LLVM 19 will be released. As usual, I maintain lld/ELF and have added some notes to https://github.com/llvm/llvm-project/blob/release/19.x/lld/docs/ReleaseNotes.rst. I've meticulously reviewed nearly all the patches that are not authored by me. I'll delve into some of the key changes.

• EI_OSABI in the output is now inferred from input object files. (#97144)
• --compress-sections <section-glib>={none,zlib,zstd}[:level] is added to compress matched output sections without the SHF_ALLOC flag. (#84855) (#90567)
• The default compression level for zlib is now independent of linker optimization level (Z_BEST_SPEED).
• zstd compression parallelism no longer requires ZSTD_MULITHREAD build.
• GNU_PROPERTY_AARCH64_FEATURE_PAUTH notes, R_AARCH64_AUTH_ABS64 and R_AARCH64_AUTH_RELATIVE relocations are now supported. (#72714)
• --no-allow-shlib-undefined now rejects non-exported definitions in the def-hidden.so ref.so case. (#86777)
• --debug-names is added to create a merged .debug_names index from input .debug_names sections. Type units are not handled yet. (#86508)
• --enable-non-contiguous-regions option allows automatically packing input sections into memory regions by automatically spilling to later matches if a region would overflow. This reduces the toil of manually packing regions (typical for embedded). It also makes full LTO feasible in such cases, since IR merging currently prevents the linker script from referring to input files. (#90007)
• --default-script/-dT is implemented to specify a default script that is processed if --script/-T is not specified. (#89327)
• --force-group-allocation is implemented to discard SHT_GROUP sections and combine relocation sections if their relocated section group members are placed to the same output section. (#94704)
• --build-id now defaults to generating a 20-byte digest ("sha1") instead of 8-byte ("fast"). This improves compatibility with RPM packaging tools. (#93943)
• -z lrodata-after-bss is implemented to place .lrodata after .bss. (#81224)
• --export-dynamic no longer creates dynamic sections for -no-pie static linking.
• --lto-emit-asm is now added as the canonical spelling of --plugin-opt=emit-llvm.
• --lto-emit-llvm now uses the pre-codegen module. (#97480)
• When AArch64 PAuth is enabled, -z pack-relative-relocs now encodes R_AARCH64_AUTH_RELATIVE relocations in .rela.auth.dyn. (#96496)
• -z gcs and -z gcs-report are now supported for AArch64 Guarded Control Stack extension.
• -r now forces -Bstatic.
• Thumb2 PLT is now supported for Cortex-M processors. (#93644)
• DW_EH_sdata4 of addresses larger than 0x80000000 is now supported for MIPS32. (#92438)
• Certain unknown section types are rejected. (#85173)
• PROVIDE(lhs = rhs) PROVIDE(rhs = ...), lhs is now defined only if rhs is needed. (#74771) (#87530)
• OUTPUT_FORMAT(binary) is now supported. (#98837)
• NOCROSSREFS and NOCRFOSSREFS_TO commands now supported to prohibit cross references between certain output sections. (#98773)
• Orphan placement is refined to prefer the last similar section when its rank <= orphan's rank. (#94099) Non-alloc orphan sections are now placed at the end. (#94519)
• R_X86_64_REX_GOTPCRELX of the addq form is no longer incorrectly optimized when the address is larger than 0x80000000.

--compress-sections

The --compress-sections option has been enhanced. You can choose between zlib and zstd for compression, along with specifying the desired compression level. Looking ahead, zlib is deprecated in favor of zstd. While zstd offers additional tuning options, we only provide the compression level.

My Compressed arbitrary sections has analyzed potential use cases.

Orphan sections

My Understanding orphan sections explains the changes in detail.

Linker scripts

There are quite a few enhancements to the linker script support. NOCROSSREFS and --enable-non-contiguous-regions are noteworthy new features. There is now an increasing demand of features for embedded programming.

The world of embedded programming is a fascinating mix of open and closed ecosystems. Developers of proprietary hardware and closed-source software are increasingly interested in migrating their toolchains to the LLVM Linker (LLD). The allure of faster link speeds, a clean codebase, and seamless LTO integration is undeniable. However, as LLD's maintainer, I must tread carefully. While accommodating these users is nice for LLD's growth, incorporating custom linker extensions risks compromising the project's code quality and maintainability. Striking the right balance between flexibility and code integrity is essential to ensure LLD remains a robust and efficient linker for a wide range of users.

GNU ld also supports extensions for embedded programming. I categorize these extensions into two groups: mature and experimental. Many of the established extensions exhibit well-defined semantics and have been incorporated into LLD. However, some newer extensions in GNU ld appear less thoughtfully designed and inflexible.

When considering a specific extension, we should prioritize practical needs over arbitrary adherence to GNU ld's implementation. If compelling reasons justify a particular feature and GNU ld's approach proves restrictive, we should feel empowered to innovate within LLD.

Conversely, when developing new extensions, it's essential to engage with the broader community. I often submit feature requests to GNU ld to inform decisions we are going to make. I believe this collaborative approach fosters knowledge sharing.

CREL

I've developed CREL (compact relocations) to reduce relocatable file tremendously for LLVM 19. LLD now supports CREL with explicit addends. See Integrated assembler improvements in LLVM 19 for details.

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Link: lld 18 ELF changes