Other than what action they send back to
EmulationActivity.handleMenuAction(), they are the same.
Change the menu-handling logic in EmulationActivity to keep track of a
boolean for whether the submenu is visible, rather than keeping the
fragment tag. There's only one fragment visible, so this makes more
sense.
Some toolchains provide enough of C++17 to conflict with Dolphin's
included backport of std::variant and std::optional. Specifically,
the recently-released macOS 10.13 SDK does not provide the <optional>
or <variant> headers, but does provide `in_place_t` in the <utility>
header.
The newer title dumpers don't clobber tickets anymore (that's good!),
which means personalised tickets still have the console specific data
used to decrypt the title key in them. Dolphin should ignore that data
when importing WADs, because the title key has already been decrypted,
and we must not try to decrypt it *again*.
Prefixing everything with a constant packagename is not needed for
internal keys, and just adds complexity.
Rename ARGUMENT_ prefix to ARG_ to match (most) of the rest of the
codebase.
Restrict visiblity of above as much as possible.
Makes the toolbar look more comfortable instead of all squished
together, and more similar to our current look.
Instead of setting a hardcoded minimal size for buttons, MakeActions()
now uses the maximum size hint width.
* remove useless units after 'zero' values
* reduce the size of 'Dolphin' to be more reasonable and look better
* avoid hardcoding the normal and small font sizes
Just create the AboutDialog on the stack -- the actual object lives on
the heap anyway, since Qt uses the pimpl idiom. Removes the need for
an explicit new and a special delete on close attribute.
FRAGMENT_ID wasn't actually the fragment's ID (that's misleading, and
sounds like the tag). It's actually the layout resource ID. There's no point in making that a static constant.
EmulationStateChanged is functionally correct right now, but
ConfigChanged expresses more semantically why the config setting gets
re-read and the widgets updated.
There are two special cases that the DSP accelerator handles in a
special way: when the end address is of the form xxxxxxx0 or
xxxxxxx1.
For these two cases, the normal overflow handling doesn't apply.
Instead, the overflow check is different, the ACCOV exception never
fires at all, the predscale register is not updated, reads are not
suspended, and if the end address is 16-byte aligned, the DSP loops
back to start_address + 1 instead of the regular start_address.
When an ACCOV is triggered, the accelerator stops reading back anything
and updating the current address until the YN2 register is set.
This is kept track of internally by the DSP; this state is not exposed
via any register.
However, we need to emulate this behaviour correctly because some
ucodes rely on it (notably AX GC); failure to emulate it will result
in reading past the end and start address for non-looped voices.
When the current address is xxxxxxxf, after doing the standard ADPCM
decoding and incrementing the current address as usual to get the
next address, the DSP will update the predscale register by reading
2 bytes from memory, and add two to get the next address.
This means xxxxxx10 cannot be a current address, as the DSP goes
from 0f to 12 directly.
A more serious issue with the old code is that if the start address
is 16-byte aligned, some samples will always be skipped, even when
that should not be the case.
An easy way to test whether this behaviour is correct is to check
the current address register and the predscale after each read.
Old code:
...
ACCA=00000002, predscale=<value>
ACCA=00000003, predscale=<value>
...
ACCA=0000000f, predscale=<value>
ACCA=00000010, predscale=<another value>
ACCA=00000013, predscale=<another value>
ACCA=00000014, predscale=<another value>
...
New code (and console):
...
ACCA=00000002, predscale=<value>
ACCA=00000003, predscale=<value>
...
ACCA=0000000f, predscale=<value>
ACCA=00000012, predscale=<another value>
ACCA=00000013, predscale=<another value>
...
Slightly cleaner, allows DSP accelerator behaviour to be
added to both HLE and LLE pretty easily, and makes the accelerator
easier to unit test.
I chose to include all accelerator state as private members, and
to expose state that is accessible via registers with getters/setters.
It's more verbose, yes, but it makes it very clear what is part of
the accelerator state and what isn't (e.g. coefs).
This works quite well for registers, since the accelerator can do
whatever it wants internally. For example, the start/end/current
addresses are masked -- having a getter/setter makes it easier to
enforce the mask.
This adds a test ucode that can be used to check the accelerator loop
behaviour with various start/end addresses.
It's actually more of a test template than a ready to use test.