...mostly.
This creates and uses an override for the `serenity_test()` function, so
that Lagom can make use of the existing `Tests/LibFoo/CMakeLists.txt`
files instead of having to GLOB for test source files and manually copy
any data files.
Some GLOBs remain but this is most of them.
Co-authored-by: Andrew Kaster <akaster@serenityos.org>
Let's put test files with the tests themselves, instead of a random user
directory. (But still copy them so they appear in the user directory
for convenience.)
Putting the LibTTF tests into the LibGfx directory worked fine before,
but causes issues if we try and call this from Lagom. Also, it's tidier
to put LibTTF tests in a LibTTF directory. :^)
The macOS FileWatcher depends on macOS dispatch queues, which run on a
different thread than the Core::EventLoop. This implementation handles
filesystem events on its dispatch queue, then forwards the event back to
the main Core::EventLoop for notifying the FileWatcher owner.
The test currently watches /tmp, which the OS can create/modify files
under at any time outside of our control. So just ignore events that we
aren't interested in.
Also test removing an item from the FileWatcher.
This will be handy for platforms which need to be able to store extra
OS-specific members. For example, macOS needs to store a dispatch queue,
and event stream, etc.
This does not need to be defined in Format.h. This causes FixedPoint.h
to be included everywhere. This is particularly going to be an issue
when trying to include <CoreServices/CoreServices.h> on macOS. The macOS
SDK defines its own FixedPoint structure which will conflict with ours.
These are currently being implicitly including by FixedPoint.h by way of
Format.h. The former will soon be removed from the latter, which would
otherwise cause a compile error in these files.
A negative return value doesn't make sense for any of those functions.
The return types were inherited from POSIX, where they also need to have
an indicator for an error (negative values).
This includes:
- Moving it from Bindings/ to HTML/
- Renaming it from LocationObject to Location
- Removing the manual definitions of the constructor and prototype
- Removing special handling of the Location interface from the bindings
generator
- Converting the JS_DEFINE_NATIVE_FUNCTIONs to regular functions
returning DeprecatedString instead of PrimitiveString
- Adding missing (no-op) setters for the various attributes, which are
expected to exist by the bindings generator
Following registers accessors are updated and put in use:
* ID_AA64ISAR0_EL1, Instruction Set Attribute Register 0
Accessors for following registers are added and put in use:
* ID_AA64ISAR1_EL1, Instruction Set Attribute Register 1
* ID_AA64ISAR2_EL1, Instruction Set Attribute Register 2
* ID_AA64MMFR1_EL1, AArch64 Memory Model Feature Register 1
* ID_AA64MMFR2_EL1, AArch64 Memory Model Feature Register 2
* ID_AA64MMFR3_EL1, AArch64 Memory Model Feature Register 3
* ID_AA64MMFR4_EL1, AArch64 Memory Model Feature Register 4
* ID_AA64PFR0_EL1, AArch64 Processor Feature Register 0
* ID_AA64PFR1_EL1, AArch64 Processor Feature Register 1
* ID_AA64PFR2_EL1, AArch64 Processor Feature Register 2
* ID_AA64ZFR0_EL1, AArch64 SVE Feature ID register 0
* ID_AA64SMFR0_EL1, AArch64 SME Feature ID register 0
* ID_AA64DFR0_EL1, AArch64 Debug Feature Register 0
* ID_AA64DFR1_EL1, AArch64 Debug Feature Register 1
Additionally, there are few CPU features detected with
* TCR_EL1, Translation Control Register
but detection mechanism using it (for LPA/LPA2) is probably wrong as
this is control register, not a id register, and needs further work.
Finally, following registers are provided. Former one is already used,
while latter is given for future use:
* MIDR_EL1, Main ID Register
* AIDR_EL1, Auxiliary ID Register
Settled for `cpu_feature_to_name` as that naming is more descriptive
and similarly named `cpu_feature_to_description` function will be
provided for Aarch64.
Because TGA images don't have magic bytes as a signature to be detected,
instead assume a sequence of ReadonlyBytes is a possible TGA image only
if we are given a path so we could check the extension of the file and
see if it's a TGA image.
When we know the path of the file being loaded, we will try to first
check its extension, and only if there's no match to a known decoder,
based on simple extension lookup, then we would probe for other formats
as usual with the normal sniffing method.
We weren't properly creating a `LoadRequest` which resulted in `m_page`
not having a value in certain situations inside
`ResourceLoader::load(LoadRequest&)`
The Unicode spec defines much more complicated caseless matching
algorithms in its Collation spec. This implements the "basic" case
folding comparison.