hakmem/core/hakmem_tiny_bg_spill.c

#include "hakmem_tiny_bg_spill.h"
#include "hakmem_tiny_superslab.h"  // For SuperSlab, TinySlabMeta, ss_active_dec_one
#include "hakmem_super_registry.h"  // For hak_super_lookup
#include "tiny_remote.h"
#include "hakmem_tiny.h"
#include <pthread.h>

static inline uint32_t tiny_self_u32_guard(void) {
    return (uint32_t)(uintptr_t)pthread_self();
}
#include <stdlib.h>  // For getenv, atoi

// Global variables
int g_bg_spill_enable = 0;           // HAKMEM_TINY_BG_SPILL=1
int g_bg_spill_target = 128;         // HAKMEM_TINY_BG_TARGET (per class)
int g_bg_spill_max_batch = 128;      // HAKMEM_TINY_BG_MAX_BATCH
_Atomic uintptr_t g_bg_spill_head[TINY_NUM_CLASSES];
_Atomic uint32_t g_bg_spill_len[TINY_NUM_CLASSES];

void bg_spill_init(void) {
    // Parse environment variables
    char* bs = getenv("HAKMEM_TINY_BG_SPILL");
    if (bs) g_bg_spill_enable = (atoi(bs) != 0) ? 1 : 0;
    char* bt2 = getenv("HAKMEM_TINY_BG_TARGET");
    if (bt2) { int v = atoi(bt2); if (v > 0 && v <= 8192) g_bg_spill_target = v; }
    char* mb = getenv("HAKMEM_TINY_BG_MAX_BATCH");
    if (mb) { int v = atoi(mb); if (v > 0 && v <= 4096) g_bg_spill_max_batch = v; }

    // Initialize atomic queues
    for (int k = 0; k < TINY_NUM_CLASSES; k++) {
        atomic_store_explicit(&g_bg_spill_head[k], (uintptr_t)0, memory_order_relaxed);
        atomic_store_explicit(&g_bg_spill_len[k], 0u, memory_order_relaxed);
    }
}

void bg_spill_drain_class(int class_idx, pthread_mutex_t* lock) {
    uint32_t approx = atomic_load_explicit(&g_bg_spill_len[class_idx], memory_order_relaxed);
    if (approx == 0) return;

    uintptr_t chain = atomic_exchange_explicit(&g_bg_spill_head[class_idx], (uintptr_t)0, memory_order_acq_rel);
    if (chain == 0) return;

    // Split chain up to max_batch
    int processed = 0;
    void* rest = NULL;
    void* cur = (void*)chain;
    void* prev = NULL;
    while (cur && processed < g_bg_spill_max_batch) {
        prev = cur;
        cur = *(void**)cur;
        processed++;
    }
    if (cur != NULL) { rest = cur; *(void**)prev = NULL; }

    // Return processed nodes to SS freelists
    pthread_mutex_lock(lock);
    uint32_t self_tid = tiny_self_u32_guard();
    void* node = (void*)chain;
    while (node) {
        void* next = *(void**)node;
        SuperSlab* owner_ss = hak_super_lookup(node);
        if (owner_ss && owner_ss->magic == SUPERSLAB_MAGIC) {
            int slab_idx = slab_index_for(owner_ss, node);
            TinySlabMeta* meta = &owner_ss->slabs[slab_idx];
            if (!tiny_remote_guard_allow_local_push(owner_ss, slab_idx, meta, node, "bg_spill", self_tid)) {
                (void)ss_remote_push(owner_ss, slab_idx, node);
                if (meta->used > 0) meta->used--;
                node = next;
                continue;
            }
            *(void**)node = meta->freelist;
            meta->freelist = node;
            meta->used--;
            // Active was decremented at free time
        }
        node = next;
    }
    pthread_mutex_unlock(lock);

    if (processed > 0) {
        atomic_fetch_sub_explicit(&g_bg_spill_len[class_idx], (uint32_t)processed, memory_order_relaxed);
    }

    if (rest) {
        // Prepend remainder back to head
        uintptr_t old_head;
        void* tail = rest;
        while (*(void**)tail) tail = *(void**)tail;
        do {
            old_head = atomic_load_explicit(&g_bg_spill_head[class_idx], memory_order_acquire);
            *(void**)tail = (void*)old_head;
        } while (!atomic_compare_exchange_weak_explicit(&g_bg_spill_head[class_idx], &old_head,
                                                        (uintptr_t)rest,
                                                        memory_order_release, memory_order_relaxed));
    }
}
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			`#include "hakmem_tiny_bg_spill.h"`
			`#include "hakmem_tiny_superslab.h" // For SuperSlab, TinySlabMeta, ss_active_dec_one`
			`#include "hakmem_super_registry.h" // For hak_super_lookup`
			`#include "tiny_remote.h"`
			`#include "hakmem_tiny.h"`
			`#include <pthread.h>`

			`static inline uint32_t tiny_self_u32_guard(void) {`
			`return (uint32_t)(uintptr_t)pthread_self();`
			`}`
			`#include <stdlib.h> // For getenv, atoi`

			`// Global variables`
			`int g_bg_spill_enable = 0; // HAKMEM_TINY_BG_SPILL=1`
			`int g_bg_spill_target = 128; // HAKMEM_TINY_BG_TARGET (per class)`
			`int g_bg_spill_max_batch = 128; // HAKMEM_TINY_BG_MAX_BATCH`
			`_Atomic uintptr_t g_bg_spill_head[TINY_NUM_CLASSES];`
			`_Atomic uint32_t g_bg_spill_len[TINY_NUM_CLASSES];`

			`void bg_spill_init(void) {`
			`// Parse environment variables`
			`char* bs = getenv("HAKMEM_TINY_BG_SPILL");`
			`if (bs) g_bg_spill_enable = (atoi(bs) != 0) ? 1 : 0;`
			`char* bt2 = getenv("HAKMEM_TINY_BG_TARGET");`
			`if (bt2) { int v = atoi(bt2); if (v > 0 && v <= 8192) g_bg_spill_target = v; }`
			`char* mb = getenv("HAKMEM_TINY_BG_MAX_BATCH");`
			`if (mb) { int v = atoi(mb); if (v > 0 && v <= 4096) g_bg_spill_max_batch = v; }`

			`// Initialize atomic queues`
			`for (int k = 0; k < TINY_NUM_CLASSES; k++) {`
			`atomic_store_explicit(&g_bg_spill_head[k], (uintptr_t)0, memory_order_relaxed);`
			`atomic_store_explicit(&g_bg_spill_len[k], 0u, memory_order_relaxed);`
			`}`
			`}`

			`void bg_spill_drain_class(int class_idx, pthread_mutex_t* lock) {`
			`uint32_t approx = atomic_load_explicit(&g_bg_spill_len[class_idx], memory_order_relaxed);`
			`if (approx == 0) return;`

			`uintptr_t chain = atomic_exchange_explicit(&g_bg_spill_head[class_idx], (uintptr_t)0, memory_order_acq_rel);`
			`if (chain == 0) return;`

			`// Split chain up to max_batch`
			`int processed = 0;`
			`void* rest = NULL;`
			`void* cur = (void*)chain;`
			`void* prev = NULL;`
			`while (cur && processed < g_bg_spill_max_batch) {`
			`prev = cur;`
			`cur = (void*)cur;`
			`processed++;`
			`}`
			`if (cur != NULL) { rest = cur; (void*)prev = NULL; }`

			`// Return processed nodes to SS freelists`
			`pthread_mutex_lock(lock);`
			`uint32_t self_tid = tiny_self_u32_guard();`
			`void* node = (void*)chain;`
			`while (node) {`
			`void* next = (void*)node;`
			`SuperSlab* owner_ss = hak_super_lookup(node);`
			`if (owner_ss && owner_ss->magic == SUPERSLAB_MAGIC) {`
			`int slab_idx = slab_index_for(owner_ss, node);`
			`TinySlabMeta* meta = &owner_ss->slabs[slab_idx];`
			`if (!tiny_remote_guard_allow_local_push(owner_ss, slab_idx, meta, node, "bg_spill", self_tid)) {`
			`(void)ss_remote_push(owner_ss, slab_idx, node);`
			`if (meta->used > 0) meta->used--;`
			`node = next;`
			`continue;`
			`}`
			`(void*)node = meta->freelist;`
			`meta->freelist = node;`
			`meta->used--;`
			`// Active was decremented at free time`
			`}`
			`node = next;`
			`}`
			`pthread_mutex_unlock(lock);`

			`if (processed > 0) {`
			`atomic_fetch_sub_explicit(&g_bg_spill_len[class_idx], (uint32_t)processed, memory_order_relaxed);`
			`}`

			`if (rest) {`
			`// Prepend remainder back to head`
			`uintptr_t old_head;`
			`void* tail = rest;`
			`while ((void)tail) tail = (void**)tail;`
			`do {`
			`old_head = atomic_load_explicit(&g_bg_spill_head[class_idx], memory_order_acquire);`
			`(void)tail = (void)old_head;`
			`} while (!atomic_compare_exchange_weak_explicit(&g_bg_spill_head[class_idx], &old_head,`
			`(uintptr_t)rest,`
			`memory_order_release, memory_order_relaxed));`
			`}`
			`}`