hakmem/core/hakmem_tiny_lazy_init.inc.h

// hakmem_tiny_lazy_init.inc.h - Phase 22: Lazy Per-Class Initialization
// Goal: Reduce cold-start page faults by initializing only used classes
//
// ChatGPT Analysis (2025-11-16):
//   - hak_tiny_init() page faults: 94.94% of all page faults
//   - Cause: Eager init of all 8 classes even if only C2/C3 used
//   - Solution: Lazy init per class on first use
//
// Expected Impact:
//   - Page faults: -90% (only touch C2/C3 for 256B workload)
//   - Cold start: +30-40% performance (16.2M → 22-25M ops/s)

#ifndef HAKMEM_TINY_LAZY_INIT_INC_H
#define HAKMEM_TINY_LAZY_INIT_INC_H

#include <pthread.h>
#include <stdint.h>
#include "superslab/superslab_types.h"  // For SuperSlabACEState

// ============================================================================
// Phase 22-1: Per-Class Initialization State
// ============================================================================

// Track which classes are initialized (per-thread)
__thread uint8_t g_class_initialized[TINY_NUM_CLASSES] = {0};

// Global one-time init flag (for shared resources)
static int g_tiny_global_initialized = 0;
static pthread_mutex_t g_lazy_init_lock = PTHREAD_MUTEX_INITIALIZER;

// ============================================================================
// Phase 22-2: Lazy Init Implementation
// ============================================================================

// Initialize one class lazily (called on first use)
static inline void lazy_init_class(int class_idx) {
    // Fast path: already initialized
    if (__builtin_expect(g_class_initialized[class_idx], 1)) {
        return;
    }

    // Slow path: need to initialize this class
    pthread_mutex_lock(&g_lazy_init_lock);

    // Double-check after acquiring lock
    if (g_class_initialized[class_idx]) {
        pthread_mutex_unlock(&g_lazy_init_lock);
        return;
    }

    // Extract from hak_tiny_init.inc lines 84-103: TLS List Init
    {
        TinyTLSList* tls = &g_tls_lists[class_idx];
        tls->head = NULL;
        tls->count = 0;
        uint32_t base_cap = (uint32_t)tiny_default_cap(class_idx);
        uint32_t class_max = (uint32_t)tiny_cap_max_for_class(class_idx);
        if (base_cap > class_max) base_cap = class_max;

        // Apply global cap limit if set
        extern int g_mag_cap_limit;
        extern int g_mag_cap_override[TINY_NUM_CLASSES];
        if ((uint32_t)g_mag_cap_limit < base_cap) base_cap = (uint32_t)g_mag_cap_limit;
        if (g_mag_cap_override[class_idx] > 0) {
            uint32_t ov = (uint32_t)g_mag_cap_override[class_idx];
            if (ov > class_max) ov = class_max;
            if (ov > (uint32_t)g_mag_cap_limit) ov = (uint32_t)g_mag_cap_limit;
            if (ov != 0u) base_cap = ov;
        }
        if (base_cap == 0u) base_cap = 32u;

        tls->cap = base_cap;
        tls->refill_low = tiny_tls_default_refill(base_cap);
        tls->spill_high = tiny_tls_default_spill(base_cap);
        tiny_tls_publish_targets(class_idx, base_cap);
    }

    // Extract from hak_tiny_init.inc lines 623-625: Per-class lock
    pthread_mutex_init(&g_tiny_class_locks[class_idx].m, NULL);

    // Extract from hak_tiny_init.inc lines 628-637: ACE state
    {
        extern SuperSlabACEState g_ss_ace[TINY_NUM_CLASSES];
        g_ss_ace[class_idx].current_lg = 20;  // Start with 1MB SuperSlabs
        g_ss_ace[class_idx].target_lg = 20;
        g_ss_ace[class_idx].hot_score = 0;
        g_ss_ace[class_idx].alloc_count = 0;
        g_ss_ace[class_idx].refill_count = 0;
        g_ss_ace[class_idx].spill_count = 0;
        g_ss_ace[class_idx].live_blocks = 0;
        g_ss_ace[class_idx].last_tick_ns = 0;
    }

    // Mark as initialized
    g_class_initialized[class_idx] = 1;

    pthread_mutex_unlock(&g_lazy_init_lock);

#if !HAKMEM_BUILD_RELEASE
    fprintf(stderr, "[LAZY_INIT] Class %d initialized\n", class_idx);
#endif
}

// Global initialization (called once, for non-class resources)
static inline void lazy_init_global(void) {
    if (__builtin_expect(g_tiny_global_initialized, 1)) {
        return;
    }

    pthread_mutex_lock(&g_lazy_init_lock);

    if (g_tiny_global_initialized) {
        pthread_mutex_unlock(&g_lazy_init_lock);
        return;
    }

    // Initialize SuperSlab subsystem (only once)
    extern int g_use_superslab;
    if (g_use_superslab) {
        extern void hak_super_registry_init(void);
        extern void hak_ss_lru_init(void);
        extern void hak_ss_prewarm_init(void);

        hak_super_registry_init();
        hak_ss_lru_init();
        hak_ss_prewarm_init();
    }

    // Mark global resources as initialized
    g_tiny_global_initialized = 1;

    pthread_mutex_unlock(&g_lazy_init_lock);

#if !HAKMEM_BUILD_RELEASE
    fprintf(stderr, "[LAZY_INIT] Global resources initialized\n");
#endif
}

#endif // HAKMEM_TINY_LAZY_INIT_INC_H
Phase 23 Unified Cache + PageFaultTelemetry generalization: Mid/VM page-fault bottleneck identified Summary: - Phase 23 Unified Cache: +30% improvement (Random Mixed 256B: 18.18M → 23.68M ops/s) - PageFaultTelemetry: Extended to generic buckets (C0-C7, MID, L25, SSM) - Measurement-driven decision: Mid/VM page-faults (80-100K) >> Tiny (6K) → prioritize Mid/VM optimization Phase 23 Changes: 1. Unified Cache implementation (core/front/tiny_unified_cache.{c,h}) - Direct SuperSlab carve (TLS SLL bypass) - Self-contained pop-or-refill pattern - ENV: HAKMEM_TINY_UNIFIED_CACHE=1, HAKMEM_TINY_UNIFIED_C{0-7}=128 2. Fast path pruning (tiny_alloc_fast.inc.h, tiny_free_fast_v2.inc.h) - Unified ON → direct cache access (skip all intermediate layers) - Alloc: unified_cache_pop_or_refill() → immediate fail to slow - Free: unified_cache_push() → fallback to SLL only if full PageFaultTelemetry Changes: 3. Generic bucket architecture (core/box/pagefault_telemetry_box.{c,h}) - PF_BUCKET_{C0-C7, MID, L25, SSM} for domain-specific measurement - Integration: hak_pool_try_alloc(), l25_alloc_new_run(), shared_pool_allocate_superslab_unlocked() 4. Measurement results (Random Mixed 500K / 256B): - Tiny C2-C7: 2-33 pages, high reuse (64-3.8 touches/page) - SSM: 512 pages (initialization footprint) - MID/L25: 0 (unused in this workload) - Mid/Large VM benchmarks: 80-100K page-faults (13-16x higher than Tiny) Ring Cache Enhancements: 5. Hot Ring Cache (core/front/tiny_ring_cache.{c,h}) - ENV: HAKMEM_TINY_HOT_RING_ENABLE=1, HAKMEM_TINY_HOT_RING_C{0-7}=size - Conditional compilation cleanup Documentation: 6. Analysis reports - RANDOM_MIXED_BOTTLENECK_ANALYSIS.md: Page-fault breakdown - RANDOM_MIXED_SUMMARY.md: Phase 23 summary - RING_CACHE_ACTIVATION_GUIDE.md: Ring cache usage - CURRENT_TASK.md: Updated with Phase 23 results and Phase 24 plan Next Steps (Phase 24): - Target: Mid/VM PageArena/HotSpanBox (page-fault reduction 80-100K → 30-40K) - Tiny SSM optimization deferred (low ROI, ~6K page-faults already optimal) - Expected improvement: +30-50% for Mid/Large workloads Generated with Claude Code Co-Authored-By: Claude <noreply@anthropic.com> 2025-11-17 02:47:58 +09:00			`// hakmem_tiny_lazy_init.inc.h - Phase 22: Lazy Per-Class Initialization`
			`// Goal: Reduce cold-start page faults by initializing only used classes`
			`//`
			`// ChatGPT Analysis (2025-11-16):`
			`// - hak_tiny_init() page faults: 94.94% of all page faults`
			`// - Cause: Eager init of all 8 classes even if only C2/C3 used`
			`// - Solution: Lazy init per class on first use`
			`//`
			`// Expected Impact:`
			`// - Page faults: -90% (only touch C2/C3 for 256B workload)`
			`// - Cold start: +30-40% performance (16.2M → 22-25M ops/s)`

			`#ifndef HAKMEM_TINY_LAZY_INIT_INC_H`
			`#define HAKMEM_TINY_LAZY_INIT_INC_H`

			`#include <pthread.h>`
			`#include <stdint.h>`
			`#include "superslab/superslab_types.h" // For SuperSlabACEState`

			`// ============================================================================`
			`// Phase 22-1: Per-Class Initialization State`
			`// ============================================================================`

			`// Track which classes are initialized (per-thread)`
			`__thread uint8_t g_class_initialized[TINY_NUM_CLASSES] = {0};`

			`// Global one-time init flag (for shared resources)`
			`static int g_tiny_global_initialized = 0;`
			`static pthread_mutex_t g_lazy_init_lock = PTHREAD_MUTEX_INITIALIZER;`

			`// ============================================================================`
			`// Phase 22-2: Lazy Init Implementation`
			`// ============================================================================`

			`// Initialize one class lazily (called on first use)`
			`static inline void lazy_init_class(int class_idx) {`
			`// Fast path: already initialized`
			`if (__builtin_expect(g_class_initialized[class_idx], 1)) {`
			`return;`
			`}`

			`// Slow path: need to initialize this class`
			`pthread_mutex_lock(&g_lazy_init_lock);`

			`// Double-check after acquiring lock`
			`if (g_class_initialized[class_idx]) {`
			`pthread_mutex_unlock(&g_lazy_init_lock);`
			`return;`
			`}`

			`// Extract from hak_tiny_init.inc lines 84-103: TLS List Init`
			`{`
			`TinyTLSList* tls = &g_tls_lists[class_idx];`
			`tls->head = NULL;`
			`tls->count = 0;`
			`uint32_t base_cap = (uint32_t)tiny_default_cap(class_idx);`
			`uint32_t class_max = (uint32_t)tiny_cap_max_for_class(class_idx);`
			`if (base_cap > class_max) base_cap = class_max;`

			`// Apply global cap limit if set`
			`extern int g_mag_cap_limit;`
			`extern int g_mag_cap_override[TINY_NUM_CLASSES];`
			`if ((uint32_t)g_mag_cap_limit < base_cap) base_cap = (uint32_t)g_mag_cap_limit;`
			`if (g_mag_cap_override[class_idx] > 0) {`
			`uint32_t ov = (uint32_t)g_mag_cap_override[class_idx];`
			`if (ov > class_max) ov = class_max;`
			`if (ov > (uint32_t)g_mag_cap_limit) ov = (uint32_t)g_mag_cap_limit;`
			`if (ov != 0u) base_cap = ov;`
			`}`
			`if (base_cap == 0u) base_cap = 32u;`

			`tls->cap = base_cap;`
			`tls->refill_low = tiny_tls_default_refill(base_cap);`
			`tls->spill_high = tiny_tls_default_spill(base_cap);`
			`tiny_tls_publish_targets(class_idx, base_cap);`
			`}`

			`// Extract from hak_tiny_init.inc lines 623-625: Per-class lock`
			`pthread_mutex_init(&g_tiny_class_locks[class_idx].m, NULL);`

			`// Extract from hak_tiny_init.inc lines 628-637: ACE state`
			`{`
			`extern SuperSlabACEState g_ss_ace[TINY_NUM_CLASSES];`
			`g_ss_ace[class_idx].current_lg = 20; // Start with 1MB SuperSlabs`
			`g_ss_ace[class_idx].target_lg = 20;`
			`g_ss_ace[class_idx].hot_score = 0;`
			`g_ss_ace[class_idx].alloc_count = 0;`
			`g_ss_ace[class_idx].refill_count = 0;`
			`g_ss_ace[class_idx].spill_count = 0;`
			`g_ss_ace[class_idx].live_blocks = 0;`
			`g_ss_ace[class_idx].last_tick_ns = 0;`
			`}`

			`// Mark as initialized`
			`g_class_initialized[class_idx] = 1;`

			`pthread_mutex_unlock(&g_lazy_init_lock);`

			`#if !HAKMEM_BUILD_RELEASE`
			`fprintf(stderr, "[LAZY_INIT] Class %d initialized\n", class_idx);`
			`#endif`
			`}`

			`// Global initialization (called once, for non-class resources)`
			`static inline void lazy_init_global(void) {`
			`if (__builtin_expect(g_tiny_global_initialized, 1)) {`
			`return;`
			`}`

			`pthread_mutex_lock(&g_lazy_init_lock);`

			`if (g_tiny_global_initialized) {`
			`pthread_mutex_unlock(&g_lazy_init_lock);`
			`return;`
			`}`

			`// Initialize SuperSlab subsystem (only once)`
			`extern int g_use_superslab;`
			`if (g_use_superslab) {`
			`extern void hak_super_registry_init(void);`
			`extern void hak_ss_lru_init(void);`
			`extern void hak_ss_prewarm_init(void);`

			`hak_super_registry_init();`
			`hak_ss_lru_init();`
			`hak_ss_prewarm_init();`
			`}`

			`// Mark global resources as initialized`
			`g_tiny_global_initialized = 1;`

			`pthread_mutex_unlock(&g_lazy_init_lock);`

			`#if !HAKMEM_BUILD_RELEASE`
			`fprintf(stderr, "[LAZY_INIT] Global resources initialized\n");`
			`#endif`
			`}`

			`#endif // HAKMEM_TINY_LAZY_INIT_INC_H`