hakmem/core/superslab_stats.c

// superslab_stats.c - Statistics and debugging for SuperSlab allocator
// Purpose: Tracking and reporting allocation statistics
// License: MIT
// Date: 2025-11-28

#include "hakmem_tiny_superslab_internal.h"

// ============================================================================
// Global Statistics
// ============================================================================

pthread_mutex_t g_superslab_lock = PTHREAD_MUTEX_INITIALIZER;
uint64_t g_superslabs_allocated = 0;  // Non-static for debugging
uint64_t g_superslabs_freed = 0;      // Phase 7.6: Non-static for test access
uint64_t g_bytes_allocated = 0;  // Non-static for debugging

// Debug counters
_Atomic uint64_t g_ss_active_dec_calls = 0;
_Atomic uint64_t g_hak_tiny_free_calls = 0;
_Atomic uint64_t g_ss_remote_push_calls = 0;
// Free path instrumentation (lightweight, for OOM/route diagnosis)
_Atomic uint64_t g_free_ss_enter = 0;          // hak_tiny_free_superslab() entries
_Atomic uint64_t g_free_local_box_calls = 0;   // same-thread freelist pushes
_Atomic uint64_t g_free_remote_box_calls = 0;  // cross-thread remote pushes
// Per-class counters for gating/metrics (Tiny classes = 8)
uint64_t g_ss_alloc_by_class[8] = {0};
uint64_t g_ss_freed_by_class[8] = {0};

// Global counters for debugging (non-static for external access)
_Atomic uint64_t g_ss_mmap_count = 0;
_Atomic uint64_t g_final_fallback_mmap_count = 0;

// ============================================================================
// Statistics Functions
// ============================================================================

void ss_stats_os_alloc(uint8_t size_class, size_t ss_size) {
    pthread_mutex_lock(&g_superslab_lock);
    g_superslabs_allocated++;
    if (size_class < 8) {
        g_ss_alloc_by_class[size_class]++;
    }
    g_bytes_allocated += ss_size;
    pthread_mutex_unlock(&g_superslab_lock);
}

void ss_stats_cache_reuse(void) {
    pthread_mutex_lock(&g_superslab_lock);
    g_superslabs_reused++;
    pthread_mutex_unlock(&g_superslab_lock);
}

void ss_stats_cache_store(void) {
    pthread_mutex_lock(&g_superslab_lock);
    g_superslabs_cached++;
    pthread_mutex_unlock(&g_superslab_lock);
}

// ============================================================================
// Diagnostics
// ============================================================================

void log_superslab_oom_once(size_t ss_size, size_t alloc_size, int err) {
    static int logged = 0;
    if (logged) return;
    logged = 1;

    // CRITICAL FIX: Increment lock depth FIRST before any LIBC calls
    // fopen/fclose/getrlimit/fprintf all may call malloc internally
    // Must bypass HAKMEM wrapper to avoid header mismatch crash
    extern __thread int g_hakmem_lock_depth;
    g_hakmem_lock_depth++;  // Force wrapper to use __libc_malloc

    struct rlimit rl = {0};
    if (getrlimit(RLIMIT_AS, &rl) != 0) {
        rl.rlim_cur = RLIM_INFINITY;
        rl.rlim_max = RLIM_INFINITY;
    }

    unsigned long vm_size_kb = 0;
    unsigned long vm_rss_kb = 0;
    FILE* status = fopen("/proc/self/status", "r");
    if (status) {
        char line[256];
        while (fgets(line, sizeof(line), status)) {
            if (strncmp(line, "VmSize:", 7) == 0) {
                (void)sscanf(line + 7, "%lu", &vm_size_kb);
            } else if (strncmp(line, "VmRSS:", 6) == 0) {
                (void)sscanf(line + 6, "%lu", &vm_rss_kb);
            }
        }
        fclose(status);
    }
    // CRITICAL FIX: Do NOT decrement lock_depth yet!
    // fprintf() below may call malloc for buffering

    char rl_cur_buf[32];
    char rl_max_buf[32];
    if (rl.rlim_cur == RLIM_INFINITY) {
        strcpy(rl_cur_buf, "inf");
    } else {
        snprintf(rl_cur_buf, sizeof(rl_cur_buf), "%llu", (unsigned long long)rl.rlim_cur);
    }
    if (rl.rlim_max == RLIM_INFINITY) {
        strcpy(rl_max_buf, "inf");
    } else {
        snprintf(rl_max_buf, sizeof(rl_max_buf), "%llu", (unsigned long long)rl.rlim_max);
    }

#if !HAKMEM_BUILD_RELEASE
    fprintf(stderr,
            "[SS OOM] mmap failed: err=%d ss_size=%zu alloc_size=%zu "
            "alloc=%llu freed=%llu bytes=%llu "
            "RLIMIT_AS(cur=%s max=%s) VmSize=%lu kB VmRSS=%lu kB\n",
            err,
            ss_size,
            alloc_size,
            (unsigned long long)g_superslabs_allocated,
            (unsigned long long)g_superslabs_freed,
            (unsigned long long)g_bytes_allocated,
            rl_cur_buf,
            rl_max_buf,
            vm_size_kb,
            vm_rss_kb);
#endif

    g_hakmem_lock_depth--;  // Now safe to restore (all libc calls complete)
}

// ============================================================================
// Statistics / Debugging
// ============================================================================

void superslab_print_stats(SuperSlab* ss) {
    if (!ss || ss->magic != SUPERSLAB_MAGIC) {
        printf("Invalid SuperSlab\n");
        return;
    }

    printf("=== SuperSlab Stats ===\n");
    printf("Address: %p\n", (void*)ss);
    // Phase 12: per-SS size_class removed; classes are per-slab via meta->class_idx.
    printf("Active slabs: %u / %d\n", ss->active_slabs, ss_slabs_capacity(ss));
    printf("Bitmap: 0x%08X\n", ss->slab_bitmap);
    printf("\nPer-slab details:\n");
    for (int i = 0; i < ss_slabs_capacity(ss); i++) {
        if (ss->slab_bitmap & (1u << i)) {
            TinySlabMeta* meta = &ss->slabs[i];
            printf("  Slab %2d: used=%u/%u freelist=%p class=%u owner_tid_low=%u\n",
                   i, meta->used, meta->capacity, meta->freelist,
                   (unsigned)meta->class_idx, (unsigned)meta->owner_tid_low);
        }
    }
    printf("\n");
}

// Global statistics
void superslab_print_global_stats(void) {
    pthread_mutex_lock(&g_superslab_lock);
    printf("=== Global SuperSlab Stats ===\n");
    printf("SuperSlabs allocated: %lu\n", g_superslabs_allocated);
    printf("SuperSlabs freed: %lu\n", g_superslabs_freed);
    printf("SuperSlabs active: %lu\n", g_superslabs_allocated - g_superslabs_freed);
    printf("Total bytes allocated: %lu MB\n", g_bytes_allocated / (1024 * 1024));
    pthread_mutex_unlock(&g_superslab_lock);
}
Refactor: Split hakmem_tiny_superslab.c + unified backend exit point Major refactoring to improve maintainability and debugging: 1. Split hakmem_tiny_superslab.c (1521 lines) into 7 focused files: - superslab_allocate.c: SuperSlab allocation/deallocation - superslab_backend.c: Backend allocation paths (legacy, shared) - superslab_ace.c: ACE (Adaptive Cache Engine) logic - superslab_slab.c: Slab initialization and bitmap management - superslab_cache.c: LRU cache and prewarm cache management - superslab_head.c: SuperSlabHead management and expansion - superslab_stats.c: Statistics tracking and debugging 2. Created hakmem_tiny_superslab_internal.h for shared declarations 3. Added superslab_return_block() as single exit point for header writing: - All backend allocations now go through this helper - Prevents bugs where headers are forgotten in some paths - Makes future debugging easier 4. Updated Makefile for new file structure 5. Added header writing to ss_legacy_backend_box.c and ss_unified_backend_box.c (though not currently linked) Note: Header corruption bug in Larson benchmark still exists. Class 1-6 allocations go through TLS refill/carve paths, not backend. Further investigation needed. 🤖 Generated with [Claude Code](https://claude.com/claude-code) Co-Authored-By: Claude <noreply@anthropic.com> 2025-11-29 05:13:04 +09:00			`// superslab_stats.c - Statistics and debugging for SuperSlab allocator`
			`// Purpose: Tracking and reporting allocation statistics`
			`// License: MIT`
			`// Date: 2025-11-28`

			`#include "hakmem_tiny_superslab_internal.h"`

			`// ============================================================================`
			`// Global Statistics`
			`// ============================================================================`

			`pthread_mutex_t g_superslab_lock = PTHREAD_MUTEX_INITIALIZER;`
			`uint64_t g_superslabs_allocated = 0; // Non-static for debugging`
			`uint64_t g_superslabs_freed = 0; // Phase 7.6: Non-static for test access`
			`uint64_t g_bytes_allocated = 0; // Non-static for debugging`

			`// Debug counters`
			`_Atomic uint64_t g_ss_active_dec_calls = 0;`
			`_Atomic uint64_t g_hak_tiny_free_calls = 0;`
			`_Atomic uint64_t g_ss_remote_push_calls = 0;`
			`// Free path instrumentation (lightweight, for OOM/route diagnosis)`
			`_Atomic uint64_t g_free_ss_enter = 0; // hak_tiny_free_superslab() entries`
			`_Atomic uint64_t g_free_local_box_calls = 0; // same-thread freelist pushes`
			`_Atomic uint64_t g_free_remote_box_calls = 0; // cross-thread remote pushes`
			`// Per-class counters for gating/metrics (Tiny classes = 8)`
			`uint64_t g_ss_alloc_by_class[8] = {0};`
			`uint64_t g_ss_freed_by_class[8] = {0};`

			`// Global counters for debugging (non-static for external access)`
			`_Atomic uint64_t g_ss_mmap_count = 0;`
			`_Atomic uint64_t g_final_fallback_mmap_count = 0;`

			`// ============================================================================`
			`// Statistics Functions`
			`// ============================================================================`

			`void ss_stats_os_alloc(uint8_t size_class, size_t ss_size) {`
			`pthread_mutex_lock(&g_superslab_lock);`
			`g_superslabs_allocated++;`
			`if (size_class < 8) {`
			`g_ss_alloc_by_class[size_class]++;`
			`}`
			`g_bytes_allocated += ss_size;`
			`pthread_mutex_unlock(&g_superslab_lock);`
			`}`

			`void ss_stats_cache_reuse(void) {`
			`pthread_mutex_lock(&g_superslab_lock);`
			`g_superslabs_reused++;`
			`pthread_mutex_unlock(&g_superslab_lock);`
			`}`

			`void ss_stats_cache_store(void) {`
			`pthread_mutex_lock(&g_superslab_lock);`
			`g_superslabs_cached++;`
			`pthread_mutex_unlock(&g_superslab_lock);`
			`}`

			`// ============================================================================`
			`// Diagnostics`
			`// ============================================================================`

			`void log_superslab_oom_once(size_t ss_size, size_t alloc_size, int err) {`
			`static int logged = 0;`
			`if (logged) return;`
			`logged = 1;`

			`// CRITICAL FIX: Increment lock depth FIRST before any LIBC calls`
			`// fopen/fclose/getrlimit/fprintf all may call malloc internally`
			`// Must bypass HAKMEM wrapper to avoid header mismatch crash`
			`extern __thread int g_hakmem_lock_depth;`
			`g_hakmem_lock_depth++; // Force wrapper to use __libc_malloc`

			`struct rlimit rl = {0};`
			`if (getrlimit(RLIMIT_AS, &rl) != 0) {`
			`rl.rlim_cur = RLIM_INFINITY;`
			`rl.rlim_max = RLIM_INFINITY;`
			`}`

			`unsigned long vm_size_kb = 0;`
			`unsigned long vm_rss_kb = 0;`
			`FILE* status = fopen("/proc/self/status", "r");`
			`if (status) {`
			`char line[256];`
			`while (fgets(line, sizeof(line), status)) {`
			`if (strncmp(line, "VmSize:", 7) == 0) {`
			`(void)sscanf(line + 7, "%lu", &vm_size_kb);`
			`} else if (strncmp(line, "VmRSS:", 6) == 0) {`
			`(void)sscanf(line + 6, "%lu", &vm_rss_kb);`
			`}`
			`}`
			`fclose(status);`
			`}`
			`// CRITICAL FIX: Do NOT decrement lock_depth yet!`
			`// fprintf() below may call malloc for buffering`

			`char rl_cur_buf[32];`
			`char rl_max_buf[32];`
			`if (rl.rlim_cur == RLIM_INFINITY) {`
			`strcpy(rl_cur_buf, "inf");`
			`} else {`
			`snprintf(rl_cur_buf, sizeof(rl_cur_buf), "%llu", (unsigned long long)rl.rlim_cur);`
			`}`
			`if (rl.rlim_max == RLIM_INFINITY) {`
			`strcpy(rl_max_buf, "inf");`
			`} else {`
			`snprintf(rl_max_buf, sizeof(rl_max_buf), "%llu", (unsigned long long)rl.rlim_max);`
			`}`

			`#if !HAKMEM_BUILD_RELEASE`
			`fprintf(stderr,`
			`"[SS OOM] mmap failed: err=%d ss_size=%zu alloc_size=%zu "`
			`"alloc=%llu freed=%llu bytes=%llu "`
			`"RLIMIT_AS(cur=%s max=%s) VmSize=%lu kB VmRSS=%lu kB\n",`
			`err,`
			`ss_size,`
			`alloc_size,`
			`(unsigned long long)g_superslabs_allocated,`
			`(unsigned long long)g_superslabs_freed,`
			`(unsigned long long)g_bytes_allocated,`
			`rl_cur_buf,`
			`rl_max_buf,`
			`vm_size_kb,`
			`vm_rss_kb);`
			`#endif`

			`g_hakmem_lock_depth--; // Now safe to restore (all libc calls complete)`
			`}`

			`// ============================================================================`
			`// Statistics / Debugging`
			`// ============================================================================`

			`void superslab_print_stats(SuperSlab* ss) {`
			`if (!ss \|\| ss->magic != SUPERSLAB_MAGIC) {`
			`printf("Invalid SuperSlab\n");`
			`return;`
			`}`

			`printf("=== SuperSlab Stats ===\n");`
			`printf("Address: %p\n", (void*)ss);`
			`// Phase 12: per-SS size_class removed; classes are per-slab via meta->class_idx.`
			`printf("Active slabs: %u / %d\n", ss->active_slabs, ss_slabs_capacity(ss));`
			`printf("Bitmap: 0x%08X\n", ss->slab_bitmap);`
			`printf("\nPer-slab details:\n");`
			`for (int i = 0; i < ss_slabs_capacity(ss); i++) {`
			`if (ss->slab_bitmap & (1u << i)) {`
			`TinySlabMeta* meta = &ss->slabs[i];`
			`printf(" Slab %2d: used=%u/%u freelist=%p class=%u owner_tid_low=%u\n",`
			`i, meta->used, meta->capacity, meta->freelist,`
			`(unsigned)meta->class_idx, (unsigned)meta->owner_tid_low);`
			`}`
			`}`
			`printf("\n");`
			`}`

			`// Global statistics`
			`void superslab_print_global_stats(void) {`
			`pthread_mutex_lock(&g_superslab_lock);`
			`printf("=== Global SuperSlab Stats ===\n");`
			`printf("SuperSlabs allocated: %lu\n", g_superslabs_allocated);`
			`printf("SuperSlabs freed: %lu\n", g_superslabs_freed);`
			`printf("SuperSlabs active: %lu\n", g_superslabs_allocated - g_superslabs_freed);`
			`printf("Total bytes allocated: %lu MB\n", g_bytes_allocated / (1024 * 1024));`
			`pthread_mutex_unlock(&g_superslab_lock);`
			`}`