Use mimalloc for Ladybird-owned allocations without overriding malloc().
Route kmalloc(), kcalloc(), krealloc(), and kfree() through mimalloc,
and put the embedded Rust crates on the same allocator via a shared
shim in AK/kmalloc.cpp.
This also lets us drop kfree_sized(), since it no longer used its size
argument. StringData, Utf16StringData, JS object storage, Rust error
strings, and the CoreAudio playback helpers can all free their AK-backed
storage with plain kfree().
Sanitizer builds still use the system allocator. LeakSanitizer does not
reliably trace references stored in mimalloc-managed AK containers, so
static caches and other long-lived roots can look leaked. Pass the old
size into the Rust realloc shim so aligned fallback reallocations can
move posix_memalign-backed blocks safely.
Static builds still need a little linker help. macOS app binaries need
the Rust allocator entry points forced in from liblagom-ak.a, while
static ELF links can pull in identical allocator shim definitions from
multiple Rust staticlibs. Keep the Apple -u flags and allow those
duplicate shim symbols for LibJS and LibRegex links on Linux and BSD.
Teach import_rust_crate() to track RustFFI.h as a real build output,
and teach the relevant Rust build scripts to rerun when their FFI
inputs change.
Also keep a copy of RustFFI.h in Cargo's own OUT_DIR and restore the
configured FFI output from that cached copy after cargo rustc runs.
This fixes the case where Ninja knows the header is missing, reruns
the custom command, and Cargo exits without rerunning build.rs
because the crate itself is already up to date.
When Cargo leaves multiple hashed build-script outputs behind, pick
the newest root-output before restoring RustFFI.h so we do not copy a
stale header after Rust-side API changes.
Finally, track the remaining Rust-side inputs that could leave build
artifacts stale: LibUnicode and LibJS now rerun build.rs when src/
changes, and the asmintgen rule now depends on Cargo.lock, the
BytecodeDef path dependency, and newly added Rust source files.
Commit 86c8a57794 caused one regression in
test/intl402/DateTimeFormat. It is expected that Intl.DateTimeFormat and
Temporal produce consistent results.
Due to the píngqì approximation implemented in icu4x, it actually does
not totally align with icu4c for lunisolar calendars at extreme dates.
Ideally, icu4x will one day support all Intl.DateTimeFormat operations
as well. But for now, the fix is to create a custom icu::Calendar class
for lunisolar calendars that pipes calculations to icu4x.
There will be an extremely similar function that accepts a calendar year
rather than ISO year in a subsequent commit. Rename the ISO year variant
so that they are more distinguishable.
Replace the icu4c-based calendar implementation with one built on the
icu4x Rust crate (icu_calendar).
The icu4c API does not expose the píngqì month-assignment algorithm
used by the Chinese and Dangi lunisolar calendars. Our old code had to
approximate this by walking months via epoch millisecond arithmetic and
manually tracking leap month positions, which produced incorrect month
codes and ordinal month numbers for certain years. The icu4x calendar
crate handles píngqì natively.
With this patch, which is almost a 1-to-1 mapping of ICU invocations, we
pass 100% of all Temporal test262 tests.
The end goal might be to use icu4x for all of our ICU needs. But it does
not yet provide the APIs needed for all ECMA-402 prototypes.
