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708e7706f3
Now it's up to 99% tests passing, 15362 are still failing, but many of those are the unimplemented IN/OUT instructions, which the Genesis doesn't seem to use
109 lines
4.8 KiB
Plaintext
109 lines
4.8 KiB
Plaintext
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2021/10/21:
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Frontend/Backend Interface
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--------------------------
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- need a way for the frontend window to be updated with graphics data from a backend device
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- also need access to input key and joystick presses; other interfaces can be used for audio, etc
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- it would be nice if it was possible to have multiple video output devices in a system
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outputting to different windows (ie. one window per video device)
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- either the frontend calls a function in the backend to update the window, or the backend
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calls an indirect function on the frontend to update the window
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- Frontend calling backend:
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- Opt 1 - supply a callback and object separately, pass object to callback (no closure)
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- older way but should work
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- object needs to be Arc in order to share, but doesn't need to be wrapped in a tuple struct
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- con: if object is device itself, would still need to use tuple struct wrapper for Addressable
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- Opt 2 - supply a trait object with an update method
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- frontend would store a Box<dyn Window>
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- device would have to make a wrapper: `struct WindowWrapper(Arc<ActualDevice>)` and
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impl Window on WindowWrapper, and `struct DeviceWrapper(Arc<ActualDevice>)` and impl
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Addressable/Steppable on DeviceWrapper
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- pro: in-sync on-demand rendering
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- con: lots of complications and indirection
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- Opt 3 - supply a common object that devices can update, and that then updates the window
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- backend would define a Frame type object which would contain a rendered frame
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- system thread would render to the Frame, ui thread would then copy the Frame to window
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- con: lots of copying of pixel data
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- con: out of sync rendering
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- pro: ui can handle any scaling
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- Backend calling frontend:
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- Opt 4 - host can produce a generic window object that satisfies Window trait
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- the device struct which needs the window would have a type parameter for the window
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object, and the system thread (step) would call an update function on the generic
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window to copy the rendered frame to a ui buffer, which then copies again on ui thread
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- window object can only have a buffer, but it can use a native format rather than internal format
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- con: out of sync rendering
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- Opt 5 - host can produce a Window trait object
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- the device would just store the trait object so no need for a type param
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- the frontend can't put the native window in the window object so it would need to be a buffer
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- con: would need a wrapper if the frontend needs internal access to the common device
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- this is
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- Opt 3, 4, and 5 would all involve an intermediate buffer, but with Opt 4 or 5, that buffer can be native-compatible
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- Opt 3, 4, and 5 are out of sync updating
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- Opt 1 and 2 can be in-sync updating if the device object is supplied, but not if it uses an intermediate buffer
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- it seems like Opt 4 isn't working because you can't make an existential generic (can't return MiniWindow as W: Window)
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- it seems Opt 5 works, but is trying to update the screen waaay too much, and causing the sim to almost never move.
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Even with a simple count limit, it seems to pause when it tries updating the screen, probably due to lock contention
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- Opt 1 is misleading because you still need a shared object, and it can't be a generic, so it's either a backend-specific
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struct or a dyn trait object, so really it's the same as Opt 2, or Opt 3
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- it might be possible to have a common data struct that contains 2 frames, one that can only be updated by the sim, and one
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that can only be read by in-sync update function, and they are swapped on update (if the writable one isn't locked), so
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that the updating is still in sync in the ui thread, but the rendering is happening in another thread
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2021/12/07:
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Signals, Etc.
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-------------
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* think more about what kinds of signals are used:
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- one setter with one or more passive listeners (bank_register, updated by writing to and used whenever a value is read)
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- one or more setters and one listeners (reset, bus_request for the CPUs)
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- one one-shot setter (no reset) with one active listener that resets the signal (certain interrupts, including a vsync interrupt)
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- what about interrupt controller?
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2023/05/22:
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Refactoring Execution of m68k
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-----------------------------
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* would it be possible to construct something that behaves more like the microcode executor using steps in chained form,
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with side effects and quirks and flags (and exceptions) handled as such
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```
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// ADD
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executor.start()
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.fetch_src(src)
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.fetch_dest(dest)
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.add()
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.write_dest(dest)
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.set_flags("XCNVS")
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.finish()?;
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// BRA
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executor.start()
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.branch_offset(offset)
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.finish()?;
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// JMP
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executor.start()
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.fetch_src(target)
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.branch_absolute()
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.finish()?;
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```
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