: Export for box refactor (Box 5 needs access from hakmem.c)`
			`#ifdef HAKMEM_TINY_PHASE6_BOX_REFACTOR`
			`void* __attribute__((cold, noinline)) hak_tiny_alloc_slow(size_t size, int class_idx) {`
			`#else`
			`static void* __attribute__((cold, noinline)) hak_tiny_alloc_slow(size_t size, int class_idx) {`
			`#endif`
			`(void)size; // size is already validated by caller`

			`if (class_idx < 0 \|\| class_idx >= TINY_NUM_CLASSES) {`
			`return NULL;`
			`}`

			`// Try refilling from HotMag`
			`if (g_hotmag_enable && class_idx <= 3) {`
			`TinyHotMag* hm = &g_tls_hot_mag[class_idx];`
			`hotmag_try_refill(class_idx, hm);`
			`void* ptr = hotmag_pop(class_idx);`
			`if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }`
			`}`

			`// Try TLS list refill`
			`if (g_tls_list_enable) {`
			`TinyTLSList* tls = &g_tls_lists[class_idx];`
			`if (tls->count > 0) {`
			`void* ptr = tls_list_pop(tls);`
			`if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }`
			`// ptr が NULL の場合でも、ここで終了せず後段の Superslab 経路へフォールバックする`
			`}`

			`// Try refilling TLS list from slab`
			`uint32_t want = tls->refill_low > 0 ? tls->refill_low : 32;`
			`if (tls_refill_from_tls_slab(class_idx, tls, want) > 0) {`
			`void* ptr = tls_list_pop(tls);`
			`if (ptr) { HAK_RET_ALLOC(class_idx, ptr); }`
			`// ここでも NULL の場合は続行（後段へフォールバック）`
			`}`
			`}`

			`// Final fallback: allocate from superslab`
			`void* ss_ptr = hak_tiny_alloc_superslab(class_idx);`
			`if (ss_ptr) { HAK_RET_ALLOC(class_idx, ss_ptr); }`
			`tiny_alloc_dump_tls_state(class_idx, "slow_fail", &g_tls_slabs[class_idx]);`
			`// Optional one-shot debug when final slow path fails`
			`static int g_alloc_dbg = -1; if (__builtin_expect(g_alloc_dbg == -1, 0)) { const char* e=getenv("HAKMEM_TINY_ALLOC_DEBUG"); g_alloc_dbg = (e && atoi(e)!=0)?1:0; }`
			`if (g_alloc_dbg) {`
			`static _Atomic int printed[8]; int exp=0;`
			`if (atomic_compare_exchange_strong(&printed[class_idx], &exp, 1)) {`
			`fprintf(stderr, "[ALLOC-SLOW] hak_tiny_alloc_superslab returned NULL class=%d size=%zu\n", class_idx, size);`
			`}`
			`}`
			`return ss_ptr;`
			`}`