bsnes/higan/md/vdp/vdp.hpp

181 lines
3.7 KiB
C++
Raw Normal View History

//Yamaha YM7101
Update to v100r02 release. byuu says: Sigh ... I'm really not a good person. I'm inherently selfish. My responsibility and obligation right now is to work on loki, and then on the Tengai Makyou Zero translation, and then on improving the Famicom emulation. And yet ... it's not what I really want to do. That shouldn't matter; I should work on my responsibilities first. Instead, I'm going to be a greedy, self-centered asshole, and work on what I really want to instead. I'm really sorry, guys. I'm sure this will make a few people happy, and probably upset even more people. I'm also making zero guarantees that this ever gets finished. As always, I wish I could keep these things secret, so if I fail / give up, I could just drop it with no shame. But I would have to cut everyone out of the WIP process completely to make it happen. So, here goes ... This WIP adds the initial skeleton for Sega Mega Drive / Genesis emulation. God help us. (minor note: apparently the new extension for Mega Drive games is .md, neat. That's what I chose for the folders too. I thought it was .smd, so that'll be fixed in icarus for the next WIP.) (aside: this is why I wanted to get v100 out. I didn't want this code in a skeleton state in v100's source. Nor did I want really broken emulation, which the first release is sure to be, tarring said release.) ... So, basically, I've been ruminating on the legacy I want to leave behind with higan. 3D systems are just plain out. I'm never going to support them. They're too complex for my abilities, and they would run too slowly with my design style. I'm not willing to compromise my design ideals. And I would never want to play a 3D game system at native 240p/480i resolution ... but 1080p+ upscaling is not accurate, so that's a conflict I want to avoid entirely. It's also never going to emulate computer systems (X68K, PC-98, FM-Towns, etc) because holy shit that would completely destroy me. It's also never going emulate arcade machines. So I think of higan as a collection of 2D emulators for consoles and handhelds. I've gone over every major 2D gaming system there is, looking for ones with games I actually care about and enjoy. And I basically have five of those systems supported already. Looking at the remaining list, I see only three systems left that I have any interest in whatsoever: PC-Engine, Master System, Mega Drive. Again, I'm not in any way committing to emulating any of these, but ... if I had all of those in higan, I think I'd be content to really, truly, finally stop writing more emulators for the rest of my life. And so I decided to tackle the most difficult system first. If I'm successful, the Z80 core should cover a lot of the work on the SMS. And the HuC6280 should land somewhere between the NES and SNES in terms of difficulty ... closer to the NES. The systems that just don't appeal to me at all, which I will never touch, include, but are not limited to: * Atari 2600/5200/7800 * Lynx * Jaguar * Vectrex * Colecovision * Commodore 64 * Neo-Geo * Neo-Geo Pocket / Color * Virtual Boy * Super A'can * 32X * CD-i * etc, etc, etc. And really, even if something were mildly interesting in there ... we have to stop. I can't scale infinitely. I'm already way past my limit, but I'm doing this anyway. Too many cores bloats everything and kills quality on everything. I don't want higan to become MESS v2. I don't know what I'll do about the Famicom Disk System, PC-Engine CD, and Mega CD. I don't think I'll be able to achieve 60fps emulating the Mega CD, even if I tried to. I don't know what's going to happen here with even the Mega Drive. Maybe I'll get driven crazy with the documentation and quit. Maybe it'll end up being too complicated and I'll quit. Maybe the emulation will end up way too slow and I'll give up. Maybe it'll take me seven years to get any games playable at all. Maybe Steve Snake, AamirM and Mike Pavone will pool money to hire a hitman to come after me. Who knows. But this is what I want to do, so ... here goes nothing.
2016-07-09 04:21:37 +00:00
struct VDP : Thread {
static auto Enter() -> void;
auto main() -> void;
auto step(uint clocks) -> void;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
auto refresh() -> void;
auto power() -> void;
auto reset() -> void;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//io.cpp
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
auto readByte(uint24 addr) -> uint8;
auto writeByte(uint24 addr, uint8 data) -> void;
auto readWord(uint24 addr) -> uint16;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
auto writeWord(uint24 addr, uint16 data) -> void;
auto readDataPort() -> uint16;
auto writeDataPort(uint16 data) -> void;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
auto readControlPort() -> uint16;
auto writeControlPort(uint16 data) -> void;
//dma.cpp
auto dmaRun() -> void;
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
auto dmaLoad() -> void;
auto dmaFill() -> void;
auto dmaCopy() -> void;
//render.cpp
auto scanline() -> void;
auto run() -> void;
auto outputPixel(uint9 color) -> void;
//background.cpp
struct Background {
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
auto scanline(uint y) -> void;
auto run(uint x, uint y) -> void;
auto power() -> void;
auto reset() -> void;
struct IO {
uint15 nametableAddress;
uint3 nametableWidth; //1 << value
uint3 nametableHeight; //1 << value
} io;
struct Output {
uint6 color;
boolean priority;
} output;
};
Background planeA;
Background window;
Background planeB;
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
//sprite.cpp
struct Sprite {
auto write(uint9 addr, uint16 data) -> void;
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
auto scanline(uint y) -> void;
auto run(uint x, uint y) -> void;
auto power() -> void;
auto reset() -> void;
struct IO {
uint15 attributeAddress;
uint1 nametableAddressBase;
} io;
struct Object {
uint10 x;
uint10 y;
uint width;
uint height;
bool horizontalFlip;
bool verticalFlip;
uint2 palette;
uint1 priority;
uint15 address;
uint7 link;
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
};
struct Output {
uint6 color;
boolean priority;
} output;
array<Object, 80> oam;
array<Object, 20> object;
};
Sprite sprite;
private:
uint16 vram[32768];
uint16 vramExpansion[32768]; //not present in stock Mega Drive hardware
uint9 cram[64];
uint10 vsram[40];
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
struct IO {
//internal state
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
boolean dmaFillWait;
uint8 dmaFillByte;
//command
uint6 command;
uint16 address;
boolean commandPending;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//$00 mode register 1
uint1 displayOverlayEnable;
uint1 counterLatch;
Update to v101r07 release. byuu says: Added VDP sprite rendering. Can't get any games far enough in to see if it actually works. So in other words, it doesn't work at all and is 100% completely broken. Also added 68K exceptions and interrupts. So far only the VDP interrupt is present. It definitely seems to be firing in commercial games, so that's promising. But the implementation is almost certainly completely wrong. There is fuck all of nothing for documentation on how interrupts actually work. I had to find out the interrupt vector numbers from reading the comments from the Sonic the Hedgehog disassembly. I have literally no fucking clue what I0-I2 (3-bit integer priority value in the status register) is supposed to do. I know that Vblank=6, Hblank=4, Ext(gamepad)=2. I know that at reset, SR.I=7. I don't know if I'm supposed to block interrupts when I is >, >=, <, <= to the interrupt level. I don't know what level CPU exceptions are supposed to be. Also implemented VDP regular DMA. No idea if it works correctly since none of the commercial games run far enough to use it. So again, it's horribly broken for usre. Also improved VDP fill mode. But I don't understand how it takes byte-lengths when the bus is 16-bit. The transfer times indicate it's actually transferring at the same speed as the 68K->VDP copy, strongly suggesting it's actually doing 16-bit transfers at a time. In which case, what happens when you set an odd transfer length? Also, both DMA modes can now target VRAM, VSRAM, CRAM. Supposedly there's all kinds of weird shit going on when you target VSRAM, CRAM with VDP fill/copy modes, but whatever. Get to that later. Also implemented a very lazy preliminary wait mechanism to to stall out a processor while another processor exerts control over the bus. This one's going to be a major work in progress. For one, it totally breaks the model I use to do save states with libco. For another, I don't know if a 68K->VDP DMA instantly locks the CPU, or if it the CPU could actually keep running if it was executing out of RAM when it started the DMA transfer from ROM (eg it's a bus busy stall, not a hard chip stall.) That'll greatly change how I handle the waiting. Also, the OSS driver now supports Audio::Latency. Sound should be even lower latency now. On FreeBSD when set to 0ms, it's absolutely incredible. Cannot detect latency whatsoever. The Mario jump sound seems to happen at the very instant I hear my cherry blue keyswitch activate.
2016-08-15 04:56:38 +00:00
uint1 horizontalBlankInterruptEnable;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
uint1 leftColumnBlank;
//$01 mode register 2
uint1 videoMode; //0 = Master System; 1 = Mega Drive
uint1 overscan; //0 = 224 lines; 1 = 240 lines
uint1 dmaEnable;
uint1 verticalBlankInterruptEnable;
uint1 displayEnable;
uint1 externalVRAM;
//$07 background color
uint6 backgroundColor;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//$0a horizontal interrupt counter
uint8 horizontalInterruptCounter;
//$0b mode register 3
uint2 horizontalScrollMode;
uint1 verticalScrollMode;
uint1 externalInterruptEnable;
//$0c mode register 4
uint2 tileWidth;
uint2 interlaceMode;
uint1 shadowHighlightEnable;
uint1 externalColorEnable;
uint1 horizontalSync;
uint1 verticalSync;
//$0d horizontal scroll data location
uint7 horizontalScrollTable;
//$0e nametable pattern base address
uint1 nametableBasePatternA;
uint1 nametableBasePatternB;
//$0f data port auto-increment value
uint8 dataIncrement;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//$11 window plane horizontal position
uint10 windowHorizontalLo;
uint10 windowHorizontalHi;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//$12 window plane vertical position
uint10 windowVerticalLo;
uint10 windowVerticalHi;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
//$13-$14 DMA length
uint16 dmaLength;
//$15-$17 DMA source
uint22 dmaSource;
uint2 dmaMode;
} io;
struct State {
uint32* output = nullptr;
uint x;
uint y;
} state;
Update to v101r04 release. byuu says: Changelog: - pulled the (u)intN type aliases into higan instead of leaving them in nall - added 68K LINEA, LINEF hooks for illegal instructions - filled the rest of the 68K lambda table with generic instance of ILLEGAL - completed the 68K disassembler effective addressing modes - still unsure whether I should use An to decode absolute addresses or not - pro: way easier to read where accesses are taking place - con: requires An to be valid; so as a disassembler it does a poor job - making it optional: too much work; ick - added I/O decoding for the VDP command-port registers - added skeleton timing to all five processor cores - output at 1280x480 (needed for mixed 256/320 widths; and to handle interlace modes) The VDP, PSG, Z80, YM2612 are all stepping one clock at a time and syncing; which is the pathological worst case for libco. But they also have no logic inside of them. With all the above, I'm averaging around 250fps with just the 68K core actually functional, and the VDP doing a dumb "draw white pixels" loop. Still way too early to tell how this emulator is going to perform. Also, the 320x240 mode of the Genesis means that we don't need an aspect correction ratio. But we do need to ensure the output window is a multiple 320x240 so that the scale values work correctly. I was hard-coding aspect correction to stretch the window an additional \*8/7. But that won't work anymore so ... the main higan window is now 640x480, 960x720, or 1280x960. Toggling aspect correction only changes the video width inside the window. It's a bit jarring ... the window is a lot wider, more black space now for most modes. But for now, it is what it is.
2016-08-12 01:07:04 +00:00
uint32 buffer[1280 * 480];
Update to v100r02 release. byuu says: Sigh ... I'm really not a good person. I'm inherently selfish. My responsibility and obligation right now is to work on loki, and then on the Tengai Makyou Zero translation, and then on improving the Famicom emulation. And yet ... it's not what I really want to do. That shouldn't matter; I should work on my responsibilities first. Instead, I'm going to be a greedy, self-centered asshole, and work on what I really want to instead. I'm really sorry, guys. I'm sure this will make a few people happy, and probably upset even more people. I'm also making zero guarantees that this ever gets finished. As always, I wish I could keep these things secret, so if I fail / give up, I could just drop it with no shame. But I would have to cut everyone out of the WIP process completely to make it happen. So, here goes ... This WIP adds the initial skeleton for Sega Mega Drive / Genesis emulation. God help us. (minor note: apparently the new extension for Mega Drive games is .md, neat. That's what I chose for the folders too. I thought it was .smd, so that'll be fixed in icarus for the next WIP.) (aside: this is why I wanted to get v100 out. I didn't want this code in a skeleton state in v100's source. Nor did I want really broken emulation, which the first release is sure to be, tarring said release.) ... So, basically, I've been ruminating on the legacy I want to leave behind with higan. 3D systems are just plain out. I'm never going to support them. They're too complex for my abilities, and they would run too slowly with my design style. I'm not willing to compromise my design ideals. And I would never want to play a 3D game system at native 240p/480i resolution ... but 1080p+ upscaling is not accurate, so that's a conflict I want to avoid entirely. It's also never going to emulate computer systems (X68K, PC-98, FM-Towns, etc) because holy shit that would completely destroy me. It's also never going emulate arcade machines. So I think of higan as a collection of 2D emulators for consoles and handhelds. I've gone over every major 2D gaming system there is, looking for ones with games I actually care about and enjoy. And I basically have five of those systems supported already. Looking at the remaining list, I see only three systems left that I have any interest in whatsoever: PC-Engine, Master System, Mega Drive. Again, I'm not in any way committing to emulating any of these, but ... if I had all of those in higan, I think I'd be content to really, truly, finally stop writing more emulators for the rest of my life. And so I decided to tackle the most difficult system first. If I'm successful, the Z80 core should cover a lot of the work on the SMS. And the HuC6280 should land somewhere between the NES and SNES in terms of difficulty ... closer to the NES. The systems that just don't appeal to me at all, which I will never touch, include, but are not limited to: * Atari 2600/5200/7800 * Lynx * Jaguar * Vectrex * Colecovision * Commodore 64 * Neo-Geo * Neo-Geo Pocket / Color * Virtual Boy * Super A'can * 32X * CD-i * etc, etc, etc. And really, even if something were mildly interesting in there ... we have to stop. I can't scale infinitely. I'm already way past my limit, but I'm doing this anyway. Too many cores bloats everything and kills quality on everything. I don't want higan to become MESS v2. I don't know what I'll do about the Famicom Disk System, PC-Engine CD, and Mega CD. I don't think I'll be able to achieve 60fps emulating the Mega CD, even if I tried to. I don't know what's going to happen here with even the Mega Drive. Maybe I'll get driven crazy with the documentation and quit. Maybe it'll end up being too complicated and I'll quit. Maybe the emulation will end up way too slow and I'll give up. Maybe it'll take me seven years to get any games playable at all. Maybe Steve Snake, AamirM and Mike Pavone will pool money to hire a hitman to come after me. Who knows. But this is what I want to do, so ... here goes nothing.
2016-07-09 04:21:37 +00:00
};
extern VDP vdp;