bsnes/higan/ws/system/system.cpp

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3.3 KiB
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#include <ws/ws.hpp>
namespace WonderSwan {
System system;
Scheduler scheduler;
Cheat cheat;
#include "io.cpp"
Update to v098r04 release. byuu says: Changelog: - SFC: fixed behavior of 21fx $21fe register when no device is connected (must return zero) - SFC: reduced 21fx buffer size to 1024 bytes in both directions to mirror the FT232H we are using - SFC: eliminated dsp/modulo-array.hpp [1] - higan: implemented higan/video interface and migrated all cores to it [2] [1] the echo history buffer was 8-bytes, so there was no need for it at all here. Not sure what I was thinking. The BRR buffer was 12-bytes, and has very weird behavior ... but there's only a single location in the code where it actually writes to this buffer. It's much easier to just write to the buffer three times there instead of implementing an entire class just to abstract away two lines of code. This change actually boosted the speed from ~124.5fps to around ~127.5fps, but that's within the margin of error for GCC. I doubt it's actually faster this way. The DSP core could really use a ton of work. It comes from a port of blargg's spc_dsp to my coding style, but he was extremely fond of using 32-bit signed integers everywhere. There's a lot of opportunity to remove red tape masking by resizing the variables to their actual state sizes. I really need to find where I put spc_dsp6.sfc from blargg. It's a great test to verify if I've made any mistakes in my implementation that would cause regressions. Don't suppose anyone has it? [2] so again, the idea is that higan/audio and higan/video are going to sit between the emulation cores and the user interfaces. The hope is to output raw encoding data from the emulation cores without having to worry about the video display format (generally 24-bit RGB) of the host display. And also to avoid having to repeat myself with eg three separate implementations of interframe blending, and so on. Furthermore, the idea is that the user interface can configure its side of the settings, and the emulation cores can configure their sides. Thus, neither has to worry about the other end. And now we can spin off new user interfaces much easier without having to mess with all of these things. Right now, I've implemented color emulation, interframe blending and SNES horizontal color bleed. I did not implement scanlines (and interlace effects for them) yet, but I probably will at some point. Further, for right now, the WonderSwan/Color screen rotation is busted and will only show games in the horizontal orientation. Obviously this must be fixed before the next official release, but I'll want to think about how to implement it. Also, the SNES light gun pointers are missing for now. Things are a bit messy right now as I've gone through several revisions of how to handle these things, so a good house cleaning is in order once everything is feature-complete again. I need to sit down and think through how and where I want to handle things like light gun cursors, LCD icons, and maybe even rasterized text messages. And obviously ... higan/audio is still just nall::DSP's headers. I need to revamp that whole interface. I want to make it quite powerful with a true audio mixer so I can handle things like SNES+SGB+MSU1+Voicer-Kun+SNES-CD (five separate audio streams at once.) The video system has the concept of "effects" for things like color bleed and interframe blending. I want to extend on this with useful other effects, such as NTSC simulation, maybe bringing back my mini-HQ2x filter, etc. I'd also like to restore the saturation/gamma/luma adjustment sliders ... I always liked allowing people to compensate for their displays without having to change settings system-wide. Lastly, I've always wanted to see some audio effects. Although I doubt we'll ever get my dream of CoreAudio-style profiles, I'd like to get some basic equalizer settings and echo/reverb effects in there.
2016-04-11 21:29:56 +00:00
#include "video.cpp"
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
#include "serialization.cpp"
auto System::init() -> void {
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
assert(interface != nullptr);
}
auto System::term() -> void {
}
auto System::load(Emulator::Interface* interface, Model model) -> bool {
_model = model;
if(auto fp = platform->open(ID::System, "manifest.bml", File::Read, File::Required)) {
Update to v099r07 release. byuu says: Changelog: - (hopefully) fixed BS Memory and Sufami Turbo slot loading - ported GB, GBA, WS cores to use nall/vfs - completely removed loadRequest, saveRequest functionality from Emulator::Interface and ui-tomoko - loadRequest(folder) is now load(folder) - save states now use a shared Emulator::SerializerVersion string - whenever this is bumped, all older states will break; but this makes bumping state versions way easier - also, the version string makes it a lot easier to identify compatibility windows for save states - SNES PPU now uses uint16 vram[32768] for memory accesses [hex_usr] NOTE: Super Game Boy loading is currently broken, and I'm not entirely sure how to fix it :/ The file loading handoff was -really- complicated, and so I'm kind of at a loss ... so for now, don't try it. Everything else should theoretically work, so please report any bugs you find. So, this is pretty much it. I'd be very curious to hear feedback from people who objected to the old nall/stream design, whether they are happy with the new file loading system or think it could use further improvements. The 16-bit VRAM turned out to be a wash on performance (roughly the same as before. 1fps slower on Zelda 3, 1fps faster on Yoshi's Island.) The main reason for this was because Yoshi's Island was breaking horribly until I changed the vramRead, vramWrite functions to take uint15 instead of uint16. I suspect the issue is we're using uint16s in some areas now that need to be uint15, and this game is setting the VRAM address to 0x8000+, causing us to go out of bounds on memory accesses. But ... I want to go ahead and do something cute for fun, and just because we can ... and this new interface is so incredibly perfect for it!! I want to support an SNES unit with 128KiB of VRAM. Not out of the box, but as a fun little tweakable thing. The SNES was clearly designed to support that, they just didn't use big enough VRAM chips, and left one of the lines disconnected. So ... let's connect it anyway! In the end, if we design it right, the only code difference should be one area where we mask by 15-bits instead of by 16-bits.
2016-06-24 12:09:30 +00:00
information.manifest = fp->reads();
} else return false;
auto document = BML::unserialize(information.manifest);
//note: IPLROM is currently undumped; otherwise we'd load it here ...
if(auto node = document["system/eeprom"]) {
eeprom.setName(node["name"].text());
eeprom.setSize(node["size"].natural() / sizeof(uint16));
eeprom.erase();
//initialize user-data section
for(uint addr = 0x0030; addr <= 0x003a; addr++) eeprom[addr] = 0x0000;
if(auto fp = platform->open(ID::System, eeprom.name(), File::Read)) {
Update to v099r07 release. byuu says: Changelog: - (hopefully) fixed BS Memory and Sufami Turbo slot loading - ported GB, GBA, WS cores to use nall/vfs - completely removed loadRequest, saveRequest functionality from Emulator::Interface and ui-tomoko - loadRequest(folder) is now load(folder) - save states now use a shared Emulator::SerializerVersion string - whenever this is bumped, all older states will break; but this makes bumping state versions way easier - also, the version string makes it a lot easier to identify compatibility windows for save states - SNES PPU now uses uint16 vram[32768] for memory accesses [hex_usr] NOTE: Super Game Boy loading is currently broken, and I'm not entirely sure how to fix it :/ The file loading handoff was -really- complicated, and so I'm kind of at a loss ... so for now, don't try it. Everything else should theoretically work, so please report any bugs you find. So, this is pretty much it. I'd be very curious to hear feedback from people who objected to the old nall/stream design, whether they are happy with the new file loading system or think it could use further improvements. The 16-bit VRAM turned out to be a wash on performance (roughly the same as before. 1fps slower on Zelda 3, 1fps faster on Yoshi's Island.) The main reason for this was because Yoshi's Island was breaking horribly until I changed the vramRead, vramWrite functions to take uint15 instead of uint16. I suspect the issue is we're using uint16s in some areas now that need to be uint15, and this game is setting the VRAM address to 0x8000+, causing us to go out of bounds on memory accesses. But ... I want to go ahead and do something cute for fun, and just because we can ... and this new interface is so incredibly perfect for it!! I want to support an SNES unit with 128KiB of VRAM. Not out of the box, but as a fun little tweakable thing. The SNES was clearly designed to support that, they just didn't use big enough VRAM chips, and left one of the lines disconnected. So ... let's connect it anyway! In the end, if we design it right, the only code difference should be one area where we mask by 15-bits instead of by 16-bits.
2016-06-24 12:09:30 +00:00
fp->read(eeprom.data(), eeprom.size());
}
}
Update to v099r08 release. byuu says: Changelog: - nall/vfs work 100% completed; even SGB games load now - emulation cores now call load() for the base cartridges as well - updated port/device handling; portmask is gone; device ID bug should be resolved now - SNES controller port 1 multitap option was removed - added support for 128KiB SNES PPU VRAM (for now, edit sfc/ppu/ppu.hpp VRAM::size=0x10000; to enable) Overall, nall/vfs was a huge success!! We've substantially reduced the amount of boilerplate code everywhere, while still allowing (even easier than before) support for RAM-based game loading/saving. All of nall/stream is dead and buried. I am considering removing Emulator::Interface::Medium::id and/or bootable flag. Or at least, doing something different with it. The values for the non-bootable GB/BS/ST entries duplicate the ID that is supposed to be unique. They are for GB/GBC and WS/WSC. Maybe I'll use this as the hardware revision selection ID, and then gut non-bootable options. There's really no reason for that to be there. I think at one point I was using it to generate library tabs for non-bootable systems, but we don't do that anymore anyway. Emulator::Interface::load() may not need the required flag anymore ... it doesn't really do anything right now anyway. I have a few reasons for having the cores load the base cartridge. Most importantly, it is going to enable a special mode for the WonderSwan / WonderSwan Color in the future. If we ever get the IPLROMs dumped ... it's possible to boot these systems with no games inserted to set user profile information and such. There are also other systems that may accept being booted without a cartridge. To reach this state, you would load a game and then cancel the load dialog. Right now, this results in games not loading. The second reason is this prevents nasty crashes when loading fails. So if you're missing a required manifest, the emulator won't die a violent death anymore. It's able to back out at any point. The third reason is consistency: loading the base cartridge works the same as the slot cartridges. The fourth reason is Emulator::Interface::open(uint pathID) values. Before, the GB, SB, GBC modes were IDs 1,2,3 respectively. This complicated things because you had to pass the correct ID. But now instead, Emulator::Interface::load() returns maybe<uint> that is nothing when no game is selected, and a pathID for a valid game. And now open() can take this ID to access this game's folder contents. The downside, which is temporary, is that command-line loading is currently broken. But I do intend on restoring it. In fact, I want to do better than before and allow multi-cart booting from the command-line by specifying the base cartridge and then slot cartridges. The idea should be pretty simple: keep a queue of pending filenames that we fill from the command-line and/or drag-and-drop operations on the main window, and then empty out the queue or prompt for load dialogs from the UI when booting a system. This also might be a bit more unorthodox compared to the traditional emulator design of "loadGame(filename)", but ... oh well. It's easy enough still. The port/device changes are fun. We simplified things quite a bit. The portmask stuff is gone entirely. While ports and devices keep IDs, this is really just sugar-coating so UIs can use for(auto& port : emulator->ports) and access port.id; rather than having to use for(auto n : range(emulator->ports)) { auto& port = emulator->ports[n]; ... }; but they should otherwise generally be identical to the order they appear in their respective ranges. Still, don't rely on that. Input::id is gone. There was no point since we also got rid of the nasty Input::order vector. Since I was in here, I went ahead and caved on the pedantics and renamed Input::guid to Input::userData. I removed the SNES controller port 1 multitap option. Basically, the only game that uses this is N-warp Daisakusen and, no offense to d4s, it's not really a good game anyway. It's just a quick demo to show 8-players on the SNES. But in the UI, all it does is confuse people into wasting time mapping a controller they're never going to use, and they're going to wonder which port to use. If more compelling use cases for 8-players comes about, we can reconsider this. I left all the code to support this in place, so all you have to do is uncomment one line to enable it again. We now have dsnes emulation! :D If you change PPU::VRAM::size to 0x10000 (words), then you should now have 128KiB of VRAM. Even better, it serializes the used-VRAM size, so your save states shouldn't crash on you if you swap between the two (though if you try this, you're nuts.) Note that this option does break commercial software. Yoshi's Island in particular. This game is setting A15 on some PPU register writes, but not on others. The end result of this is things break horribly in-game. Also, this option is causing a very tiny speed hit for obvious reasons with the variable masking value (I'm even using size-1 for now.) Given how niche this is, I may just leave it a compile-time constant to avoid the overhead cost. Otherwise, if we keep the option, then it'll go into Super Famicom.sys/manifest.bml ... I'll flesh that out in the near-future. ---- Finally, some fun for my OCD ... my monitor suddenly cut out on me in the middle of working on this WIP, about six hours in of non-stop work. Had to hit a bunch of ctrl+alt+fN commands (among other things) and trying to log in headless on another TTY to do issue commands, trying to recover the display. Finally power cycled the monitor and it came back up. So all my typing ended up going to who knows where. Usually this sort of thing terrifies me enough that I scrap a WIP and start over to ensure I didn't screw anything up during the crashed screen when hitting keys randomly. Obviously, everything compiles and appears to work fine. And I know it's extremely paranoid, but OCD isn't logical, so ... I'm going to go over every line of the 100KiB r07->r08 diff looking for any corruption/errors/whatever. ---- Review finished. r08 diff review notes: - fc/controller/gamepad/gamepad.cpp: use uint device = ID::Device::Gamepad; not id = ...; - gb/cartridge/cartridge.hpp: remove redundant uint _pathID; (in Information::pathID already) - gb/cartridge/cartridge.hpp: pull sha256 inside Information - sfc/cartridge/load/cpp: add " - Slot (A,B)" to interface->load("Sufami Turbo"); to be more descriptive - sfc/controller/gamepad/gamepad.cpp: use uint device = ID::Device::Gamepad; not id = ...; - sfc/interface/interface.cpp: remove n variable from the Multitap device input generation loop (now unused) - sfc/interface/interface.hpp: put struct Port above struct Device like the other classes - ui-tomoko: cheats.bml is reading from/writing to mediumPaths(0) [system folder instead of game folder] - ui-tomoko: instead of mediumPaths(1) - call emulator->metadataPathID() or something like that
2016-06-24 12:16:53 +00:00
if(!cartridge.load()) return false;
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
serializeInit();
Update to v098r04 release. byuu says: Changelog: - SFC: fixed behavior of 21fx $21fe register when no device is connected (must return zero) - SFC: reduced 21fx buffer size to 1024 bytes in both directions to mirror the FT232H we are using - SFC: eliminated dsp/modulo-array.hpp [1] - higan: implemented higan/video interface and migrated all cores to it [2] [1] the echo history buffer was 8-bytes, so there was no need for it at all here. Not sure what I was thinking. The BRR buffer was 12-bytes, and has very weird behavior ... but there's only a single location in the code where it actually writes to this buffer. It's much easier to just write to the buffer three times there instead of implementing an entire class just to abstract away two lines of code. This change actually boosted the speed from ~124.5fps to around ~127.5fps, but that's within the margin of error for GCC. I doubt it's actually faster this way. The DSP core could really use a ton of work. It comes from a port of blargg's spc_dsp to my coding style, but he was extremely fond of using 32-bit signed integers everywhere. There's a lot of opportunity to remove red tape masking by resizing the variables to their actual state sizes. I really need to find where I put spc_dsp6.sfc from blargg. It's a great test to verify if I've made any mistakes in my implementation that would cause regressions. Don't suppose anyone has it? [2] so again, the idea is that higan/audio and higan/video are going to sit between the emulation cores and the user interfaces. The hope is to output raw encoding data from the emulation cores without having to worry about the video display format (generally 24-bit RGB) of the host display. And also to avoid having to repeat myself with eg three separate implementations of interframe blending, and so on. Furthermore, the idea is that the user interface can configure its side of the settings, and the emulation cores can configure their sides. Thus, neither has to worry about the other end. And now we can spin off new user interfaces much easier without having to mess with all of these things. Right now, I've implemented color emulation, interframe blending and SNES horizontal color bleed. I did not implement scanlines (and interlace effects for them) yet, but I probably will at some point. Further, for right now, the WonderSwan/Color screen rotation is busted and will only show games in the horizontal orientation. Obviously this must be fixed before the next official release, but I'll want to think about how to implement it. Also, the SNES light gun pointers are missing for now. Things are a bit messy right now as I've gone through several revisions of how to handle these things, so a good house cleaning is in order once everything is feature-complete again. I need to sit down and think through how and where I want to handle things like light gun cursors, LCD icons, and maybe even rasterized text messages. And obviously ... higan/audio is still just nall::DSP's headers. I need to revamp that whole interface. I want to make it quite powerful with a true audio mixer so I can handle things like SNES+SGB+MSU1+Voicer-Kun+SNES-CD (five separate audio streams at once.) The video system has the concept of "effects" for things like color bleed and interframe blending. I want to extend on this with useful other effects, such as NTSC simulation, maybe bringing back my mini-HQ2x filter, etc. I'd also like to restore the saturation/gamma/luma adjustment sliders ... I always liked allowing people to compensate for their displays without having to change settings system-wide. Lastly, I've always wanted to see some audio effects. Although I doubt we'll ever get my dream of CoreAudio-style profiles, I'd like to get some basic equalizer settings and echo/reverb effects in there.
2016-04-11 21:29:56 +00:00
_orientation = cartridge.information.orientation;
this->interface = interface;
Update to v099r07 release. byuu says: Changelog: - (hopefully) fixed BS Memory and Sufami Turbo slot loading - ported GB, GBA, WS cores to use nall/vfs - completely removed loadRequest, saveRequest functionality from Emulator::Interface and ui-tomoko - loadRequest(folder) is now load(folder) - save states now use a shared Emulator::SerializerVersion string - whenever this is bumped, all older states will break; but this makes bumping state versions way easier - also, the version string makes it a lot easier to identify compatibility windows for save states - SNES PPU now uses uint16 vram[32768] for memory accesses [hex_usr] NOTE: Super Game Boy loading is currently broken, and I'm not entirely sure how to fix it :/ The file loading handoff was -really- complicated, and so I'm kind of at a loss ... so for now, don't try it. Everything else should theoretically work, so please report any bugs you find. So, this is pretty much it. I'd be very curious to hear feedback from people who objected to the old nall/stream design, whether they are happy with the new file loading system or think it could use further improvements. The 16-bit VRAM turned out to be a wash on performance (roughly the same as before. 1fps slower on Zelda 3, 1fps faster on Yoshi's Island.) The main reason for this was because Yoshi's Island was breaking horribly until I changed the vramRead, vramWrite functions to take uint15 instead of uint16. I suspect the issue is we're using uint16s in some areas now that need to be uint15, and this game is setting the VRAM address to 0x8000+, causing us to go out of bounds on memory accesses. But ... I want to go ahead and do something cute for fun, and just because we can ... and this new interface is so incredibly perfect for it!! I want to support an SNES unit with 128KiB of VRAM. Not out of the box, but as a fun little tweakable thing. The SNES was clearly designed to support that, they just didn't use big enough VRAM chips, and left one of the lines disconnected. So ... let's connect it anyway! In the end, if we design it right, the only code difference should be one area where we mask by 15-bits instead of by 16-bits.
2016-06-24 12:09:30 +00:00
return _loaded = true;
}
auto System::save() -> void {
if(!loaded()) return;
cartridge.save();
Update to v097r12 release. byuu says: Nothing WS-related this time. First, I fixed expansion port device mapping. On first load, it was mapping the expansion port device too late, so it ended up not taking effect. I had to spin out the logic for that into Program::connectDevices(). This was proving to be quite annoying while testing eBoot (SNES-Hook simulation.) Second, I fixed the audio->set(Frequency, Latency) functions to take (uint) parameters from the configuration file, so the weird behavior around changing settings in the audio panel should hopefully be gone now. Third, I rewrote the interface->load,unload functions to call into the (Emulator)::System::load,unload functions. And I have those call out to Cartridge::load,unload. Before, this was inverted, and Cartridge::load() was invoking System::load(), which I felt was kind of backward. The Super Game Boy really didn't like this change, however. And it took me a few hours to power through it. Before, I had the Game Boy core dummying out all the interface->(load,save)Request calls, and having the SNES core make them for it. This is because the folder paths and IDs will be different between the two cores. I've redesigned things so that ICD2's Emulator::Interface overloads loadRequest and saveRequest, and translates the requests into new requests for the SuperFamicom core. This allows the Game Boy code to do its own loading for everything without a bunch of Super Game Boy special casing, and without any awkwardness around powering on with no cartridge inserted. This also lets the SNES side of things simply call into higher-level GameBoy::interface->load,save(id, stream) functions instead of stabbing at the raw underlying state inside of various Game Boy core emulation classes. So things are a lot better abstracted now.
2016-02-08 03:17:59 +00:00
}
auto System::unload() -> void {
if(!loaded()) return;
eeprom.setName("");
eeprom.setSize(0);
Update to v097r12 release. byuu says: Nothing WS-related this time. First, I fixed expansion port device mapping. On first load, it was mapping the expansion port device too late, so it ended up not taking effect. I had to spin out the logic for that into Program::connectDevices(). This was proving to be quite annoying while testing eBoot (SNES-Hook simulation.) Second, I fixed the audio->set(Frequency, Latency) functions to take (uint) parameters from the configuration file, so the weird behavior around changing settings in the audio panel should hopefully be gone now. Third, I rewrote the interface->load,unload functions to call into the (Emulator)::System::load,unload functions. And I have those call out to Cartridge::load,unload. Before, this was inverted, and Cartridge::load() was invoking System::load(), which I felt was kind of backward. The Super Game Boy really didn't like this change, however. And it took me a few hours to power through it. Before, I had the Game Boy core dummying out all the interface->(load,save)Request calls, and having the SNES core make them for it. This is because the folder paths and IDs will be different between the two cores. I've redesigned things so that ICD2's Emulator::Interface overloads loadRequest and saveRequest, and translates the requests into new requests for the SuperFamicom core. This allows the Game Boy code to do its own loading for everything without a bunch of Super Game Boy special casing, and without any awkwardness around powering on with no cartridge inserted. This also lets the SNES side of things simply call into higher-level GameBoy::interface->load,save(id, stream) functions instead of stabbing at the raw underlying state inside of various Game Boy core emulation classes. So things are a lot better abstracted now.
2016-02-08 03:17:59 +00:00
cartridge.unload();
_loaded = false;
}
auto System::power() -> void {
Update to v098r06 release. byuu says: Changelog: - emulation cores now refresh video from host thread instead of cothreads (fix AMD crash) - SFC: fixed another bug with leap year months in SharpRTC emulation - SFC: cleaned up camelCase on function names for armdsp,epsonrtc,hitachidsp,mcc,nss,sharprtc classes - GB: added MBC1M emulation (requires manually setting mapper=MBC1M in manifest.bml for now, sorry) - audio: implemented Emulator::Audio mixer and effects processor - audio: implemented Emulator::Stream interface - it is now possible to have more than two audio streams: eg SNES + SGB + MSU1 + Voicer-Kun (eventually) - audio: added reverb delay + reverb level settings; exposed balance configuration in UI - video: reworked palette generation to re-enable saturation, gamma, luminance adjustments - higan/emulator.cpp is gone since there was nothing left in it I know you guys are going to say the color adjust/balance/reverb stuff is pointless. And indeed it mostly is. But I like the idea of allowing some fun special effects and configurability that isn't system-wide. Note: there seems to be some kind of added audio lag in the SGB emulation now, and I don't really understand why. The code should be effectively identical to what I had before. The only main thing is that I'm sampling things to 48000hz instead of 32040hz before mixing. There's no point where I'm intentionally introducing added latency though. I'm kind of stumped, so if anyone wouldn't mind taking a look at it, it'd be much appreciated :/ I don't have an MSU1 test ROM, but the latency issue may affect MSU1 as well, and that would be very bad.
2016-04-22 13:35:51 +00:00
Emulator::video.reset();
Emulator::video.setInterface(interface);
configureVideoPalette();
configureVideoEffects();
Emulator::audio.reset();
Emulator::audio.setInterface(interface);
Update to v100r14 release. byuu says: (Windows: compile with -fpermissive to silence an annoying error. I'll fix it in the next WIP.) I completely replaced the time management system in higan and overhauled the scheduler. Before, processor threads would have "int64 clock"; and there would be a 1:1 relationship between two threads. When thread A ran for X cycles, it'd subtract X * B.Frequency from clock; and when thread B ran for Y cycles, it'd add Y * A.Frequency from clock. This worked well and allowed perfect precision; but it doesn't work when you have more complicated relationships: eg the 68K can sync to the Z80 and PSG; the Z80 to the 68K and PSG; so the PSG needs two counters. The new system instead uses a "uint64 clock" variable that represents time in attoseconds. Every time the scheduler exits, it subtracts the smallest clock count from all threads, to prevent an overflow scenario. The only real downside is that rounding errors mean that roughly every 20 minutes, we have a rounding error of one clock cycle (one 20,000,000th of a second.) However, this only applies to systems with multiple oscillators, like the SNES. And when you're in that situation ... there's no such thing as a perfect oscillator anyway. A real SNES will be thousands of times less out of spec than 1hz per 20 minutes. The advantages are pretty immense. First, we obviously can now support more complex relationships between threads. Second, we can build a much more abstracted scheduler. All of libco is now abstracted away completely, which may permit a state-machine / coroutine version of Thread in the future. We've basically gone from this: auto SMP::step(uint clocks) -> void { clock += clocks * (uint64)cpu.frequency; dsp.clock -= clocks; if(dsp.clock < 0 && !scheduler.synchronizing()) co_switch(dsp.thread); if(clock >= 0 && !scheduler.synchronizing()) co_switch(cpu.thread); } To this: auto SMP::step(uint clocks) -> void { Thread::step(clocks); synchronize(dsp); synchronize(cpu); } As you can see, we don't have to do multiple clock adjustments anymore. This is a huge win for the SNES CPU that had to update the SMP, DSP, all peripherals and all coprocessors. Likewise, we don't have to synchronize all coprocessors when one runs, now we can just synchronize the active one to the CPU. Third, when changing the frequencies of threads (think SGB speed setting modes, GBC double-speed mode, etc), it no longer causes the "int64 clock" value to be erroneous. Fourth, this results in a fairly decent speedup, mostly across the board. Aside from the GBA being mostly a wash (for unknown reasons), it's about an 8% - 12% speedup in every other emulation core. Now, all of this said ... this was an unbelievably massive change, so ... you know what that means >_> If anyone can help test all types of SNES coprocessors, and some other system games, it'd be appreciated. ---- Lastly, we have a bitchin' new about screen. It unfortunately adds ~200KiB onto the binary size, because the PNG->C++ header file transformation doesn't compress very well, and I want to keep the original resource files in with the higan archive. I might try some things to work around this file size increase in the future, but for now ... yeah, slightly larger archive sizes, sorry. The logo's a bit busted on Windows (the Label control's background transparency and alignment settings aren't working), but works well on GTK. I'll have to fix Windows before the next official release. For now, look on my Twitter feed if you want to see what it's supposed to look like. ---- EDIT: forgot about ICD2::Enter. It's doing some weird inverse run-to-save thing that I need to implement support for somehow. So, save states on the SGB core probably won't work with this WIP.
2016-07-30 03:56:12 +00:00
scheduler.reset();
bus.power();
iram.power();
eeprom.power();
cpu.power();
ppu.power();
apu.power();
cartridge.power();
Update to v100r14 release. byuu says: (Windows: compile with -fpermissive to silence an annoying error. I'll fix it in the next WIP.) I completely replaced the time management system in higan and overhauled the scheduler. Before, processor threads would have "int64 clock"; and there would be a 1:1 relationship between two threads. When thread A ran for X cycles, it'd subtract X * B.Frequency from clock; and when thread B ran for Y cycles, it'd add Y * A.Frequency from clock. This worked well and allowed perfect precision; but it doesn't work when you have more complicated relationships: eg the 68K can sync to the Z80 and PSG; the Z80 to the 68K and PSG; so the PSG needs two counters. The new system instead uses a "uint64 clock" variable that represents time in attoseconds. Every time the scheduler exits, it subtracts the smallest clock count from all threads, to prevent an overflow scenario. The only real downside is that rounding errors mean that roughly every 20 minutes, we have a rounding error of one clock cycle (one 20,000,000th of a second.) However, this only applies to systems with multiple oscillators, like the SNES. And when you're in that situation ... there's no such thing as a perfect oscillator anyway. A real SNES will be thousands of times less out of spec than 1hz per 20 minutes. The advantages are pretty immense. First, we obviously can now support more complex relationships between threads. Second, we can build a much more abstracted scheduler. All of libco is now abstracted away completely, which may permit a state-machine / coroutine version of Thread in the future. We've basically gone from this: auto SMP::step(uint clocks) -> void { clock += clocks * (uint64)cpu.frequency; dsp.clock -= clocks; if(dsp.clock < 0 && !scheduler.synchronizing()) co_switch(dsp.thread); if(clock >= 0 && !scheduler.synchronizing()) co_switch(cpu.thread); } To this: auto SMP::step(uint clocks) -> void { Thread::step(clocks); synchronize(dsp); synchronize(cpu); } As you can see, we don't have to do multiple clock adjustments anymore. This is a huge win for the SNES CPU that had to update the SMP, DSP, all peripherals and all coprocessors. Likewise, we don't have to synchronize all coprocessors when one runs, now we can just synchronize the active one to the CPU. Third, when changing the frequencies of threads (think SGB speed setting modes, GBC double-speed mode, etc), it no longer causes the "int64 clock" value to be erroneous. Fourth, this results in a fairly decent speedup, mostly across the board. Aside from the GBA being mostly a wash (for unknown reasons), it's about an 8% - 12% speedup in every other emulation core. Now, all of this said ... this was an unbelievably massive change, so ... you know what that means >_> If anyone can help test all types of SNES coprocessors, and some other system games, it'd be appreciated. ---- Lastly, we have a bitchin' new about screen. It unfortunately adds ~200KiB onto the binary size, because the PNG->C++ header file transformation doesn't compress very well, and I want to keep the original resource files in with the higan archive. I might try some things to work around this file size increase in the future, but for now ... yeah, slightly larger archive sizes, sorry. The logo's a bit busted on Windows (the Label control's background transparency and alignment settings aren't working), but works well on GTK. I'll have to fix Windows before the next official release. For now, look on my Twitter feed if you want to see what it's supposed to look like. ---- EDIT: forgot about ICD2::Enter. It's doing some weird inverse run-to-save thing that I need to implement support for somehow. So, save states on the SGB core probably won't work with this WIP.
2016-07-30 03:56:12 +00:00
scheduler.primary(cpu);
bus.map(this, 0x0060);
bus.map(this, 0x00ba, 0x00be);
r.unknown = 0;
r.format = 0;
r.depth = 0;
r.color = 0;
}
auto System::run() -> void {
if(scheduler.enter() == Scheduler::Event::Frame) ppu.refresh();
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
pollKeypad();
}
auto System::runToSave() -> void {
Update to v100r14 release. byuu says: (Windows: compile with -fpermissive to silence an annoying error. I'll fix it in the next WIP.) I completely replaced the time management system in higan and overhauled the scheduler. Before, processor threads would have "int64 clock"; and there would be a 1:1 relationship between two threads. When thread A ran for X cycles, it'd subtract X * B.Frequency from clock; and when thread B ran for Y cycles, it'd add Y * A.Frequency from clock. This worked well and allowed perfect precision; but it doesn't work when you have more complicated relationships: eg the 68K can sync to the Z80 and PSG; the Z80 to the 68K and PSG; so the PSG needs two counters. The new system instead uses a "uint64 clock" variable that represents time in attoseconds. Every time the scheduler exits, it subtracts the smallest clock count from all threads, to prevent an overflow scenario. The only real downside is that rounding errors mean that roughly every 20 minutes, we have a rounding error of one clock cycle (one 20,000,000th of a second.) However, this only applies to systems with multiple oscillators, like the SNES. And when you're in that situation ... there's no such thing as a perfect oscillator anyway. A real SNES will be thousands of times less out of spec than 1hz per 20 minutes. The advantages are pretty immense. First, we obviously can now support more complex relationships between threads. Second, we can build a much more abstracted scheduler. All of libco is now abstracted away completely, which may permit a state-machine / coroutine version of Thread in the future. We've basically gone from this: auto SMP::step(uint clocks) -> void { clock += clocks * (uint64)cpu.frequency; dsp.clock -= clocks; if(dsp.clock < 0 && !scheduler.synchronizing()) co_switch(dsp.thread); if(clock >= 0 && !scheduler.synchronizing()) co_switch(cpu.thread); } To this: auto SMP::step(uint clocks) -> void { Thread::step(clocks); synchronize(dsp); synchronize(cpu); } As you can see, we don't have to do multiple clock adjustments anymore. This is a huge win for the SNES CPU that had to update the SMP, DSP, all peripherals and all coprocessors. Likewise, we don't have to synchronize all coprocessors when one runs, now we can just synchronize the active one to the CPU. Third, when changing the frequencies of threads (think SGB speed setting modes, GBC double-speed mode, etc), it no longer causes the "int64 clock" value to be erroneous. Fourth, this results in a fairly decent speedup, mostly across the board. Aside from the GBA being mostly a wash (for unknown reasons), it's about an 8% - 12% speedup in every other emulation core. Now, all of this said ... this was an unbelievably massive change, so ... you know what that means >_> If anyone can help test all types of SNES coprocessors, and some other system games, it'd be appreciated. ---- Lastly, we have a bitchin' new about screen. It unfortunately adds ~200KiB onto the binary size, because the PNG->C++ header file transformation doesn't compress very well, and I want to keep the original resource files in with the higan archive. I might try some things to work around this file size increase in the future, but for now ... yeah, slightly larger archive sizes, sorry. The logo's a bit busted on Windows (the Label control's background transparency and alignment settings aren't working), but works well on GTK. I'll have to fix Windows before the next official release. For now, look on my Twitter feed if you want to see what it's supposed to look like. ---- EDIT: forgot about ICD2::Enter. It's doing some weird inverse run-to-save thing that I need to implement support for somehow. So, save states on the SGB core probably won't work with this WIP.
2016-07-30 03:56:12 +00:00
scheduler.synchronize(cpu);
scheduler.synchronize(ppu);
scheduler.synchronize(apu);
scheduler.synchronize(cartridge);
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
}
Update to v097r24 release. byuu says: Changelog: - WS: fixed bug when IRQs triggered during a rep string instruction - WS: added sprite attribute caching (per-scanline); absolutely massive speed-up - WS: emulated limit of 32 sprites per scanline - WS: emulated the extended PPU register bit behavior based on the DISP_CTRL tile bit-depth setting - WS: added "Rotate" key binding; can be used to flip the WS display between horizontal and vertical in real-time The prefix emulation may not be 100% hardware-accurate, but the edge cases should be extreme enough to not come up in the WS library. No way to get the emulation 100% down without intensive hardware testing. trap15 pointed me at a workflow diagram for it, but that diagram is impossible without a magic internal stack frame that grows with every IRQ, and can thus grow infinitely large. The rotation thing isn't exactly the most friendly set-up, but oh well. I'll see about adding a default rotation setting to manifests, so that games like GunPey can start in the correct orientation. After that, if the LCD orientation icon turns out to be reliable, then I'll start using that. But if there are cases where it's not reliable, then I'll leave it to manual button presses. Speaking of icons, I'll need a set of icons to render on the screen. Going to put them to the top right on vertical orientation, and on the bottom left for horizontal orientation. Just outside of the video output, of course. Overall, WS is getting pretty far along, but still some major bugs in various games. I really need sound emulation, though. Nobody's going to use this at all without that.
2016-03-12 13:27:41 +00:00
Update to v097r28 release. byuu says: Changelog: (all WSC unless otherwise noted) - fixed LINECMP=0 interrupt case (fixes FF4 world map during airship sequence) - improved CPU timing (fixes Magical Drop flickering and FF1 battle music) - added per-frame OAM caching (fixes sprite glitchiness in Magical Drop, Riviera, etc.) - added RTC emulation (fixes Dicing Knight and Judgement Silversword) - added save state support - added cheat code support (untested because I don't know of any cheat codes that exist for this system) - icarus: can now detect games with RTC chips - SFC: bugfix to SharpRTC emulation (Dai Kaijuu Monogatari II) - ( I was adding the extra leap year day to all 12 months instead of just February ... >_< ) Note that the RTC emulation is very incomplete. It's not really documented at all, and the two games I've tried that use it never even ask you to set the date/time (so they're probably just using it to count seconds.) I'm not even sure if I've implement the level-sensitive behavior correctly (actually, now that I think about it, I need to mask the clear bit in INT_ACK for the level-sensitive interrupts ...) A bit worried about the RTC alarm, because it seems like it'll fire continuously for a full minute. Or even if you turn it off after it fires, then that doesn't seem to be lowering the line until the next second ticks on the RTC, so that likely needs to happen when changing the alarm flag. Also not sure on this RTC's weekday byte. On the SharpRTC, it actually computes this for you. Because it's not at all an easy thing to calculate yourself in 65816 or V30MZ assembler. About 40 lines of code to do it in C. For now, I'm requiring the program to calculate the value itself. Also note that there's some gibberish tiles in Judgement Silversword, sadly. Not sure what's up there, but the game's still fully playable at least. Finally, no surprise: Beat-Mania doesn't run :P
2016-03-25 06:19:08 +00:00
auto System::pollKeypad() -> void {
uint port = !_orientation ? ID::Port::HardwareHorizontal : ID::Port::HardwareVertical;
uint device = ID::Device::Controls;
Update to v097r24 release. byuu says: Changelog: - WS: fixed bug when IRQs triggered during a rep string instruction - WS: added sprite attribute caching (per-scanline); absolutely massive speed-up - WS: emulated limit of 32 sprites per scanline - WS: emulated the extended PPU register bit behavior based on the DISP_CTRL tile bit-depth setting - WS: added "Rotate" key binding; can be used to flip the WS display between horizontal and vertical in real-time The prefix emulation may not be 100% hardware-accurate, but the edge cases should be extreme enough to not come up in the WS library. No way to get the emulation 100% down without intensive hardware testing. trap15 pointed me at a workflow diagram for it, but that diagram is impossible without a magic internal stack frame that grows with every IRQ, and can thus grow infinitely large. The rotation thing isn't exactly the most friendly set-up, but oh well. I'll see about adding a default rotation setting to manifests, so that games like GunPey can start in the correct orientation. After that, if the LCD orientation icon turns out to be reliable, then I'll start using that. But if there are cases where it's not reliable, then I'll leave it to manual button presses. Speaking of icons, I'll need a set of icons to render on the screen. Going to put them to the top right on vertical orientation, and on the bottom left for horizontal orientation. Just outside of the video output, of course. Overall, WS is getting pretty far along, but still some major bugs in various games. I really need sound emulation, though. Nobody's going to use this at all without that.
2016-03-12 13:27:41 +00:00
bool rotate = keypad.rotate;
Update to v099r08 release. byuu says: Changelog: - nall/vfs work 100% completed; even SGB games load now - emulation cores now call load() for the base cartridges as well - updated port/device handling; portmask is gone; device ID bug should be resolved now - SNES controller port 1 multitap option was removed - added support for 128KiB SNES PPU VRAM (for now, edit sfc/ppu/ppu.hpp VRAM::size=0x10000; to enable) Overall, nall/vfs was a huge success!! We've substantially reduced the amount of boilerplate code everywhere, while still allowing (even easier than before) support for RAM-based game loading/saving. All of nall/stream is dead and buried. I am considering removing Emulator::Interface::Medium::id and/or bootable flag. Or at least, doing something different with it. The values for the non-bootable GB/BS/ST entries duplicate the ID that is supposed to be unique. They are for GB/GBC and WS/WSC. Maybe I'll use this as the hardware revision selection ID, and then gut non-bootable options. There's really no reason for that to be there. I think at one point I was using it to generate library tabs for non-bootable systems, but we don't do that anymore anyway. Emulator::Interface::load() may not need the required flag anymore ... it doesn't really do anything right now anyway. I have a few reasons for having the cores load the base cartridge. Most importantly, it is going to enable a special mode for the WonderSwan / WonderSwan Color in the future. If we ever get the IPLROMs dumped ... it's possible to boot these systems with no games inserted to set user profile information and such. There are also other systems that may accept being booted without a cartridge. To reach this state, you would load a game and then cancel the load dialog. Right now, this results in games not loading. The second reason is this prevents nasty crashes when loading fails. So if you're missing a required manifest, the emulator won't die a violent death anymore. It's able to back out at any point. The third reason is consistency: loading the base cartridge works the same as the slot cartridges. The fourth reason is Emulator::Interface::open(uint pathID) values. Before, the GB, SB, GBC modes were IDs 1,2,3 respectively. This complicated things because you had to pass the correct ID. But now instead, Emulator::Interface::load() returns maybe<uint> that is nothing when no game is selected, and a pathID for a valid game. And now open() can take this ID to access this game's folder contents. The downside, which is temporary, is that command-line loading is currently broken. But I do intend on restoring it. In fact, I want to do better than before and allow multi-cart booting from the command-line by specifying the base cartridge and then slot cartridges. The idea should be pretty simple: keep a queue of pending filenames that we fill from the command-line and/or drag-and-drop operations on the main window, and then empty out the queue or prompt for load dialogs from the UI when booting a system. This also might be a bit more unorthodox compared to the traditional emulator design of "loadGame(filename)", but ... oh well. It's easy enough still. The port/device changes are fun. We simplified things quite a bit. The portmask stuff is gone entirely. While ports and devices keep IDs, this is really just sugar-coating so UIs can use for(auto& port : emulator->ports) and access port.id; rather than having to use for(auto n : range(emulator->ports)) { auto& port = emulator->ports[n]; ... }; but they should otherwise generally be identical to the order they appear in their respective ranges. Still, don't rely on that. Input::id is gone. There was no point since we also got rid of the nasty Input::order vector. Since I was in here, I went ahead and caved on the pedantics and renamed Input::guid to Input::userData. I removed the SNES controller port 1 multitap option. Basically, the only game that uses this is N-warp Daisakusen and, no offense to d4s, it's not really a good game anyway. It's just a quick demo to show 8-players on the SNES. But in the UI, all it does is confuse people into wasting time mapping a controller they're never going to use, and they're going to wonder which port to use. If more compelling use cases for 8-players comes about, we can reconsider this. I left all the code to support this in place, so all you have to do is uncomment one line to enable it again. We now have dsnes emulation! :D If you change PPU::VRAM::size to 0x10000 (words), then you should now have 128KiB of VRAM. Even better, it serializes the used-VRAM size, so your save states shouldn't crash on you if you swap between the two (though if you try this, you're nuts.) Note that this option does break commercial software. Yoshi's Island in particular. This game is setting A15 on some PPU register writes, but not on others. The end result of this is things break horribly in-game. Also, this option is causing a very tiny speed hit for obvious reasons with the variable masking value (I'm even using size-1 for now.) Given how niche this is, I may just leave it a compile-time constant to avoid the overhead cost. Otherwise, if we keep the option, then it'll go into Super Famicom.sys/manifest.bml ... I'll flesh that out in the near-future. ---- Finally, some fun for my OCD ... my monitor suddenly cut out on me in the middle of working on this WIP, about six hours in of non-stop work. Had to hit a bunch of ctrl+alt+fN commands (among other things) and trying to log in headless on another TTY to do issue commands, trying to recover the display. Finally power cycled the monitor and it came back up. So all my typing ended up going to who knows where. Usually this sort of thing terrifies me enough that I scrap a WIP and start over to ensure I didn't screw anything up during the crashed screen when hitting keys randomly. Obviously, everything compiles and appears to work fine. And I know it's extremely paranoid, but OCD isn't logical, so ... I'm going to go over every line of the 100KiB r07->r08 diff looking for any corruption/errors/whatever. ---- Review finished. r08 diff review notes: - fc/controller/gamepad/gamepad.cpp: use uint device = ID::Device::Gamepad; not id = ...; - gb/cartridge/cartridge.hpp: remove redundant uint _pathID; (in Information::pathID already) - gb/cartridge/cartridge.hpp: pull sha256 inside Information - sfc/cartridge/load/cpp: add " - Slot (A,B)" to interface->load("Sufami Turbo"); to be more descriptive - sfc/controller/gamepad/gamepad.cpp: use uint device = ID::Device::Gamepad; not id = ...; - sfc/interface/interface.cpp: remove n variable from the Multitap device input generation loop (now unused) - sfc/interface/interface.hpp: put struct Port above struct Device like the other classes - ui-tomoko: cheats.bml is reading from/writing to mediumPaths(0) [system folder instead of game folder] - ui-tomoko: instead of mediumPaths(1) - call emulator->metadataPathID() or something like that
2016-06-24 12:16:53 +00:00
keypad.y1 = platform->inputPoll(port, device, 0);
keypad.y2 = platform->inputPoll(port, device, 1);
keypad.y3 = platform->inputPoll(port, device, 2);
keypad.y4 = platform->inputPoll(port, device, 3);
keypad.x1 = platform->inputPoll(port, device, 4);
keypad.x2 = platform->inputPoll(port, device, 5);
keypad.x3 = platform->inputPoll(port, device, 6);
keypad.x4 = platform->inputPoll(port, device, 7);
keypad.b = platform->inputPoll(port, device, 8);
keypad.a = platform->inputPoll(port, device, 9);
keypad.start = platform->inputPoll(port, device, 10);
keypad.rotate = platform->inputPoll(port, device, 11);
Update to v097r24 release. byuu says: Changelog: - WS: fixed bug when IRQs triggered during a rep string instruction - WS: added sprite attribute caching (per-scanline); absolutely massive speed-up - WS: emulated limit of 32 sprites per scanline - WS: emulated the extended PPU register bit behavior based on the DISP_CTRL tile bit-depth setting - WS: added "Rotate" key binding; can be used to flip the WS display between horizontal and vertical in real-time The prefix emulation may not be 100% hardware-accurate, but the edge cases should be extreme enough to not come up in the WS library. No way to get the emulation 100% down without intensive hardware testing. trap15 pointed me at a workflow diagram for it, but that diagram is impossible without a magic internal stack frame that grows with every IRQ, and can thus grow infinitely large. The rotation thing isn't exactly the most friendly set-up, but oh well. I'll see about adding a default rotation setting to manifests, so that games like GunPey can start in the correct orientation. After that, if the LCD orientation icon turns out to be reliable, then I'll start using that. But if there are cases where it's not reliable, then I'll leave it to manual button presses. Speaking of icons, I'll need a set of icons to render on the screen. Going to put them to the top right on vertical orientation, and on the bottom left for horizontal orientation. Just outside of the video output, of course. Overall, WS is getting pretty far along, but still some major bugs in various games. I really need sound emulation, though. Nobody's going to use this at all without that.
2016-03-12 13:27:41 +00:00
Update to v097r27 release. byuu says: Absolutely major improvements to the WS/C emulation today. Changelog: (all WS/C related) - fixed channel 3 sweep pitch adjustment - fixed channel 3 sweep value sign extension - removed errant channel 5 speed setting (not what's really going on) - fixed sign extension on channel 5 samples - improved DAC mixing of all five audio channels - fixed r26 regression with PPU timing loop - fixed sprite windowing behavior (sprite attribute flag is window mode; not window enable) - added per-scanline register latching to the PPU - IRQs should terminate HLT even when the IRQ enable register bits are clear - fixed PALMONO reads - added blur emulation - added color emulation (based on GBA, so it heavily desaturates colors; not entirely correct, but it helps a lot) - no longer decimating audio to 24KHz; running at full 3.072MHz through the windowed sinc filter [1] - cleaned up PPU portRead / portWrite functions significantly - emulated a weird quirk as mentioned by trap15 regarding timer frequency writes enabling said timers [2] - emulated LCD_CTRL sleep bit; screen can now be disabled (always draws black in this case for now) - improved OAM caching; but it's still disabled because it causes huge amounts of sprite glitches (unsure why) - fixed rendering of sprites that wrap around the screen edges back to the top/left of the display - emulated keypad interrupts - icarus: detect orientation bit in game header - higan: use orientation setting in manifest to set default screen rotation [1] the 24KHz -> 3.072MHz sound change is huge. Sound is substantially improved over the previous WIPs. It does come at a pretty major speed penalty, though. This is the highest frequency of any system in higan running through an incredibly (amazing, yet) demanding sinc resampler. Frame rate dropped from around 240fps to 150fps with the sinc filter on. If you choose a different audio filter, you'll get most of that speed back, but audio will sound worse again. [2] we aren't sure if this is correct hardware behavior or not. It seems to very slightly help Magical Drop, but not much. The blur emulation is brutal. It's absolutely required for Riviera's translucency simulation of selected menu items, but it causes serious headaches due to the WS's ~75hz refresh rate running on ~60hz monitors without vsync. It's probably best to leave it off and just deal with the awful flickering on Riviera's menu options. Overall, WS/C emulation is starting to get quite usable indeed. Couple of major bugs that I'd really like to get fixed before releasing it, though. But they're getting harder and harder to fix ... Major Bugs: - Final Fantasy battle background music is absent. Sound effects still work. Very weird. - Final Fantasy IV scrolling during airship flight opening sequence is horribly broken. Scrolls one screen at a time. - Magical Drop flickers like crazy in-game. Basically unplayable like this. - Star Hearts character names don't appear in the smaller dialog box that pops up. Minor Bugs: - Occasional flickering during Riviera opening scenes. - One-frame flicker of Leda's sprite at the start of the first stage.
2016-03-19 07:35:25 +00:00
if(keypad.y1 || keypad.y2 || keypad.y3 || keypad.y4
|| keypad.x1 || keypad.x2 || keypad.x3 || keypad.x4
|| keypad.b || keypad.a || keypad.start
) {
cpu.raise(CPU::Interrupt::Input);
}
Update to v097r24 release. byuu says: Changelog: - WS: fixed bug when IRQs triggered during a rep string instruction - WS: added sprite attribute caching (per-scanline); absolutely massive speed-up - WS: emulated limit of 32 sprites per scanline - WS: emulated the extended PPU register bit behavior based on the DISP_CTRL tile bit-depth setting - WS: added "Rotate" key binding; can be used to flip the WS display between horizontal and vertical in real-time The prefix emulation may not be 100% hardware-accurate, but the edge cases should be extreme enough to not come up in the WS library. No way to get the emulation 100% down without intensive hardware testing. trap15 pointed me at a workflow diagram for it, but that diagram is impossible without a magic internal stack frame that grows with every IRQ, and can thus grow infinitely large. The rotation thing isn't exactly the most friendly set-up, but oh well. I'll see about adding a default rotation setting to manifests, so that games like GunPey can start in the correct orientation. After that, if the LCD orientation icon turns out to be reliable, then I'll start using that. But if there are cases where it's not reliable, then I'll leave it to manual button presses. Speaking of icons, I'll need a set of icons to render on the screen. Going to put them to the top right on vertical orientation, and on the bottom left for horizontal orientation. Just outside of the video output, of course. Overall, WS is getting pretty far along, but still some major bugs in various games. I really need sound emulation, though. Nobody's going to use this at all without that.
2016-03-12 13:27:41 +00:00
if(!rotate && keypad.rotate) {
_orientation = !_orientation;
}
}
}