hakmem/core/box/ss_cache_box.c

// ss_cache_box.c - SuperSlab Cache Management Box Implementation
#include "ss_cache_box.h"
#include "ss_os_acquire_box.h"
#include "ss_stats_box.h"
#include <pthread.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>

// ============================================================================
// Cache Entry Type (internal)
// ============================================================================

typedef struct SuperslabCacheEntry {
    struct SuperslabCacheEntry* next;
} SuperslabCacheEntry;

// ============================================================================
// Cache State (per-class)
// ============================================================================

static SuperslabCacheEntry* g_ss_cache_head[8] = {0};
static size_t g_ss_cache_count[8] = {0};
size_t g_ss_cache_cap[8] = {0};  // Exported for ss_allocation_box.c
size_t g_ss_precharge_target[8] = {0};  // Exported for ss_allocation_box.c
static _Atomic int g_ss_precharge_done[8] = {0};
static int g_ss_cache_enabled = 0;

static pthread_once_t g_ss_cache_once = PTHREAD_ONCE_INIT;
static pthread_mutex_t g_ss_cache_lock[8];

// ============================================================================
// Cache Statistics
// ============================================================================

uint64_t g_ss_cache_hits[8] = {0};
uint64_t g_ss_cache_misses[8] = {0};
uint64_t g_ss_cache_puts[8] = {0};
uint64_t g_ss_cache_drops[8] = {0};
uint64_t g_ss_cache_precharged[8] = {0};

// ============================================================================
// Cache Initialization
// ============================================================================

static void ss_cache_global_init(void) {
    for (int i = 0; i < 8; i++) {
        pthread_mutex_init(&g_ss_cache_lock[i], NULL);
    }
}

void ss_cache_ensure_init(void) {
    pthread_once(&g_ss_cache_once, ss_cache_global_init);
}

// ============================================================================
// Cache Operations
// ============================================================================

void* ss_cache_pop(uint8_t size_class) {
    if (!g_ss_cache_enabled) return NULL;
    if (size_class >= 8) return NULL;

    ss_cache_ensure_init();

    pthread_mutex_lock(&g_ss_cache_lock[size_class]);
    SuperslabCacheEntry* entry = g_ss_cache_head[size_class];
    if (entry) {
        g_ss_cache_head[size_class] = entry->next;
        if (g_ss_cache_count[size_class] > 0) {
            g_ss_cache_count[size_class]--;
        }
        entry->next = NULL;
        g_ss_cache_hits[size_class]++;
    } else {
        g_ss_cache_misses[size_class]++;
    }
    pthread_mutex_unlock(&g_ss_cache_lock[size_class]);
    return (void*)entry;
}

int ss_cache_push(uint8_t size_class, SuperSlab* ss) {
    if (!g_ss_cache_enabled) return 0;
    if (size_class >= 8) return 0;

    ss_cache_ensure_init();
    pthread_mutex_lock(&g_ss_cache_lock[size_class]);
    size_t cap = g_ss_cache_cap[size_class];
    if (cap != 0 && g_ss_cache_count[size_class] >= cap) {
        g_ss_cache_drops[size_class]++;
        pthread_mutex_unlock(&g_ss_cache_lock[size_class]);
        return 0;
    }
    SuperslabCacheEntry* entry = (SuperslabCacheEntry*)ss;
    entry->next = g_ss_cache_head[size_class];
    g_ss_cache_head[size_class] = entry;
    g_ss_cache_count[size_class]++;
    g_ss_cache_puts[size_class]++;
    pthread_mutex_unlock(&g_ss_cache_lock[size_class]);
    return 1;
}

void ss_cache_precharge(uint8_t size_class, size_t ss_size, uintptr_t ss_mask) {
    if (!g_ss_cache_enabled) return;
    if (size_class >= 8) return;
    if (g_ss_precharge_target[size_class] == 0) return;
    if (atomic_load_explicit(&g_ss_precharge_done[size_class], memory_order_acquire)) return;

    ss_cache_ensure_init();
    pthread_mutex_lock(&g_ss_cache_lock[size_class]);
    size_t target = g_ss_precharge_target[size_class];
    size_t cap = g_ss_cache_cap[size_class];
    size_t desired = target;
    if (cap != 0 && desired > cap) {
        desired = cap;
    }
    while (g_ss_cache_count[size_class] < desired) {
        void* raw = ss_os_acquire(size_class, ss_size, ss_mask, 1);
        if (!raw) {
            break;
        }
        SuperslabCacheEntry* entry = (SuperslabCacheEntry*)raw;
        entry->next = g_ss_cache_head[size_class];
        g_ss_cache_head[size_class] = entry;
        g_ss_cache_count[size_class]++;
        g_ss_cache_precharged[size_class]++;
    }
    atomic_store_explicit(&g_ss_precharge_done[size_class], 1, memory_order_release);
    pthread_mutex_unlock(&g_ss_cache_lock[size_class]);
}

// ============================================================================
// Runtime Tuning API
// ============================================================================

void tiny_ss_cache_set_class_cap(int class_idx, size_t new_cap) {
    if (class_idx < 0 || class_idx >= 8) {
        return;
    }

    ss_cache_ensure_init();
    pthread_mutex_lock(&g_ss_cache_lock[class_idx]);

    size_t old_cap = g_ss_cache_cap[class_idx];
    g_ss_cache_cap[class_idx] = new_cap;

    // If shrinking cap, drop extra cached superslabs (oldest from head) and munmap them.
    if (new_cap == 0 || new_cap < old_cap) {
        while (g_ss_cache_count[class_idx] > new_cap) {
            SuperslabCacheEntry* entry = g_ss_cache_head[class_idx];
            if (!entry) {
                g_ss_cache_count[class_idx] = 0;
                break;
            }
            g_ss_cache_head[class_idx] = entry->next;
            g_ss_cache_count[class_idx]--;
            g_ss_cache_drops[class_idx]++;

            // Convert cache entry back to SuperSlab* and release it to OS.
            SuperSlab* ss = (SuperSlab*)entry;
            size_t ss_size = (size_t)1 << ss->lg_size;
            munmap((void*)ss, ss_size);

            // Update global stats to keep accounting consistent.
            extern pthread_mutex_t g_superslab_lock;  // From ss_stats_box.c
            pthread_mutex_lock(&g_superslab_lock);
            g_superslabs_freed++;
            if (g_bytes_allocated >= ss_size) {
                g_bytes_allocated -= ss_size;
            } else {
                g_bytes_allocated = 0;
            }
            pthread_mutex_unlock(&g_superslab_lock);
        }
    }

    pthread_mutex_unlock(&g_ss_cache_lock[class_idx]);

    // Recompute cache enabled flag (8 classes, so O(8) is cheap)
    int enabled = 0;
    for (int i = 0; i < 8; i++) {
        if (g_ss_cache_cap[i] > 0 || g_ss_precharge_target[i] > 0) {
            enabled = 1;
            break;
        }
    }
    g_ss_cache_enabled = enabled;
}

void tiny_ss_precharge_set_class_target(int class_idx, size_t target) {
    if (class_idx < 0 || class_idx >= 8) {
        return;
    }

    ss_cache_ensure_init();
    pthread_mutex_lock(&g_ss_cache_lock[class_idx]);

    g_ss_precharge_target[class_idx] = target;
    if (target > 0) {
        g_ss_cache_enabled = 1;
        atomic_store_explicit(&g_ss_precharge_done[class_idx], 0, memory_order_relaxed);
    }

    pthread_mutex_unlock(&g_ss_cache_lock[class_idx]);
}
Phase 3d-B: TLS Cache Merge - Unified g_tls_sll[] structure (+12-18% expected) Merge separate g_tls_sll_head[] and g_tls_sll_count[] arrays into unified TinyTLSSLL struct to improve L1D cache locality. Expected performance gain: +12-18% from reducing cache line splits (2 loads → 1 load per operation). Changes: - core/hakmem_tiny.h: Add TinyTLSSLL type (16B aligned, head+count+pad) - core/hakmem_tiny.c: Replace separate arrays with g_tls_sll[8] - core/box/tls_sll_box.h: Update Box API (13 sites) for unified access - Updated 32+ files: All g_tls_sll_head[i] → g_tls_sll[i].head - Updated 32+ files: All g_tls_sll_count[i] → g_tls_sll[i].count - core/hakmem_tiny_integrity.h: Unified canary guards - core/box/integrity_box.c: Simplified canary validation - Makefile: Added core/box/tiny_sizeclass_hist_box.o to link Build: ✅ PASS (10K ops sanity test) Warnings: Only pre-existing LTO type mismatches (unrelated) 🤖 Generated with [Claude Code](https://claude.com/claude-code) Co-Authored-By: Claude <noreply@anthropic.com> 2025-11-20 07:32:30 +09:00			`// ss_cache_box.c - SuperSlab Cache Management Box Implementation`
			`#include "ss_cache_box.h"`
			`#include "ss_os_acquire_box.h"`
			`#include "ss_stats_box.h"`
			`#include <pthread.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <sys/mman.h>`

			`// ============================================================================`
			`// Cache Entry Type (internal)`
			`// ============================================================================`

			`typedef struct SuperslabCacheEntry {`
			`struct SuperslabCacheEntry* next;`
			`} SuperslabCacheEntry;`

			`// ============================================================================`
			`// Cache State (per-class)`
			`// ============================================================================`

			`static SuperslabCacheEntry* g_ss_cache_head[8] = {0};`
			`static size_t g_ss_cache_count[8] = {0};`
			`size_t g_ss_cache_cap[8] = {0}; // Exported for ss_allocation_box.c`
			`size_t g_ss_precharge_target[8] = {0}; // Exported for ss_allocation_box.c`
			`static _Atomic int g_ss_precharge_done[8] = {0};`
			`static int g_ss_cache_enabled = 0;`

			`static pthread_once_t g_ss_cache_once = PTHREAD_ONCE_INIT;`
			`static pthread_mutex_t g_ss_cache_lock[8];`

			`// ============================================================================`
			`// Cache Statistics`
			`// ============================================================================`

			`uint64_t g_ss_cache_hits[8] = {0};`
			`uint64_t g_ss_cache_misses[8] = {0};`
			`uint64_t g_ss_cache_puts[8] = {0};`
			`uint64_t g_ss_cache_drops[8] = {0};`
			`uint64_t g_ss_cache_precharged[8] = {0};`

			`// ============================================================================`
			`// Cache Initialization`
			`// ============================================================================`

			`static void ss_cache_global_init(void) {`
			`for (int i = 0; i < 8; i++) {`
			`pthread_mutex_init(&g_ss_cache_lock[i], NULL);`
			`}`
			`}`

			`void ss_cache_ensure_init(void) {`
			`pthread_once(&g_ss_cache_once, ss_cache_global_init);`
			`}`

			`// ============================================================================`
			`// Cache Operations`
			`// ============================================================================`

			`void* ss_cache_pop(uint8_t size_class) {`
			`if (!g_ss_cache_enabled) return NULL;`
			`if (size_class >= 8) return NULL;`

			`ss_cache_ensure_init();`

			`pthread_mutex_lock(&g_ss_cache_lock[size_class]);`
			`SuperslabCacheEntry* entry = g_ss_cache_head[size_class];`
			`if (entry) {`
			`g_ss_cache_head[size_class] = entry->next;`
			`if (g_ss_cache_count[size_class] > 0) {`
			`g_ss_cache_count[size_class]--;`
			`}`
			`entry->next = NULL;`
			`g_ss_cache_hits[size_class]++;`
			`} else {`
			`g_ss_cache_misses[size_class]++;`
			`}`
			`pthread_mutex_unlock(&g_ss_cache_lock[size_class]);`
			`return (void*)entry;`
			`}`

			`int ss_cache_push(uint8_t size_class, SuperSlab* ss) {`
			`if (!g_ss_cache_enabled) return 0;`
			`if (size_class >= 8) return 0;`

			`ss_cache_ensure_init();`
			`pthread_mutex_lock(&g_ss_cache_lock[size_class]);`
			`size_t cap = g_ss_cache_cap[size_class];`
			`if (cap != 0 && g_ss_cache_count[size_class] >= cap) {`
			`g_ss_cache_drops[size_class]++;`
			`pthread_mutex_unlock(&g_ss_cache_lock[size_class]);`
			`return 0;`
			`}`
			`SuperslabCacheEntry* entry = (SuperslabCacheEntry*)ss;`
			`entry->next = g_ss_cache_head[size_class];`
			`g_ss_cache_head[size_class] = entry;`
			`g_ss_cache_count[size_class]++;`
			`g_ss_cache_puts[size_class]++;`
			`pthread_mutex_unlock(&g_ss_cache_lock[size_class]);`
			`return 1;`
			`}`

			`void ss_cache_precharge(uint8_t size_class, size_t ss_size, uintptr_t ss_mask) {`
			`if (!g_ss_cache_enabled) return;`
			`if (size_class >= 8) return;`
			`if (g_ss_precharge_target[size_class] == 0) return;`
			`if (atomic_load_explicit(&g_ss_precharge_done[size_class], memory_order_acquire)) return;`

			`ss_cache_ensure_init();`
			`pthread_mutex_lock(&g_ss_cache_lock[size_class]);`
			`size_t target = g_ss_precharge_target[size_class];`
			`size_t cap = g_ss_cache_cap[size_class];`
			`size_t desired = target;`
			`if (cap != 0 && desired > cap) {`
			`desired = cap;`
			`}`
			`while (g_ss_cache_count[size_class] < desired) {`
			`void* raw = ss_os_acquire(size_class, ss_size, ss_mask, 1);`
			`if (!raw) {`
			`break;`
			`}`
			`SuperslabCacheEntry* entry = (SuperslabCacheEntry*)raw;`
			`entry->next = g_ss_cache_head[size_class];`
			`g_ss_cache_head[size_class] = entry;`
			`g_ss_cache_count[size_class]++;`
			`g_ss_cache_precharged[size_class]++;`
			`}`
			`atomic_store_explicit(&g_ss_precharge_done[size_class], 1, memory_order_release);`
			`pthread_mutex_unlock(&g_ss_cache_lock[size_class]);`
			`}`

			`// ============================================================================`
			`// Runtime Tuning API`
			`// ============================================================================`

			`void tiny_ss_cache_set_class_cap(int class_idx, size_t new_cap) {`
			`if (class_idx < 0 \|\| class_idx >= 8) {`
			`return;`
			`}`

			`ss_cache_ensure_init();`
			`pthread_mutex_lock(&g_ss_cache_lock[class_idx]);`

			`size_t old_cap = g_ss_cache_cap[class_idx];`
			`g_ss_cache_cap[class_idx] = new_cap;`

			`// If shrinking cap, drop extra cached superslabs (oldest from head) and munmap them.`
			`if (new_cap == 0 \|\| new_cap < old_cap) {`
			`while (g_ss_cache_count[class_idx] > new_cap) {`
			`SuperslabCacheEntry* entry = g_ss_cache_head[class_idx];`
			`if (!entry) {`
			`g_ss_cache_count[class_idx] = 0;`
			`break;`
			`}`
			`g_ss_cache_head[class_idx] = entry->next;`
			`g_ss_cache_count[class_idx]--;`
			`g_ss_cache_drops[class_idx]++;`

			`// Convert cache entry back to SuperSlab* and release it to OS.`
			`SuperSlab* ss = (SuperSlab*)entry;`
			`size_t ss_size = (size_t)1 << ss->lg_size;`
			`munmap((void*)ss, ss_size);`

			`// Update global stats to keep accounting consistent.`
			`extern pthread_mutex_t g_superslab_lock; // From ss_stats_box.c`
			`pthread_mutex_lock(&g_superslab_lock);`
			`g_superslabs_freed++;`
			`if (g_bytes_allocated >= ss_size) {`
			`g_bytes_allocated -= ss_size;`
			`} else {`
			`g_bytes_allocated = 0;`
			`}`
			`pthread_mutex_unlock(&g_superslab_lock);`
			`}`
			`}`

			`pthread_mutex_unlock(&g_ss_cache_lock[class_idx]);`

			`// Recompute cache enabled flag (8 classes, so O(8) is cheap)`
			`int enabled = 0;`
			`for (int i = 0; i < 8; i++) {`
			`if (g_ss_cache_cap[i] > 0 \|\| g_ss_precharge_target[i] > 0) {`
			`enabled = 1;`
			`break;`
			`}`
			`}`
			`g_ss_cache_enabled = enabled;`
			`}`

			`void tiny_ss_precharge_set_class_target(int class_idx, size_t target) {`
			`if (class_idx < 0 \|\| class_idx >= 8) {`
			`return;`
			`}`

			`ss_cache_ensure_init();`
			`pthread_mutex_lock(&g_ss_cache_lock[class_idx]);`

			`g_ss_precharge_target[class_idx] = target;`
			`if (target > 0) {`
			`g_ss_cache_enabled = 1;`
			`atomic_store_explicit(&g_ss_precharge_done[class_idx], 0, memory_order_relaxed);`
			`}`

			`pthread_mutex_unlock(&g_ss_cache_lock[class_idx]);`
			`}`