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hakmem/core/hakmem_tiny_refill_p0.inc.h
Moe Charm (CI) 72b38bc994 Phase E3-FINAL: Fix Box API offset bugs - ALL classes now use correct offsets 
## Root Cause Analysis (GPT5)

**Physical Layout Constraints**:
- Class 0: 8B = [1B header][7B payload] → offset 1 = 9B needed =  IMPOSSIBLE
- Class 1-6: >=16B = [1B header][15B+ payload] → offset 1 =  POSSIBLE
- Class 7: 1KB → offset 0 (compatibility)

**Correct Specification**:
- HAKMEM_TINY_HEADER_CLASSIDX != 0:
  - Class 0, 7: next at offset 0 (overwrites header when on freelist)
  - Class 1-6: next at offset 1 (after header)
- HAKMEM_TINY_HEADER_CLASSIDX == 0:
  - All classes: next at offset 0

**Previous Bug**:
- Attempted "ALL classes offset 1" unification
- Class 0 with offset 1 caused immediate SEGV (9B > 8B block size)
- Mixed 2-arg/3-arg API caused confusion

## Fixes Applied

### 1. Restored 3-Argument Box API (core/box/tiny_next_ptr_box.h)
```c
// Correct signatures
void tiny_next_write(int class_idx, void* base, void* next_value)
void* tiny_next_read(int class_idx, const void* base)

// Correct offset calculation
size_t offset = (class_idx == 0 || class_idx == 7) ? 0 : 1;
```

### 2. Updated 123+ Call Sites Across 34 Files
- hakmem_tiny_hot_pop_v4.inc.h (4 locations)
- hakmem_tiny_fastcache.inc.h (3 locations)
- hakmem_tiny_tls_list.h (12 locations)
- superslab_inline.h (5 locations)
- tiny_fastcache.h (3 locations)
- ptr_trace.h (macro definitions)
- tls_sll_box.h (2 locations)
- + 27 additional files

Pattern: `tiny_next_read(base)` → `tiny_next_read(class_idx, base)`
Pattern: `tiny_next_write(base, next)` → `tiny_next_write(class_idx, base, next)`

### 3. Added Sentinel Detection Guards
- tiny_fast_push(): Block nodes with sentinel in ptr or ptr->next
- tls_list_push(): Block nodes with sentinel in ptr or ptr->next
- Defense-in-depth against remote free sentinel leakage

## Verification (GPT5 Report)

**Test Command**: `./out/release/bench_random_mixed_hakmem --iterations=70000`

**Results**:
-  Main loop completed successfully
-  Drain phase completed successfully
-  NO SEGV (previous crash at iteration 66151 is FIXED)
- ℹ️ Final log: "tiny_alloc(1024) failed" is normal fallback to Mid/ACE layers

**Analysis**:
- Class 0 immediate SEGV:  RESOLVED (correct offset 0 now used)
- 66K iteration crash:  RESOLVED (offset consistency fixed)
- Box API conflicts:  RESOLVED (unified 3-arg API)

## Technical Details

### Offset Logic Justification
```
Class 0:  8B block → next pointer (8B) fits ONLY at offset 0
Class 1: 16B block → next pointer (8B) fits at offset 1 (after 1B header)
Class 2: 32B block → next pointer (8B) fits at offset 1
...
Class 6: 512B block → next pointer (8B) fits at offset 1
Class 7: 1024B block → offset 0 for legacy compatibility
```

### Files Modified (Summary)
- Core API: `box/tiny_next_ptr_box.h`
- Hot paths: `hakmem_tiny_hot_pop*.inc.h`, `tiny_fastcache.h`
- TLS layers: `hakmem_tiny_tls_list.h`, `hakmem_tiny_tls_ops.h`
- SuperSlab: `superslab_inline.h`, `tiny_superslab_*.inc.h`
- Refill: `hakmem_tiny_refill.inc.h`, `tiny_refill_opt.h`
- Free paths: `tiny_free_magazine.inc.h`, `tiny_superslab_free.inc.h`
- Documentation: Multiple Phase E3 reports

## Remaining Work

None for Box API offset bugs - all structural issues resolved.

Future enhancements (non-critical):
- Periodic `grep -R '*(void**)' core/` to detect direct pointer access violations
- Enforce Box API usage via static analysis
- Document offset rationale in architecture docs

🤖 Generated with [Claude Code](https://claude.com/claude-code)

Co-Authored-By: Claude <noreply@anthropic.com>
2025-11-13 06:50:20 +09:00

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// hakmem_tiny_refill_p0.inc.h
// ChatGPT Pro P0: Complete Batch Refill (SLL用)
//
// Purpose: Optimize sll_refill_small_from_ss with batch carving
// Based on: tls_refill_from_tls_slab (hakmem_tiny_tls_ops.h:115-126)
//
// Key optimization: ss_active_inc × 64 → ss_active_add × 1
//
// Maintains: Existing g_tls_sll_head fast path (no changes to hot path!)
//
// Enable P0 by default for testing (set to 0 to disable)
#ifndef HAKMEM_TINY_P0_BATCH_REFILL
#define HAKMEM_TINY_P0_BATCH_REFILL 0
#endif
#ifndef HAKMEM_TINY_REFILL_P0_INC_H
#define HAKMEM_TINY_REFILL_P0_INC_H
#include "tiny_box_geometry.h" // Box 3: Geometry & Capacity Calculator
// Debug counters (compile-time gated)
#if HAKMEM_DEBUG_COUNTERS
extern unsigned long long g_rf_hit_slab[];
// Diagnostic counters for refill early returns
extern unsigned long long g_rf_early_no_ss[]; // Line 27: !g_use_superslab
extern unsigned long long g_rf_early_no_meta[]; // Line 35: !meta
extern unsigned long long g_rf_early_no_room[]; // Line 40: room <= 0
extern unsigned long long g_rf_early_want_zero[]; // Line 55: want == 0
#endif
// Refill TLS SLL from SuperSlab with batch carving (P0 optimization)
#include "tiny_refill_opt.h"
#include "tiny_fc_api.h"
#include "superslab/superslab_inline.h" // For _ss_remote_drain_to_freelist_unsafe()
#include "box/integrity_box.h" // Box I: Integrity verification (Priority ALPHA)
#include "box/tiny_next_ptr_box.h" // Box API: Next pointer read/write
// Optional P0 diagnostic logging helper
static inline int p0_should_log(void) {
static int en = -1;
if (__builtin_expect(en == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_LOG");
en = (e && *e && *e != '0') ? 1 : 0;
}
return en;
}
static inline int sll_refill_batch_from_ss(int class_idx, int max_take) {
// Phase E1-CORRECT: C7 now has headers, can use P0 batch refill
// Runtime A/B kill switch (defensive). Set HAKMEM_TINY_P0_DISABLE=1 to bypass P0 path.
do {
static int g_p0_disable = -1;
if (__builtin_expect(g_p0_disable == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_DISABLE");
g_p0_disable = (e && *e && *e != '0') ? 1 : 0;
}
if (__builtin_expect(g_p0_disable, 0)) {
return 0;
}
} while (0);
if (!g_use_superslab || max_take <= 0) {
#if HAKMEM_DEBUG_COUNTERS
if (!g_use_superslab) g_rf_early_no_ss[class_idx]++;
#endif
return 0;
}
TinyTLSSlab* tls = &g_tls_slabs[class_idx];
uint32_t active_before = 0;
if (tls->ss) {
active_before = atomic_load_explicit(&tls->ss->total_active_blocks, memory_order_relaxed);
}
// CRITICAL DEBUG: Log class 7 pre-warm
if (__builtin_expect(class_idx == 7 && p0_should_log(), 0)) {
fprintf(stderr, "[P0_DEBUG_C7] Entry: tls->ss=%p tls->meta=%p max_take=%d\n",
(void*)tls->ss, (void*)tls->meta, max_take);
}
if (!tls->ss) {
// Try to obtain a SuperSlab for this class
if (superslab_refill(class_idx) == NULL) {
if (__builtin_expect(class_idx == 7 && p0_should_log(), 0)) {
fprintf(stderr, "[P0_DEBUG_C7] superslab_refill() returned NULL\n");
}
return 0;
}
if (__builtin_expect(class_idx == 7 && p0_should_log(), 0)) {
fprintf(stderr, "[P0_DEBUG_C7] After superslab_refill(): tls->ss=%p tls->meta=%p\n",
(void*)tls->ss, (void*)tls->meta);
}
}
TinySlabMeta* meta = tls->meta;
if (!meta) {
#if HAKMEM_DEBUG_COUNTERS
g_rf_early_no_meta[class_idx]++;
#endif
return 0;
}
/* BOX_BOUNDARY: Box 2 (Refill) → Box I (Integrity Check) */
#if HAKMEM_INTEGRITY_LEVEL >= 4
uint8_t* initial_slab_base = tls->slab_base ? tls->slab_base : tiny_slab_base_for(tls->ss, tls->slab_idx);
SlabMetadataState meta_initial = integrity_capture_slab_metadata(meta, initial_slab_base, class_idx);
INTEGRITY_CHECK_SLAB_METADATA(meta_initial, "P0 refill entry");
#endif
/* BOX_BOUNDARY: Box I → Box 2 (Integrity Verified) */
if (!meta) {
if (__builtin_expect(class_idx == 7 && p0_should_log(), 0)) {
fprintf(stderr, "[P0_DEBUG_C7] meta is NULL after superslab_refill, returning 0\n");
}
return 0;
}
// Optional: Direct-FC fast path for class 5 (256B) / class 7 (1024B)
// env:
// - HAKMEM_TINY_P0_DIRECT_FC (default ON for class5)
// - HAKMEM_TINY_P0_DIRECT_FC_C7 (default OFF for class7)
do {
static int g_direct_fc = -1;
static int g_direct_fc_c7 = -1;
if (__builtin_expect(g_direct_fc == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_DIRECT_FC");
// Default ON when unset
g_direct_fc = (e && *e && *e == '0') ? 0 : 1;
}
if (__builtin_expect(g_direct_fc_c7 == -1, 0)) {
const char* e7 = getenv("HAKMEM_TINY_P0_DIRECT_FC_C7");
// Default OFF for class7 (1KB) until stability is fully verified; opt-in via env
g_direct_fc_c7 = (e7 && *e7) ? ((*e7 == '0') ? 0 : 1) : 0;
}
if (__builtin_expect((g_direct_fc && class_idx == 5) || (g_direct_fc_c7 && class_idx == 7), 0)) {
int room = tiny_fc_room(class_idx);
if (room <= 0) return 0;
// Drain only if above threshold
uint32_t rmt = atomic_load_explicit(&tls->ss->remote_counts[tls->slab_idx], memory_order_relaxed);
static int g_drain_th = -1;
if (__builtin_expect(g_drain_th == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_DRAIN_THRESH");
g_drain_th = (e && *e) ? atoi(e) : 64;
if (g_drain_th < 0) g_drain_th = 0;
}
if (rmt >= (uint32_t)g_drain_th) {
static int no_drain = -1;
if (__builtin_expect(no_drain == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_NO_DRAIN");
no_drain = (e && *e && *e != '0') ? 1 : 0;
}
if (!no_drain) {
_ss_remote_drain_to_freelist_unsafe(tls->ss, tls->slab_idx, tls->meta);
}
}
// Gather pointers without writing into objects
void* out[128]; int produced = 0;
TinySlabMeta* m = tls->meta;
// Box 3: Get stride (block size + header, except C7 which is headerless)
size_t bs = tiny_stride_for_class(class_idx);
uint8_t* base = tls->slab_base ? tls->slab_base : tiny_slab_base_for_geometry(tls->ss, tls->slab_idx);
while (produced < room) {
if (__builtin_expect(m->freelist != NULL, 0)) {
// Phase E1-CORRECT: Use Box API for freelist next pointer read
void* p = m->freelist; m->freelist = tiny_next_read(class_idx, p); m->used++;
out[produced++] = p;
continue;
}
if (__builtin_expect(m->carved < m->capacity, 1)) {
void* p = (void*)(base + ((size_t)m->carved * bs));
m->carved++; m->used++;
out[produced++] = p;
continue;
}
// Need to move to another slab with space
if (__builtin_expect(superslab_refill(class_idx) == NULL, 0)) break;
// Rebind
tls = &g_tls_slabs[class_idx];
m = tls->meta;
base = tls->slab_base ? tls->slab_base : tiny_slab_base_for(tls->ss, tls->slab_idx);
}
if (produced > 0) {
ss_active_add(tls->ss, (uint32_t)produced);
int pushed = tiny_fc_push_bulk(class_idx, out, produced);
(void)pushed; // roomに合わせているので一致するはず
if (p0_should_log()) {
static _Atomic int g_logged = 0;
int exp = 0;
if (atomic_compare_exchange_strong(&g_logged, &exp, 1)) {
fprintf(stderr, "[P0_DIRECT_FC_TAKE] cls=%d take=%d room=%d drain_th=%d remote_cnt=%u\n",
class_idx, produced, room, g_drain_th, rmt);
}
}
return produced;
}
// fallthrough to regular path
}
} while (0);
// Compute how many we can actually push into SLL without overflow
uint32_t sll_cap = sll_cap_for_class(class_idx, (uint32_t)TINY_TLS_MAG_CAP);
int room = (int)sll_cap - (int)g_tls_sll_count[class_idx];
if (room <= 0) {
#if HAKMEM_DEBUG_COUNTERS
g_rf_early_no_room[class_idx]++;
#endif
return 0;
}
// For hot tiny classes (0..3), allow an env override to increase batch size
uint32_t want = (uint32_t)max_take;
if (class_idx <= 3) {
static int g_hot_override = -2; // -2 = uninitialized, -1 = no override, >0 = value
if (__builtin_expect(g_hot_override == -2, 0)) {
const char* e = getenv("HAKMEM_TINY_REFILL_COUNT_HOT");
int v = (e && *e) ? atoi(e) : -1;
if (v < 0) v = -1; if (v > 256) v = 256; // clamp
g_hot_override = v;
}
if (g_hot_override > 0) want = (uint32_t)g_hot_override;
} else {
// Mid classes (>=4): optional override for batch size
static int g_mid_override = -2; // -2 = uninitialized, -1 = no override, >0 = value
if (__builtin_expect(g_mid_override == -2, 0)) {
const char* e = getenv("HAKMEM_TINY_REFILL_COUNT_MID");
int v = (e && *e) ? atoi(e) : -1;
if (v < 0) v = -1; if (v > 256) v = 256; // clamp
g_mid_override = v;
}
if (g_mid_override > 0) want = (uint32_t)g_mid_override;
}
if (want > (uint32_t)room) want = (uint32_t)room;
if (want == 0) {
#if HAKMEM_DEBUG_COUNTERS
g_rf_early_want_zero[class_idx]++;
#endif
return 0;
}
// Box 3: Get stride (block size + header, except C7 which is headerless)
size_t bs = tiny_stride_for_class(class_idx);
int total_taken = 0;
// === P0 Batch Carving Loop ===
while (want > 0) {
// Calculate slab base for validation (accounts for 2048 offset in slab 0)
uintptr_t ss_base = 0;
uintptr_t ss_limit = 0;
if (tls->ss && tls->slab_idx >= 0) {
// Box 3: Get slab base (handles Slab 0 offset)
uint8_t* slab_base = tiny_slab_base_for_geometry(tls->ss, tls->slab_idx);
ss_base = (uintptr_t)slab_base;
// Box 3: Get usable bytes for limit calculation
ss_limit = ss_base + tiny_usable_bytes_for_slab(tls->slab_idx);
}
// CRITICAL FIX: Drain remote queue BEFORE popping from freelist
// Without this, blocks in both freelist and remote queue can be double-allocated
// (Thread A pops from freelist, Thread B adds to remote queue, Thread A drains remote → overwrites user data)
// OPTIMIZATION: Only drain if remote queue is non-empty (check atomic counter)
if (tls->ss && tls->slab_idx >= 0) {
uint32_t remote_count = atomic_load_explicit(&tls->ss->remote_counts[tls->slab_idx], memory_order_relaxed);
if (remote_count > 0) {
// Runtime A/B: allow skipping remote drain for切り分け
static int no_drain = -1;
if (__builtin_expect(no_drain == -1, 0)) {
const char* e = getenv("HAKMEM_TINY_P0_NO_DRAIN");
no_drain = (e && *e && *e != '0') ? 1 : 0;
}
if (!no_drain) {
_ss_remote_drain_to_freelist_unsafe(tls->ss, tls->slab_idx, meta);
}
}
}
// Handle freelist items first (usually 0)
TinyRefillChain chain;
uint32_t from_freelist = trc_pop_from_freelist(
meta, class_idx, ss_base, ss_limit, bs, want, &chain);
if (from_freelist > 0) {
trc_splice_to_sll(class_idx, &chain, &g_tls_sll_head[class_idx], &g_tls_sll_count[class_idx]);
// FIX: Blocks from freelist were decremented when freed, must increment when allocated
ss_active_add(tls->ss, from_freelist);
// FIX: Keep TinySlabMeta::used consistent with non-P0 path
meta->used = (uint16_t)((uint32_t)meta->used + from_freelist);
/* BOX_BOUNDARY: Box 2 → Box I (Verify metadata after freelist pop) */
#if HAKMEM_INTEGRITY_LEVEL >= 4
SlabMetadataState meta_after_freelist = integrity_capture_slab_metadata(
meta, ss_base, class_idx);
INTEGRITY_CHECK_SLAB_METADATA(meta_after_freelist, "P0 after freelist pop");
#endif
/* BOX_BOUNDARY: Box I → Box 2 */
extern unsigned long long g_rf_freelist_items[];
g_rf_freelist_items[class_idx] += from_freelist;
total_taken += from_freelist;
want -= from_freelist;
if (want == 0) break;
}
// === Linear Carve (P0 Key Optimization!) ===
// Use monotonic 'carved' to track linear progression (used can decrement on free)
if (meta->carved >= meta->capacity) {
// Slab exhausted, try to get another
if (superslab_refill(class_idx) == NULL) break;
// CRITICAL FIX: Reload tls pointer after superslab_refill() binds new slab
tls = &g_tls_slabs[class_idx];
meta = tls->meta;
if (!meta) break;
/* BOX_BOUNDARY: Box 2 → Box I (Verify new slab after superslab_refill) */
#if HAKMEM_INTEGRITY_LEVEL >= 4
uint8_t* new_slab_base = tls->slab_base ? tls->slab_base : tiny_slab_base_for(tls->ss, tls->slab_idx);
SlabMetadataState meta_after_refill = integrity_capture_slab_metadata(
meta, new_slab_base, class_idx);
INTEGRITY_CHECK_SLAB_METADATA(meta_after_refill, "P0 after superslab_refill");
#endif
/* BOX_BOUNDARY: Box I → Box 2 */
continue;
}
uint32_t available = meta->capacity - meta->carved;
uint32_t batch = want;
if (batch > available) batch = available;
if (batch == 0) break;
// Get slab base
uint8_t* slab_base = tls->slab_base ? tls->slab_base
: tiny_slab_base_for(tls->ss, tls->slab_idx);
// Diagnostic log (one-shot)
#if !HAKMEM_BUILD_RELEASE
static _Atomic int g_carve_log_printed = 0;
if (atomic_load(&g_carve_log_printed) == 0 &&
atomic_exchange(&g_carve_log_printed, 1) == 0) {
fprintf(stderr, "[BATCH_CARVE] cls=%u slab=%d used=%u cap=%u batch=%u base=%p bs=%zu\n",
class_idx, tls->slab_idx, meta->used, meta->capacity, batch,
(void*)slab_base, bs);
fflush(stderr);
}
#endif
TinyRefillChain carve;
trc_linear_carve(slab_base, bs, meta, batch, class_idx, &carve);
// One-shot sanity: validate first few nodes are within the slab and stride-aligned
#if !HAKMEM_BUILD_RELEASE
do {
static _Atomic int g_once = 0;
int exp = 0;
if (atomic_compare_exchange_strong(&g_once, &exp, 1)) {
uintptr_t base_chk = (uintptr_t)(tls->slab_base ? tls->slab_base : tiny_slab_base_for(tls->ss, tls->slab_idx));
uintptr_t limit_chk = base_chk + tiny_usable_bytes_for_slab(tls->slab_idx);
void* node = carve.head;
for (int i = 0; i < 3 && node; i++) {
uintptr_t a = (uintptr_t)node;
if (!(a >= base_chk && a < limit_chk)) {
fprintf(stderr, "[P0_SANITY_FAIL] out_of_range cls=%d node=%p base=%p limit=%p bs=%zu\n",
class_idx, node, (void*)base_chk, (void*)limit_chk, bs);
abort();
}
size_t off = (size_t)(a - base_chk);
if ((off % bs) != 0) {
fprintf(stderr, "[P0_SANITY_FAIL] misaligned cls=%d node=%p off=%zu bs=%zu base=%p\n",
class_idx, node, off, bs, (void*)base_chk);
abort();
}
node = tiny_next_read(class_idx, node);
}
}
} while (0);
#endif
trc_splice_to_sll(class_idx, &carve, &g_tls_sll_head[class_idx], &g_tls_sll_count[class_idx]);
// FIX: Update SuperSlab active counter (was missing!)
ss_active_add(tls->ss, batch);
/* BOX_BOUNDARY: Box 2 → Box I (Verify metadata after linear carve) */
#if HAKMEM_INTEGRITY_LEVEL >= 4
SlabMetadataState meta_after_carve = integrity_capture_slab_metadata(
meta, slab_base, class_idx);
INTEGRITY_CHECK_SLAB_METADATA(meta_after_carve, "P0 after linear carve");
#endif
/* BOX_BOUNDARY: Box I → Box 2 */
extern unsigned long long g_rf_carve_items[];
g_rf_carve_items[class_idx] += batch;
total_taken += batch;
want -= batch;
}
#if HAKMEM_DEBUG_COUNTERS
// Track successful SLL refills from SuperSlab (compile-time gated)
// NOTE: Increment unconditionally to verify counter is working
g_rf_hit_slab[class_idx]++;
#endif
if (tls->ss && p0_should_log()) {
uint32_t active_after = atomic_load_explicit(&tls->ss->total_active_blocks, memory_order_relaxed);
int32_t delta = (int32_t)active_after - (int32_t)active_before;
if ((int32_t)total_taken != delta) {
fprintf(stderr,
"[P0_COUNTER_MISMATCH] cls=%d slab=%d taken=%d active_delta=%d used=%u carved=%u cap=%u freelist=%p\n",
class_idx, tls->slab_idx, total_taken, delta,
(unsigned)meta->used, (unsigned)meta->carved, (unsigned)meta->capacity,
meta->freelist);
} else {
fprintf(stderr,
"[P0_COUNTER_OK] cls=%d slab=%d taken=%d active_delta=%d\n",
class_idx, tls->slab_idx, total_taken, delta);
}
}
return total_taken;
}
#endif // HAKMEM_TINY_REFILL_P0_INC_H
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