tl;dr This blog post describes a recent
SmallVector::push_back optimization for approximately
trivially copyable element types.
SmallVector is LLVM's most-used container, and
push_back its hot operation. For the trivially-copyable
specialization the fast path should be fast.
1 |
|
clang -S --target=x86_64 -O2 -DNDEBUG a.cc
generates:
1 | push rbp # callee-saved spills + a stack realignment, |
LLVM has several hash tables. They used quadratic probing with in-band sentinel keys (empty, tombstone); recent work has been replacing that with linear probing with tombstone key removed.
DenseMap (replacement for
std::unordered_map):
DenseMapInfo::getEmptyKey() /
getTombstoneKey().
DenseSet: implemented using DenseMapcompiler-rt/lib/sanitizer_common/sanitizer_dense_map.h
ports the implementation for sanitizers.SmallPtrSet (replacement for
std::unordered_set<T *>): hard-coded -1
(empty) and -2 (tombstone).StringMap (replacement for
std::unordered_map<std::string, V>)
StringSet: implemented using
StringMapFor the open-addressed DenseMap and
SmallPtrSet, pointers, references, and iterators are
invalidated by insert. StringMap is different: each entry
lives in a heap-allocated StringMapEntry<V> node, so
entry pointers survive grow. std::unordered_map, being
node-based, keeps surviving-element pointers valid across both insert
and erase and only invalidates the erased element's own iterator. LLVM
code rarely needs that stronger contract — callers do not hold
long-lived references into the container across mutation — and that gap
is what gives pass to relocating erase and bit-array occupancy.
Recently,
erase() also invalidates pointers.int/unsigned/size_t) had
-1/-2 reserved — a footgun, now fixed.remove_if.With a sufficient number of users of an API, it does not matter what you promise in the contract: all observable behaviors of your system will be depended on by somebody. — Hyrum's Law
In a compiler, the most common form of Hyrum's Law is dependence on
unspecified behavior — hash bucket order, the order of equal
elements after std::sort, padding offsets. The same framing
covers a few cases that are technically undefined behavior (use of an
invalidated iterator) or plain incidental properties (ABI struct layout,
ELF section offsets).
When the compiler itself harbors such a dependency, the symptom is
usually output that varies build-to-build: an unstable sort that lands
differently after the standard library changes, a hash map whose
iteration order shifts when the hash function does. Occasionally the
variation is run-to-run within a single build —
DenseMap<void *, X> keys with an ASLR-derived seed
reorder buckets each invocation. Either way, reproducible builds,
bisection, and bug reports all assume same input → same output, and a
stealth Hyrum dependency breaks that.
This post surveys some mechanisms that perturb the contract's blind spots so dependencies cannot quietly form.
Updated in 2026-05.
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
1.34x as fast as lld 22.1; Chromium debug with --gdb-index
is 1.09x as fast. mold and wild are still ahead — the last section
explains why.
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.
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:
1 | # i386, x86-64 |
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.
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.
I've created pr-shadow with vibe coding, a tool that maintains a shadow branch for GitHub pull requests (PR) that never requires force-pushing. This addresses pain points I described in Reflections on LLVM's switch to GitHub pull requests#Patch evolution.
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。
不包括这篇总结,一共写了18篇文章。
翻新了integrated assembler,写了4篇相关的blog posts: https://maskray.me/blog/tags/assembler/
Reviewed
numerous patches. query
is:pr created:>2025-01-01 reviewed-by:MaskRay => "989
Closed"
贡献了两个commits,被引用了一次。
clang.prependArgs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。
Reported 6 feature requests or bugs to binutils.
ld --build-id does not use symtab/strtab contentgas: monolithic .sframe violates COMDAT group rulegas: Clarify whitespace between a label's symbol and its colonld: Add --print-gc-sections=fileld riscv: Relocatable linking challenge with R_RISCV_ALIGNld: add --why-live