hakmem/core/hakmem_tiny_magazine.c

#include "hakmem_tiny_magazine.h"
#include "hakmem_tiny_config.h"    // Centralized configuration
#include "hakmem_tiny.h" // For TINY_NUM_CLASSES
#include "hakmem_tiny_superslab.h"
#include "hakmem_super_registry.h"  // Phase 1: For hak_super_lookup()
#include "tiny_remote.h"
#include "hakmem_prof.h"
#include "hakmem_internal.h"
#include <pthread.h>

static inline uint32_t tiny_self_u32_guard(void) {
    return (uint32_t)(uintptr_t)pthread_self();
}

static inline void superslab_dec_active_safe(SuperSlab* ss) {
    if (!ss) return;
    uint32_t old = atomic_load_explicit(&ss->total_active_blocks, memory_order_relaxed);
    while (old != 0u) {
        if (atomic_compare_exchange_weak_explicit(&ss->total_active_blocks,
                                                  &old,
                                                  old - 1u,
                                                  memory_order_relaxed,
                                                  memory_order_relaxed)) {
            break;
        }
    }
}

__thread TinyTLSMag g_tls_mags[TINY_NUM_CLASSES];

// Global cap limiter (can be reduced via env HAKMEM_TINY_MAG_CAP)
int g_mag_cap_limit = TINY_TLS_MAG_CAP;

// Normal-path per-class overrides (env tunables)
int g_mag_cap_override[TINY_NUM_CLASSES] = {0};     // HAKMEM_TINY_MAG_CAP_C{0..7}

__thread int g_tls_small_mags_inited = 0;

// tiny_default_cap() and tiny_cap_max_for_class() now defined as inline functions
// in hakmem_tiny_config.h for centralized configuration

int tiny_effective_cap(int class_idx) {
    // Env override takes precedence per class
    int ov = g_mag_cap_override[class_idx];
    if (ov > 0) return ov;
    return tiny_default_cap(class_idx);  // Use centralized config function
}

void tiny_small_mags_init_once(void) {
    if (__builtin_expect(g_tls_small_mags_inited, 1)) return;
    for (int k = 0; k <= 3; k++) {
        TinyTLSMag* m = &g_tls_mags[k];
        if (m->cap == 0) {
            int base = tiny_effective_cap(k);
            int cap = (base < TINY_TLS_MAG_CAP) ? base : TINY_TLS_MAG_CAP;
            if (g_mag_cap_limit < cap) cap = g_mag_cap_limit;
            m->cap = cap;
            m->top = 0;
        }
    }
    g_tls_small_mags_inited = 1;
}

void tiny_mag_init_if_needed(int class_idx) {
    TinyTLSMag* mag = &g_tls_mags[class_idx];
    if (mag->cap == 0) {
        int base = tiny_effective_cap(class_idx);
        int cap = (base < TINY_TLS_MAG_CAP) ? base : TINY_TLS_MAG_CAP;
        if (g_mag_cap_limit < cap) cap = g_mag_cap_limit;
        mag->cap = cap;
        mag->top = 0;
    }
}

// ============================================================================
// ACE Learning Layer: Runtime TLS Capacity Adjustment
// ============================================================================

void hkm_ace_set_tls_capacity(int class_idx, uint32_t capacity) {
    // Validate inputs
    if (class_idx < 0 || class_idx >= TINY_NUM_CLASSES) {
        return;
    }
    if (capacity < 16 || capacity > (uint32_t)tiny_cap_max_for_class(class_idx)) {
        return;
    }

    // Set override (will be used by new thread-local magazines on next init)
    // Note: Lazy sync implementation is in hakmem_tiny_magazine.h (inlined)
    g_mag_cap_override[class_idx] = (int)capacity;
}

// ============================================================================
// Phase 7.7: Magazine Flush API
// ============================================================================

// Flush Magazine cache for a specific size class
// Forces all cached blocks to be returned to freelists, enabling empty
// SuperSlab detection and deallocation
void hak_tiny_magazine_flush(int class_idx) {
    if (class_idx < 0 || class_idx >= TINY_NUM_CLASSES) return;

    // Initialize if needed
    tiny_mag_init_if_needed(class_idx);

    TinyTLSMag* mag = &g_tls_mags[class_idx];
    if (mag->top == 0) return;  // Nothing to flush

    // Lock and flush entire Magazine to freelist
    pthread_mutex_t* lock = &g_tiny_class_locks[class_idx].m;
    struct timespec tss; int ss_time = hkm_prof_begin(&tss);
    pthread_mutex_lock(lock);

    // Flush ALL blocks (not just half like normal spill)
    int flush_count = mag->top;
    uint32_t self_tid = tiny_self_u32_guard();
    for (int i = 0; i < flush_count; i++) {
        TinyMagItem it = mag->items[--mag->top];

        // Return to SuperSlab freelist
        SuperSlab* owner_ss = hak_super_lookup(it.ptr);
        if (owner_ss && owner_ss->magic == SUPERSLAB_MAGIC) {
            int slab_idx = slab_index_for(owner_ss, it.ptr);
            TinySlabMeta* meta = &owner_ss->slabs[slab_idx];
            if (!tiny_remote_guard_allow_local_push(owner_ss, slab_idx, meta, it.ptr, "mag_flush", self_tid)) {
                (void)ss_remote_push(owner_ss, slab_idx, it.ptr);
                if (meta->used > 0) meta->used--;
                continue;
            }
            *(void**)it.ptr = meta->freelist;
            meta->freelist = it.ptr;
            meta->used--;
            // Active was decremented at free time

            // 空検出・解放はフラッシュ系APIへ委譲（ホットパス除外）
        }
    }

    pthread_mutex_unlock(lock);
    hkm_prof_end(ss_time, HKP_TINY_SPILL, &tss);
}

// Flush all Magazine caches
// Call this when memory needs to be released (e.g., before measuring RSS)
void hak_tiny_magazine_flush_all(void) {
    for (int i = 0; i < TINY_NUM_CLASSES; i++) {
        hak_tiny_magazine_flush(i);
    }
    hak_tiny_trim();
}