Recent lld/ELF performance improvements

Since the LLVM 22 branch was cut, I've landed patches that parallelize more link phases and cut task-runtime overhead. This post compares current main against lld 22.1, mold, and wild.

Headline: a Release+Asserts clang --gc-sections link is 1.37x as fast as lld 22.1; Chromium debug with --gdb-index is 1.07x as fast. mold and wild are still ahead — the last section explains why.

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Bit-field layout

The C and C++ standards leave nearly every detail to the implementation. C23 §6.7.3.2:

An implementation may allocate any addressable storage unit large enough to hold a bit-field. If enough space remains, a bit-field that immediately follows another bit-field in a structure shall be packed into adjacent bits of the same unit. If insufficient space remains, whether a bit-field that does not fit is put into the next unit or overlaps adjacent units is implementation-defined. The order of allocation of bit-fields within a unit (high-order to low-order or low-order to high-order) is implementation-defined. The alignment of the addressable storage unit is unspecified

C++ is also terse — [class.bit]p1:

Allocation of bit-fields within a class object is implementation-defined. Alignment of bit-fields is implementation-defined. Bit-fields are packed into some addressable allocation unit.

The actual rules come from the platform ABI:

  • Itanium ABI — used on Linux, macOS, BSD, and most non-Windows platforms. The Itanium C++ ABI (section 2.4) defers bit-field placement to "the base C ABI" but adds its own constraints (notably: bit-fields are never placed in the tail padding of a base class).
  • System V ABI Processor Supplement. The x86-64 psABI says little about bit-fields, while the AArch64 AAPCS has a more detailed description.
  • Microsoft ABI — used on Windows (MSVC). In GCC and Clang, structs with the ms_struct attribute also mimics this ABI.

Clang implements both ABIs in clang/lib/AST/RecordLayoutBuilder.cpp. It processes bit-fields in two distinct phases:

  1. Layout (storage units) — assign a bit offset to every bit-field. This is ABI-specified and determines sizeof and alignof.
  2. Codegen (access units) — choose what LLVM IR loads and stores to emit. This is a compiler optimization that affects generated code but not the ABI.

Understanding these separately is the key to understanding bit-fields. This article focuses on Itanium (the default on most platforms), with a section on how the Microsoft ABI differs.

Phase 1: Storage Units

In clang/lib/AST/RecordLayoutBuilder.cpp, ItaniumRecordLayoutBuilder::LayoutFields lays out fields of a RecordDecl. For each bit field, it calls LayoutBitField to determine the storage unit and bit offset.

A storage unit is a region of sizeof(T) bytes, by default aligned to alignof(T). For an int bit-field, that's a 4-byte region at a 4-byte-aligned offset. The alignment can be reduced by the packed attribute and #pragma pack.

  • StorageUnitSize = sizeof(T) * 8 — the unit's size in bits
  • FieldAlign = alignof(T) in bits — the unit's alignment (before modifiers)
  • FieldOffset — the first bit after the last bit-field

Itanium's Core Rule

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if (FieldSize == 0 ||
    (AllowPadding &&
     (FieldOffset & (FieldAlign-1)) + FieldSize > StorageUnitSize))
  FieldOffset = alignTo(FieldOffset, FieldAlign);

Compute where FieldOffset falls within its aligned storage unit. If the remaining space is less than FieldSize, round up to the next aligned boundary. Otherwise, pack the bit-field at the current position.

Declared Type Matters

Consider two structs that store the same total number of bits (7 + 7 + 2 = 16) but use different declared types:

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struct U8  { uint8_t  a:7, b:7, c:2; };   // sizeof = 3
struct U16 { uint16_t a:7, b:7, c:2; };   // sizeof = 2

struct S1 { int a:14; int b:10; int c:30; };   // sizeof = 8

Walk-through for U8 (all fields have StorageUnitSize = 8, FieldAlign = 8):

  • a at bit 0. Position = 0, 0 + 7 = 7 <= 8. Fits. Offset = 0.
  • b at bit 7. Position = 7, 7 + 7 = 14 > 8. Doesn't fit. New unit at bit 8. Offset = 8.
  • c at bit 15. Position = 15 - 8 = 7, 7 + 2 = 9 > 8. Doesn't fit. New unit at bit 16. Offset = 16.

Three 1-byte storage units. sizeof(U8) = 3. Eight padding bits wasted.

Walk-through for U16 (all fields have StorageUnitSize = 16, FieldAlign = 16):

  • a at bit 0. Position = 0, 0 + 7 = 7 <= 16. Fits. Offset = 0.
  • b at bit 7. Position = 7, 7 + 7 = 14 <= 16. Fits. Offset = 7.
  • c at bit 14. Position = 14, 14 + 2 = 16 <= 16. Fits. Offset = 14.

One 2-byte storage unit. sizeof(U16) = 2. No waste.

Walk-through for S1 (all fields have StorageUnitSize = 32, FieldAlign = 32):

  • a at bit 0. Position = 0, 14 fits in 32. Offset = 0.
  • b at bit 14. Position = 14, 14 + 10 = 24 <= 32. Fits. Offset = 14. Bits 24–31 are padding (unfilled tail of the first storage unit).
  • c at bit 24. Position = 24, 24 + 30 = 54 > 32. Doesn't fit. New unit at bit 32. Offset = 32. Bits 62–63 are padding (unfilled tail of the second storage unit).

sizeof(S1) = 8, alignof(S1) = 4.

Note: Phase 1 uses two int storage units, but Phase 2 is free to merge a, b, and c into a single i64 access unit (since there are no non-bit-field barriers and 8 bytes fits in a register). On x86_64, the LLVM type ends up as { i64 }.

Mixed Types

When bit-fields have different declared types, the storage unit size changes:

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struct S2 { int a:24; short b:8; };   // sizeof = 4
  • a is int (StorageUnitSize = 32). Placed at bit 0.
  • b is short (StorageUnitSize = 16, FieldAlign = 16). Current offset = 24. Position within a 16-bit aligned unit: 24 % 16 = 8. 8 + 8 = 16 <= 16. Fits. Offset = 24.

sizeof(S2) = 4. The short bit-field overlaps into the int's storage unit. Under Itanium, storage units of different types can share bytes.

The short can also reuse space left by a smaller bit-field:

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struct S2b { int a:16; short b:8; };   // sizeof = 4
  • a is int (StorageUnitSize = 32). Placed at bit 0.
  • b is short (StorageUnitSize = 16, FieldAlign = 16). Current offset = 16. Position within a 16-bit aligned unit: 16 % 16 = 0. 0 + 8 = 8 <= 16. Fits. Offset = 16.

Here b's 16-bit storage unit (bits 16–31) falls entirely within a's 32-bit storage unit.

Under Microsoft ABI, sizeof is 8: the type size change from int to short forces a new storage unit.

This overlapping extends to non-bit-field members too. A non-bit-field can be allocated within the unfilled bytes of a preceding bit-field's storage unit:

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struct S2c { uint16_t first:8; uint8_t second; };   // sizeof = 2
  • first is uint16_t:8. Placed at bit 0. Uses 8 bits of a 16-bit storage unit (bytes 0–1).
  • second is a non-bit-field uint8_t. The bit-field state resets, but DataSize is only 1 byte. second (alignment 1) goes at byte 1 (bit 8) — inside first's storage unit.

Note that this overlapping means a write to first via its access unit could touch byte 1 where second lives. Phase 2 must ensure the access units don't clobber each other (see Hard constraints).

Under Microsoft ABI, sizeof is 4: first gets a full uint16_t unit (2 bytes), and second starts at byte 2 instead of byte 1.

Non-bit-field After Bit-field

When a non-bit-field field cannot fit within the remaining bytes, it resets the bit-field state and unfilled bits become padding:

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struct S3 { int a:10; int b:6; char c; int d:6; };   // sizeof = 4
  • a at bit 0, b at bit 10 — both fit in the first int storage unit. a + b occupy 16 bits = 2 bytes, leaving 16 bits unused in the 32-bit storage unit.
  • c is not a bit-field. It resets UnfilledBitsInLastUnit to 0. c (a char, alignment 1) goes at byte 2 (bit 16). A subsequent bit-field could have used bits 16–31, but the non-bit-field c claims byte 2.
  • d is a new int bit-field. Current bit offset = 24 (byte 3). Position = 24 % 32 = 24. 24 + 6 = 30 <= 32. Fits. Offset = 24.

sizeof(S3) = 4.

Under Microsoft ABI, sizeof is 12: a+b get a full int unit (4 bytes), c starts at byte 4, and d gets a new int unit at byte 8.

Bit-field After Non-bit-field

The overlap works in the other direction too. When a bit-field follows a non-bit-field, its storage unit can encompass the preceding bytes:

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struct NB { char a; int b:4; };   // sizeof = 4
  • a is a char at byte 0. DataSize = 1 byte.
  • b is int:4. FieldOffset = 8, FieldAlign = 32, StorageUnitSize = 32. Position: 8 & 31 = 8. 8 + 4 = 12 ≤ 32. Fits. Offset = 8.

b's 4-byte int storage unit (bytes 0–3) encompasses a at byte 0. No padding is inserted — the core rule only cares whether the field fits within an aligned unit, not whether that unit overlaps earlier non-bit-field storage.

Under Microsoft ABI, sizeof is 8: b's int unit starts at byte 4, after a is padded to int alignment.

Attributes and Pragmas

Several attributes and pragmas alter the placement rules. They all work by changing FieldAlign.

packed — sets FieldAlign = 1 (bit-granular packing). Bitfields pack at the next available bit with no alignment constraint.

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struct [[gnu::packed]] P { int x:4, y:30, z:30; };
// 4 + 30 + 30 = 64 bits = 8 bytes. sizeof = 8.

Under Microsoft ABI, sizeof is 12: each bit-field must fit within a single int unit, so x, y, and z each get their own 4-byte unit.

packed can also be applied to individual fields:

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struct P2 { short a:8; [[gnu::packed]] int b:30; };   // sizeof = 6, b at bit 8
// Without packed on b: b at bit 32, sizeof = 8

Without packed, b's FieldAlign is 32, so it doesn't fit in a's short storage unit and starts a new int unit at bit 32. With packed, b's FieldAlign drops to 1, so it packs immediately after a at bit 8.

#pragma pack(N) — caps FieldAlign at N * 8 bits and suppresses the padding-insertion test (AllowPadding = false, so the overflow check is skipped — the field is placed at the current offset without rounding up).

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#pragma pack(1)
struct PP { char a; int b:4; int c:28; char s; };   // sizeof = 6
#pragma pack()

b packs at bit 8 by the normal core rule — (8 & 31) + 4 = 12 ≤ 32, so it fits. Without #pragma pack, c:28 at bit 12 would fail the same check — 12 + 28 = 40 > 32 — and round up to bit 32. With #pragma pack(1), AllowPadding is false, so the overflow check is skipped and c stays at bit 12. Total: a(8) + b+c(32) + s(8) = 48 bits = 6 bytes.

aligned(N) — forces minimum alignment. Overrides packed, but is itself overridden by #pragma pack.

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struct A { char a; [[gnu::aligned(16)]] int b:1; char c; };
// b aligned to 16 bytes = bit 128. c at byte 17. sizeof = 32, alignof = 16.

Precedence (for non-zero-width bit-fields): #pragma pack > aligned attr > packed attr > natural alignment.

Zero-width Bitfields

T : 0 rounds up to alignof(T), acting as a separator. Subsequent fields start in a new storage unit.

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struct Z { char x; int : 0; char y; };
// x86:         y at offset 4, sizeof = 5, alignof = 1
// ARM/AArch64: y at offset 4, sizeof = 8, alignof = 4

On most targets, anonymous bit-fields don't contribute to struct alignment. But on AArch32/AArch64 (with useZeroLengthBitfieldAlignment()), zero-width bit-fields do raise the struct's alignment.

Zero-width bit-fields are exempt from both packed and #pragma pack — they always round up to alignof(T).

Microsoft ABI Differences

Clang uses the Microsoft layout rules in two situations: targeting a Windows triple (e.g. x86_64-windows-msvc), which uses MicrosoftRecordLayoutBuilder; or applying __attribute__((ms_struct)) to individual structs on any target, which activates the IsMsStruct path inside ItaniumRecordLayoutBuilder. GCC documents the rules under TARGET_MS_BITFIELD_LAYOUT_P.

The Microsoft ABI uses a fundamentally different layout strategy. While Itanium packs bit-fields into overlapping storage units of potentially different types, Microsoft allocates a complete storage unit of the declared type, then parcels bits among successive bit-fields of the same type size.

The key differences:

Type size changes force a new storage unit. In the GCC documentation's wording: "a bit-field won't share the same storage unit with the previous bit-field if their underlying types have different sizes, and the bit-field will be aligned to the highest alignment of the underlying types of itself and of the previous bit-field." Itanium would let them overlap.

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struct Itn { int a:24; short b:8; };                             // sizeof = 4
struct __attribute__((ms_struct)) MS { int a:24; short b:8; };   // sizeof = 8

Under Itanium, b's short storage unit overlaps into a's int unit — everything fits in 4 bytes. Under Microsoft, the type size changes from 4 to 2, so b gets its own storage unit. The int unit (4 bytes) plus the short unit (2 bytes, padded to 4 for alignment) gives 8 bytes. Note that the rule is about type size, not type identity — int a:24; unsigned b:8 share a unit because both types are 4 bytes.

Each unit is discrete — this is a direct consequence of the type size rule.

Zero-width bit-fields are ignored unless they follow a non-zero-width bit-field. (MicrosoftRecordLayoutBuilder::layoutZeroWidthBitField.) GCC's documentation: "zero-sized bit-fields are disregarded unless they follow another nonzero-size bit-field." When honored, they terminate the current run and affect the struct's alignment.

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// MS mode:
struct MS_ZW1 { long : 0; char bar; };                       // sizeof = 1 (no preceding bit-field)
struct MS_ZW2 { char foo; int : 0; char bar; };              // sizeof = 2 (preceding non-bit-field doesn't count)
struct MS_ZW3 { int : 0; long : 0; char bar; };              // sizeof = 1 (zero-width doesn't count either)
struct MS_ZW4 { char foo : 4; int : 0; char bar; };          // sizeof = 8 (non-zero-width bit-field — honored)
struct MS_ZW5 { long : 0; char foo : 4; int : 0; char bar; };  // sizeof = 8 (first ignored, second honored)

Alignment = type size. The alignment of a fundamental type always equals its size — alignof(long long) == 8 even on targets where the natural alignment is 4 (like Darwin PPC32).

Unions. ms_struct ignores all alignment attributes in unions. All bit-fields use alignment 1 and start at offset 0.

Phase 2: Access Units

LLVM IR has no bit-field concept. To access a bit-field, the Clang-generated IR must:

  1. Load an integer from memory (the access unit)
  2. Mask and shift to extract or insert the bit-field's bits
  3. Store the integer back

The access unit is the LLVM type that gets loaded and stored. Choosing it well matters:

  • Too narrow means multiple memory operations for adjacent bit-field writes;
  • Too wide means touching memory unnecessarily or clobbering adjacent data.

Implementation: CGRecordLowering::accumulateBitFields (clang/lib/CodeGen/CGRecordLayoutBuilder.cpp).

Itanium: Merging Algorithm

Hard constraints — an access unit must never:

  1. Overlap non-bit-field storage. The C memory model allows non-bit-field members to be accessed from other threads. A load/store of the access unit must not touch bytes belonging to other members.
  2. Cross a zero-width bit-field at a byte boundary. Zero-width bit-fields define memory location boundaries — they are barriers.
  3. Extend into reusable tail padding. In C++, a derived class may place fields in a non-POD base class's tail padding. The access unit must not overwrite those bytes.

Soft goals — subject to the hard constraints, access units should be:

  • Power-of-2 sized (1, 2, 4, 8 bytes). Non-power-of-2 sizes (e.g., 3 bytes) get lowered as multiple smaller loads plus bit manipulation.
  • No wider than a register. Avoids multi-register loads.
  • Naturally aligned (on strict-alignment targets). Avoids the compiler synthesizing unaligned access sequences.
  • As wide as possible within the above. Fewer, wider accesses let LLVM combine adjacent bit-field writes into one read-modify-write.

The algorithm: spans then merging.

Step 1 — Spans. Bitfields that share a byte are inseparable. They form a minimal "span" that must be in the same access unit. A span is a maximal run of bit-fields where each successive one starts mid-byte.

Spans break at byte-aligned boundaries and at zero-width bit-field barriers. A field mid-byte is unconditionally part of the current span — step 2 never sees it as a merge point.

Step 2 — Merge. Starting from each span, try to widen the access unit by incorporating the next span. Accept the merge if the combined unit:

  • Fits in one register (<= RegSize)
  • Is power-of-2 and naturally aligned (on strict-alignment targets)
  • Doesn't cross a barrier (zero-width bit-field or non-bit-field storage)
  • The natural iN type fits before the limit offset

Track the best candidate and install it when merging can't improve further.

Access unit representation.

Clang represents each access unit as either an integer type iN or an array type [N x i8] (see CGRecordLowering::accumulateBitFields). iN is preferred — it generates a single load/store instruction. But LLVM's iN types have allocation sizes rounded up to powers of 2 (DataLayout.getTypeAllocSize). For example, i24 has allocation size 4 bytes.

If that rounded-up size would extend past the next field or past reusable tail padding, the access unit is clipped to [N x i8], which has an exact byte count. Clang assumes clipped for each new span (BestClipped = true) and sets it to false only when the natural iN fits within the available space (BeginOffset + TypeSize <= LimitOffset).

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// Tail padding reuse (C++)
struct A { int x:24; ~A(); };      // non-POD: DataSize=3, Size=4
struct B : A { char c; };          // c at offset 3, in A's tail padding

// i24 allocates 4 bytes, but byte 3 belongs to B::c.
// Access unit for x is clipped to [3 x i8].

Strict vs cheap unaligned. On targets with cheap unaligned access (x86, AArch64 without +strict-align), alignment checks are skipped — spans merge freely up to register width. On strict-alignment targets (e.g. -mstrict-align), a merge is rejected if the combined access unit would not be naturally aligned at its offset within the struct.

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struct Align { char x; short a:12; short b:4; char c:8; }; // sizeof = 6

// AArch64 -mno-strict-align:  %struct.S = type <{ i8, i8, i32 }>
//   → a+b+c merged into one i32 at offset 2 (unaligned, but cheap)
// AArch64 -mstrict-align:     %struct.S = type { i8, i16, i8 }
//   → a+b merged
//   → +c rejected; a+b stay as i16, c gets its own i8

-ffine-grained-bit-field-accesses. This Clang flag disables merging entirely. Each span becomes its own access unit — no adjacent spans are combined. For example:

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struct S4 { unsigned long f1:28, f2:4, f3:12; };
// Default:        %struct.S4 = type { i64 }       — spans merged into one access unit
// Fine-grained:   %struct.S4 = type { i32, i16 }  — each span kept separate

The flag is incompatible with sanitizers and is automatically disabled (with a warning) when any sanitizer is active.

Returning to S3:

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struct S3 { int a:10; int b:6; char c; int d:6; };

Phase 1 assigned: a@0, b@10, c@16 (byte 2), d@24 (byte 3).

Phase 2 sees two bit-field runs (separated by non-bit-field c):

Run 1: a and b (bits 0–15, bytes 0–1). They share byte 1 (bits 8–15), so they form one span. The span covers 2 bytes. The natural type i16 fits exactly — no clipping needed. Access unit: i16.

Run 2: d (bits 24–29, byte 3). Single span, 6 bits in 1 byte. Access unit: i8.

The resulting LLVM struct type:

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%struct.S3 = type { i16, i8, i8 }
                    a,b   c   d

To read a, codegen loads the i16, extracts bits 0–9. To read b, it loads the same i16, extracts bits 10–15. Neither load touches c.

When clipping is needed. Widen the bit-fields so a + b no longer fits in 2 bytes:

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struct S3w { int a:14; int b:10; char c; int d:6; };

Phase 1 assigned: a@0, b@14, c@24 (byte 3), d@32 (byte 4). sizeof(S3w) = 8.

Run 1: a and b (bits 0–23, bytes 0–2). The span covers 3 bytes. The natural type i24 has allocation size 4 bytes — but byte 3 belongs to c. The access unit is clipped to [3 x i8].

Run 2: d (bits 32–37, byte 4). Access unit: i8.

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%struct.S3w = type { [3 x i8], i8, i8, [3 x i8] }
                      a,b       c    d    padding

Endianness.

Access unit selection is endianness-agnostic — spans, merging, and clipping all work in byte offsets from the start of the struct. Endianness matters only when codegen emits the shift/mask sequence to extract or insert a bitfield within its access unit.

LLVM loads an access unit as a single integer. On little-endian, bit 0 of the integer corresponds to the lowest-addressed byte's LSB — bitfield offsets from Phase 1 can be used directly as shift amounts. On big-endian, bit 0 of the integer corresponds to the highest-addressed byte's MSB, so the bit numbering within the loaded integer is reversed.

Clang handles this in setBitFieldInfo (CGRecordLayoutBuilder.cpp):

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Info.Offset = (unsigned)(getFieldBitOffset(FD) - Context.toBits(StartOffset));
// ...
if (DataLayout.isBigEndian())
  Info.Offset = Info.StorageSize - (Info.Offset + Info.Size);

The little-endian offset counts up from the LSB; the big-endian offset is mirrored to count down from the MSB. EmitLoadOfBitfieldLValue (CGExpr.cpp) then uses Info.Offset uniformly — it right-shifts by Offset and masks to Size bits, which works for both endiannesses because the flip was already baked into Offset.

Microsoft: Discrete Access Units

Microsoft ABI's codegen is simple: each bit-field gets an access unit of its declared type. Adjacent bit-fields of the same type size share one access unit. Zero-width bit-fields and type-size changes break runs. There is no complex merging — the Phase 1 storage units are the access units.

Contrast S3 under both ABIs:

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struct S3 { int a:10; int b:6; char c; int d:6; };
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Itanium:   %struct.S3  = type { i16, i8, i8 }        // a,b merged into i16, d is i8
Microsoft: %struct.MS3 = type { i32, i8, i32 }       // a,b share i32 unit, d gets own i32

Itanium's Phase 2 merges a and b into the tightest access unit that covers both (i16), and clips or shrinks to avoid touching c. Microsoft uses the full declared type (int = i32) for each storage unit — no merging, no clipping.

Similarly for mixed types:

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struct S2 { int a:24; short b:8; };
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Itanium:   %struct.S2  = type { i32 }                 // a and b merged into one i32
Microsoft: %struct.MS2 = type { i32, i16 }            // separate units: i32 for a, i16 for b

Itanium merges a and b into a single i32 since they share the same 4 bytes. Microsoft gives each its own access unit matching the declared type.

Conclusion

Phase 1 decides where bits go — it's specified by the ABI and determines sizeof and alignof. Phase 2 decides how to access them — it's a compiler optimization that affects codegen but not the binary layout. They answer different questions and often produce different-sized units. The storage unit for a bit-field is determined by its declared type; the access unit is determined by what's safe and efficient to load.

Call relocation types

Most architectures encode direct branch/call instructions with a PC-relative displacement. This post discusses a specific category of branch relocations: those used for direct function calls and tail calls. Some architectures use two ELF relocation types for a call instruction:

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# i386, x86-64
call foo              # R_386_PC32, R_X86_64_PC32
call foo@plt          # R_386_PLT32, R_X86_64_PLT32

# m68k
bsr.l foo             # R_68K_PC32
bsr.l foo@plt         # R_68K_PLT32

# s390/s390x
brasl %r14, foo       # R_390_PC32DBL
brasl %r14, foo@plt   # R_390_PLT32DBL

# sparc
call    foo, 0        # not PIC: R_SPARC_WDISP30
call    foo, 0        # gas -KPIC: R_SPARC_WPLT30

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lld 22 ELF changes

For those unfamiliar, lld is the LLVM linker, supporting PE/COFF, ELF, Mach-O, and WebAssembly ports. These object file formats differ significantly, and each port must follow the conventions of the platform's system linker. As a result, the ports share limited code (diagnostics, memory allocation, etc) and have largely separate reviewer groups.

With LLVM 22.1 releasing soon, I've added some notes to the https://github.com/llvm/llvm-project/blob/release/22.x/lld/docs/ReleaseNotes.rst as an lld/ELF maintainer. As usual, I've reviewed almost all the patches not authored by me.

For the first time, I used an LLM agent (Claude Code) to help look through commits (git log release/21.x..release/22.x -- lld/ELF) and draft the release notes. Despite my request to only read lld/ELF changes, Claude Code also crafted notes for other ports, which I retained since their release notes had been quite sparse for several releases. Changes back ported to the 21.x release are removed (git log --oneline llvmorg-22-init..llvmorg-21.1.8 -- lld).

I'll delve into some of the key changes.

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Long branches in compilers, assemblers, and linkers

Branch instructions on most architectures use PC-relative addressing with a limited range. When the target is too far away, the branch becomes "out of range" and requires special handling.

Consider a large binary where main() at address 0x10000 calls foo() at address 0x8010000-over 128MiB away. On AArch64, the bl instruction can only reach ±128MiB, so this call cannot be encoded directly. Without proper handling, the linker would fail with an error like "relocation out of range." The toolchain must handle this transparently to produce correct executables.

This article explores how compilers, assemblers, and linkers work together to solve the long branch problem.

  • Compiler (IR to assembly): Handles branches within a function that exceed the range of conditional branch instructions
  • Assembler (assembly to relocatable file): Handles branches within a section where the distance is known at assembly time
  • Linker: Handles cross-section and cross-object branches discovered during final layout

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2025年总结

TODO

一如既往,主要在工具链领域耕耘。但由于工作忙碌在open source社区投入的时间减少了。

Blogging

不包括这篇总结,一共写了18篇文章。

llvm-project

Linux kernel

贡献了两个commits,被引用了一次。

ccls

  • clang.prependArgs
  • 支持了LLVM 21和22

ELF specification

尝试推进compact section header table,没有取得共识。 一些成员希望采用general compression (like zstd)的方式,像SHF_COMPRESSED那样压缩section header table。包括我在内的另一些人不喜欢采用general compression。

Misc

Reported 6 feature requests or bugs to binutils.

旅行

  • 第一次去:台南、西安、兰州、天水、Sacramento、Puerto Vallarta, Jalisco, Mexico、Mazatlán, Sinaloa, Mexico
  • 曾经去过:台北(上一次是近11年前)、北京

Weak AVL Tree

tl;dr: Weak AVL trees are replacements for AVL trees and red-black trees.

The 2014 paper Rank-Balanced Trees (Haeupler, Sen, Tarjan) presents a framework using ranks and rank differences to define binary search trees.

  • Each node has a non-negative integer rank r(x). Null nodes have rank -1.
  • The rank difference of a node x with parent p(x) is r(p(x)) − r(x).
  • A node is i,j if its children have rank differences i and j (unordered), e.g., a 1,2 node has children with rank differences 1 and 2.
  • A node is called 1-node if its rank difference is 1.

Several balanced trees fit this framework:

  • AVL tree: Ranks are defined as heights. Every node is 1,1 or 1,2 (rank differences of children)
  • Red-Black tree: All rank differences are 0 or 1, and no parent of a 0-child is a 0-child. (red: 0-child; black: 1-child; null nodes are black)
  • Weak AVL tree (new tree described by this paper): All rank differences are 1 or 2, and every leaf has rank 0.
    • A weak AVL tree without 2,2 nodes is an AVL tree.
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AVL trees ⫋ weak AVL trees ⫋ red-black trees

Weak AVL Tree

Weak AVL trees are replacements for AVL trees and red-black trees. A single insertion or deletion operation requires at most two rotations (forming a double rotation when two are needed). In contrast, AVL deletion requires O(log n) rotations, and red-black deletion requires up to three.

Without deletions, a weak AVL tree is exactly an AVL tree. With deletions, its height remains at most that of an AVL tree with the same number of insertions but no deletions.

The rank rules imply:

  • Null nodes have rank -1, leaves have rank 0, unary nodes have rank 1.

Insertion

The new node x has a rank of 0, changed from the null node of rank -1. There are three cases.

  • If the tree was previously empty, the new node becomes the root.
  • If the parent of the new node was previously a unary node (1,2 node), it is now a 1,1 binary node.
  • If the parent of the new node was previously a leaf (1,1 node), it is now a 0,1 binary node, leading to a rank violation.

When the tree was previously non-empty, x has a parent node. We call the following subroutine with x indicating the new node to handle the second and third cases.

The following subroutine handles the rank increase of x. We call break if there is no more rank violation, i.e. we are done.

The 2014 paper isn't very clear about the conditions.

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// Assume that x's rank has just increased by 1 and rank_diff(x) has been updated.

p = x->parent;
if (rank_diff(x) == 1) {
  // x was previously a 2-child before increasing x->rank.
  // Done.
} else {
  for (;;) {
    // Otherwise, p is a 0,1 node (previously a 1,1 node before increasing x->rank).
    // x being a 0-child is a violation.

    Promote p.
    // Since we have promoted both x and p, it's as if rank_diff(x's sibling) is flipped.
    // p is now a 1,2 node.

    x = p;
    p = p->parent;
    // x is a 1,2 node.
    if (!p) break;
    d = p->ch[1] == x;

    if (rank_diff(x) == 1) { break; }
    // Otherwise, x is a 0-child, leading to a new rank violation.

    auto sib = p->ch[!d];
    if (rank_diff(sib) == 2) { // p is a 0,2 node
      auto y = x->ch[d^1];
      if (y && rank_diff(y) == 1) {
        // y is a 1-child. y must the previous `x` in the last iteration.
        Perform a double rotation involving `p`, `x`, and `y`.
      } else {
        // Otherwise, y is null or a 2-child.
        Perform a single rotation involving `p` and `x`.
        x is now a 1,1 node and there is no more violation.
      }
      break;
    }

    // Otherwise, p is a 0,1 node. Goto the next iteration.
  }
}

Insertion never introduces a 2,2 node, so insertion-only sequences produce AVL trees.

Deletion

TODO: Describe deletion

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if (!was_2 && !x && !p->ch[0] && !p->ch[1] && p->rp()) {
  // p was unary and becomes 2,2. Demote it.
}

Implementation

Since valid rank differences can only be 1 or 2, ranks can be encoded efficiently using bit flags. There are three approaches:

  • Store two bits representing the rank differences to each child. Bit 0: rank difference to left child (1 = diff is 2, 0 = diff is 1). Bit 1: rank difference to right child
  • Store a single bit representing the parity (even/odd) of the node's absolute rank. The rank difference to a child is computed by comparing parities. Same parity → rank difference of 2. Different parity → rank difference of 1
  • Store a 1-bit rank difference parity in each node.

FreeBSD's sys/tree.h (https://reviews.freebsd.org/D25480, 2020) uses the first approach. The rb_ prefix remains as it can also indicate Rank-Balanced:) Note: its insertion operation can be futher optimized as the following code demonstrates.

https://github.com/pvachon/wavl_tree and https://crates.io/crates/wavltree use the second approach.

The third approach is less efficient because a null node can be either a 1-child (parent is binary) or a 2-child (parent is unary), requiring the sibling node to be probed to determine the rank difference: int rank_diff(Node *p, int d) { return p->ch[d] ? p->ch[d]->par_and_flg & 1 : p->ch[!d] ? 2 : 1; }

https://maskray.me/blog/2025-12-14-weak-avl-tree is a C++ implementation covering both approaches, supporting the following operations:

  • insert: insert a node
  • remove: remove a node
  • rank: count elements less than a key
  • select: find the k-th smallest element (0-indexed)
  • prev: find the largest element less than a key
  • next: find the smallest element greater than a key

Node structure:

  • ch[2]: left and right child pointers.
  • par_and_flg: packs the parent pointer with 2 flag bits in the low bits. Bit 0 indicates whether the left child has rank difference 2; bit 1 indicates whether the right child has rank difference 2. A cleared bit means rank difference 1.
  • i: the key value.
  • sum, size: augmented data maintained by mconcat for order statistics operations.

Helper methods:

  • rd2(d): returns true if child d has rank difference 2.
  • flip(d): toggles the rank difference of child d between 1 and 2.
  • clr_flags(): sets both children to rank difference 1 (used after rotations to reset a node to 1,1).

Invariants:

  • Leaves always have flags() == 0, meaning both null children are 1-children (null nodes have rank -1, leaf has rank 0).
  • After each insertion or deletion, mconcat is called along the path to the root to update augmented data.

Rotations:

The rotate(x, d) function rotates node x in direction d. It lifts x->ch[d] to replace x, and updates the augmented data for x. The caller is responsible for updating rank differences.

Misc

Visualization: https://tjkendev.github.io/bst-visualization/avl-tree/bu-weak.html

Stack walking: space and time trade-offs

On most Linux platforms (except AArch32, which uses .ARM.exidx), DWARF .eh_frame is required for C++ exception handling and stack unwinding to restore callee-saved registers. While .eh_frame can be used for call trace recording, it is often criticized for its runtime overhead. As an alternative, developers can enable frame pointers, or adopt SFrame, a newer format designed specifically for profiling. This article examines the size overhead of enabling non-DWARF stack walking mechanisms when building several LLVM executables.

Runtime performance analysis will be added in a future update.

Read More