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hakmem/core/tiny_alloc_fast_inline.h
Moe Charm (CI) dc9e650db3 Tiny Pool redesign: P0.1, P0.3, P1.1, P1.2 - Out-of-band class_idx lookup 
This commit implements the first phase of Tiny Pool redesign based on
ChatGPT architecture review. The goal is to eliminate Header/Next pointer
conflicts by moving class_idx lookup out-of-band (to SuperSlab metadata).

## P0.1: C0(8B) class upgraded to 16B
- Size table changed: {16,32,64,128,256,512,1024,2048} (8 classes)
- LUT updated: 1..16 → class 0, 17..32 → class 1, etc.
- tiny_next_off: C0 now uses offset 1 (header preserved)
- Eliminates edge cases for 8B allocations

## P0.3: Slab reuse guard Box (tls_slab_reuse_guard_box.h)
- New Box for draining TLS SLL before slab reuse
- ENV gate: HAKMEM_TINY_SLAB_REUSE_GUARD=1
- Prevents stale pointers when slabs are recycled
- Follows Box theory: single responsibility, minimal API

## P1.1: SuperSlab class_map addition
- Added uint8_t class_map[SLABS_PER_SUPERSLAB_MAX] to SuperSlab
- Maps slab_idx → class_idx for out-of-band lookup
- Initialized to 255 (UNASSIGNED) on SuperSlab creation
- Set correctly on slab initialization in all backends

## P1.2: Free fast path uses class_map
- ENV gate: HAKMEM_TINY_USE_CLASS_MAP=1
- Free path can now get class_idx from class_map instead of Header
- Falls back to Header read if class_map returns invalid value
- Fixed Legacy Backend dynamic slab initialization bug

## Documentation added
- HAKMEM_ARCHITECTURE_OVERVIEW.md: 4-layer architecture analysis
- TLS_SLL_ARCHITECTURE_INVESTIGATION.md: Root cause analysis
- PTR_LIFECYCLE_TRACE_AND_ROOT_CAUSE_ANALYSIS.md: Pointer tracking
- TINY_REDESIGN_CHECKLIST.md: Implementation roadmap (P0-P3)

## Test results
- Baseline: 70% success rate (30% crash - pre-existing issue)
- class_map enabled: 70% success rate (same as baseline)
- Performance: ~30.5M ops/s (unchanged)

## Next steps (P1.3, P2, P3)
- P1.3: Add meta->active for accurate TLS/freelist sync
- P2: TLS SLL redesign with Box-based counting
- P3: Complete Header out-of-band migration

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

Co-Authored-By: Claude <noreply@anthropic.com>
2025-11-28 13:42:39 +09:00

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// tiny_alloc_fast_inline.h - Phase 7 Task 2: Aggressive inline TLS cache access
// Purpose: Eliminate function call overhead (5-10 cycles) in hot path
// Design: Macro-based inline expansion of TLS freelist operations
// Performance: Expected +10-15% (22M → 24-25M ops/s)
#ifndef TINY_ALLOC_FAST_INLINE_H
#define TINY_ALLOC_FAST_INLINE_H
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#include "hakmem_build_flags.h"
#include "tiny_remote.h" // for TINY_REMOTE_SENTINEL (defense-in-depth)
#include "box/tiny_next_ptr_box.h" // Phase E1-CORRECT: unified next pointer API
#include "tiny_region_id.h" // For HEADER_MAGIC, HEADER_CLASS_MASK (Fix #7)
#include "box/tls_sll_box.h"
// External TLS variables (defined in hakmem_tiny.c)
// Phase 3d-B: TLS Cache Merge - Unified TLS SLL structure
extern __thread TinyTLSSLL g_tls_sll[TINY_NUM_CLASSES];
extern __thread const char* g_tls_sll_last_writer[TINY_NUM_CLASSES];
#ifndef TINY_NUM_CLASSES
#define TINY_NUM_CLASSES 8
#endif
// ========== Inline Macro: TLS Freelist Pop ==========
//
// Aggressive inline expansion of tiny_alloc_fast_pop()
// Saves: 5-10 cycles (function call overhead + register spilling)
//
// Assembly comparison (x86-64):
// Function call:
// push %rbx ; Save registers
// mov %edi, %ebx ; class_idx to %ebx
// call tiny_alloc_fast_pop ; Call (5-10 cycles overhead)
// pop %rbx ; Restore registers
// test %rax, %rax ; Check result
//
// Inline macro:
// mov g_tls_sll_head(%rdi), %rax ; Direct access (3-4 cycles)
// test %rax, %rax
// je .miss
// mov (%rax), %rdx
// mov %rdx, g_tls_sll_head(%rdi)
//
// Result: 5-10 fewer instructions, better register allocation
//
#define TINY_ALLOC_FAST_POP_INLINE(class_idx, ptr_out) do { \
extern int g_tls_sll_class_mask; \
if (__builtin_expect(((g_tls_sll_class_mask & (1u << (class_idx))) == 0), 0)) { \
(ptr_out) = NULL; \
break; \
} \
void* _head = g_tls_sll[(class_idx)].head; \
if (__builtin_expect(_head != NULL, 1)) { \
if (__builtin_expect((uintptr_t)_head == TINY_REMOTE_SENTINEL, 0)) { \
/* Break the chain defensively if sentinel leaked into TLS SLL */ \
g_tls_sll[(class_idx)].head = NULL; \
g_tls_sll_last_writer[(class_idx)] = "fast_pop_sentinel"; \
if (g_tls_sll[(class_idx)].count > 0) g_tls_sll[(class_idx)].count--; \
(ptr_out) = NULL; \
} else { \
/* Phase E1-CORRECT: Use Box API for next pointer read */ \
void* _next = tiny_next_read(class_idx, _head); \
if (__builtin_expect(class_idx == 4 || class_idx == 6, 0)) { \
tls_sll_diag_next(class_idx, _head, _next, "fast_pop_next"); \
} \
g_tls_sll[(class_idx)].head = _next; \
g_tls_sll_last_writer[(class_idx)] = "fast_pop"; \
if ((class_idx == 4 || class_idx == 6) && _next && ((uintptr_t)_next < 4096 || (uintptr_t)_next > 0x00007fffffffffffULL)) { \
static __thread uint8_t s_fast_pop_invalid_log[8] = {0}; \
if (s_fast_pop_invalid_log[(class_idx)] < 4) { \
fprintf(stderr, "[TLS_SLL_FAST_POP_INVALID] cls=%d head=%p next=%p\n", (class_idx), _head, _next); \
s_fast_pop_invalid_log[(class_idx)]++; \
} \
g_tls_sll[(class_idx)].head = NULL; \
/* keep count unchanged to flag drop */ \
g_tls_sll_last_writer[(class_idx)] = "fast_pop_post_invalid"; \
(ptr_out) = NULL; \
} else { \
if (g_tls_sll[(class_idx)].count > 0) { \
g_tls_sll[(class_idx)].count--; \
} \
/* Phase 7: Fast path returns BASE pointer; HAK_RET_ALLOC does BASE→USER */ \
(ptr_out) = _head; \
} \
} \
} else { \
(ptr_out) = NULL; \
} \
} while(0)
// ========== Inline Macro: TLS Freelist Push ==========
//
// Aggressive inline expansion of tiny_alloc_fast_push()
// Saves: 5-10 cycles (function call overhead)
//
// Assembly comparison:
// Function call:
// mov %rdi, %rsi ; ptr to %rsi
// mov %ebx, %edi ; class_idx to %edi
// call tiny_alloc_fast_push ; Call (5-10 cycles)
//
// Inline macro:
// mov g_tls_sll_head(%rdi), %rax ; Direct inline (2-3 cycles)
// mov %rax, (%rsi)
// mov %rsi, g_tls_sll_head(%rdi)
//
#if HAKMEM_TINY_HEADER_CLASSIDX
// DESIGN RULE: "Header is written by BOTH Alloc and Free/Drain"
// FREE path: Restore header for Class 1-6, then write Next pointer
// ALLOC path: Write header before returning to user (HAK_RET_ALLOC)
// This ensures Free path can read header to determine class_idx
#define TINY_ALLOC_FAST_PUSH_INLINE(class_idx, ptr) do { \
extern int g_tls_sll_class_mask; \
if (__builtin_expect(((g_tls_sll_class_mask & (1u << (class_idx))) == 0), 0)) { \
break; \
} \
if (!(ptr)) break; \
/* Phase E1-CORRECT: API ptr is USER pointer (= base+1). Convert back to BASE. */ \
uint8_t* _base = (uint8_t*)(ptr) - 1; \
/* C0-C6: Restore header BEFORE writing Next. C7: skip (next overwrites header). */ \
if ((class_idx) != 7) { \
*_base = HEADER_MAGIC | ((class_idx) & HEADER_CLASS_MASK); \
} \
/* Link node using BASE as the canonical SLL node address. */ \
tiny_next_write((class_idx), _base, g_tls_sll[(class_idx)].head); \
g_tls_sll[(class_idx)].head = _base; \
g_tls_sll_last_writer[(class_idx)] = "fast_push"; \
g_tls_sll[(class_idx)].count++; \
} while(0)
#else
#define TINY_ALLOC_FAST_PUSH_INLINE(class_idx, ptr) do { \
tiny_next_write(class_idx, (ptr), g_tls_sll[(class_idx)].head); \
g_tls_sll[(class_idx)].head = (ptr); \
g_tls_sll_last_writer[(class_idx)] = "fast_push"; \
g_tls_sll[(class_idx)].count++; \
} while(0)
#endif
// ========== Performance Notes ==========
//
// Benchmark results (expected):
// - Random Mixed 128B: 21M → 23M ops/s (+10%)
// - Random Mixed 256B: 19M → 22M ops/s (+15%)
// - Larson 1T: 2.7M → 3.0M ops/s (+11%)
//
// Key optimizations:
// 1. No function call overhead (save 5-10 cycles)
// 2. Better register allocation (inline knows full context)
// 3. No stack frame setup/teardown
// 4. Compiler can optimize across macro boundaries
//
// Trade-offs:
// 1. Code size: +100-200 bytes (each call site expanded)
// 2. Debug visibility: Macros harder to step through
// 3. Maintenance: Changes must be kept in sync with function version
//
// Recommendation: Use inline macros for CRITICAL hot paths only
// (alloc/free fast path), keep functions for diagnostics/debugging
#endif // TINY_ALLOC_FAST_INLINE_H
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