Most cases where the pointer is stored into an already-declared variable can
trivially be changed to MakeNotNull<T*>, as the NotNull raw pointer will end
up in a smart pointer.
In RAII cases, the target type can be specified (e.g.:
`MakeNotNull<RefPtr<imgFrame>>)`), in which case the variable type may just be
`auto`, similar to the common use of MakeUnique.
Except when the target type is a base pointer, in which case it must be
specified in the declaration.
MozReview-Commit-ID: BYaSsvMhiDi
--HG--
extra : rebase_source : 8fe6f2aeaff5f515b7af2276c439004fa3a1f3ab
This patch:
- adds fails-if annotations for all the reftests that were consistently failing
with layers-free turned on.
- removes fails-if or reduces the range on fuzzy-if annotations for all
the reftests that were producing UNEXPECTED-PASS results with
layers-free turned on.
- adds skip-if, random-if, or fuzzy-if annotations to the reftests that
were intermittently failing due to timeout, obvious incorrectness, or
slight pixel differences, respectively.
MozReview-Commit-ID: A0Aknn6rnjj
--HG--
extra : rebase_source : 420d9cf43f23a5d654fa36eec69138937d13c173
A default constructed SurfacePipe contains a NullSurfaceSink as its
filter in mHead. This filter does nothing and is merely a placeholder.
Since most SurfacePipe objects are constructed with the default
constructor, and NullSurfaceSink has no (modified) state, we use a
singleton to represent it. Normally the SurfacePipe owns its filter, so
it needs to do a special check for NullSurfaceSink to ensure it doesn't
free it explicitly.
A Decoder object contains a default constructed SurfacePipe until it
needs to create the first frame from an image. This is a very brief
window because it does not take very long or much data to get to this
stage of decoding.
The NullSurfaceSink singleton is freed upon shutdown, however some
ISurfaceProvider objects may be lingering after this. If their Decoder
has yet to create the first frame, that means the SurfacePipe actually
contains a dangling pointer to the already freed singleton. To make
things worse, it actually tried to free the filter because it didn't
match the singleton (it got freed!).
As such, this change removes NullSurfaceSink entirely. We never use the
SurfacePipe before initializing it with a proper filter, and it would be
considered a programming error to do so. Instead let SurfacePipe::mHead
be null, and assert that it is not null when any operations are
performed on the SurfacePipe.
This mechanically replaces nsILocalFile with nsIFile in
*.js, *.jsm, *.sjs, *.html, *.xul, *.xml, and *.py.
MozReview-Commit-ID: 4ecl3RZhOwC
--HG--
extra : rebase_source : 412880ea27766118c38498d021331a3df6bccc70
Currently SourceBuffer::ExpectLength will allocate a buffer which is a
multiple of MIN_CHUNK_CAPACITY (4096) bytes, no matter what the expected
size is. While it is true that HTTP servers can lie, and that we need to
handle that for legacy purposes, it is more likely the HTTP servers are
telling the truth when it comes to the content length. Additionally
images sourced from other locations, such as the file system or data
URIs, are always going to have the correct size information (barring a
bug elsewhere in the file system or our code). We should be able to
trust the size given as a good first guess.
While overallocating in general is a waste of memory,
SourceBuffer::Compact causes a far worse problem. After we have written
all of the data, and there are no active readers, we attempt to shrink
the allocated buffer(s) into a single contiguous chunk of the exact
length that we need (e.g. N allocations to 1, or 1 oversized allocation
to 1 perfect). Since we almost always overallocate, that means we almost
always trigger the logic in SourceBuffer::Compact to reallocate the data
into a properly sized buffer. If we had simply trusted the expected size
in the first place, we could have avoided this situation for the
majority of images.
In the case that we really do get the wrong size, then we will allocate
additional chunks which are multiples of MIN_CHUNK_CAPACITY bytes to fit
the data. At most, this will increase the number of discrete allocations
by 1, and trigger SourceBuffer::Compact to consolidate at the end. Since
we are almost always doing that before, and now we rarely do, this is a
significant win.
Thus far gtests have only tested fairly simple images which already
render the same on all platforms (e.g. solid green 100x100 square).
If we want to test more complicated images consistently across
platforms, we need to ensure the color adjustments we perform are
also consistent. Using the pref gfx.color_management.force_srgb to
force an sRGB CMS profile makes us consistent with the reftests and
mochitests.
However an additional quirk of the gtests is that we own the main
thread and we never check our event queue to see if anything is
pending. Depending on the initialization order of our graphics
dependencies, it may or may not have created pending runnables to
process the pref change. As such, we need to change the pref,
initialize imagelib/gfx and then check for, and if present execute,
any necessary runnables. Only then can we be sure that our desired
CMS profile is applied.
We do this to avoid having one of the image loads happen before the cache entry for the image times out and the other image load after the cache entry times out.
--HG--
rename : image/test/mochitest/damon.jpg => image/test/mochitest/bug1217571.jpg