melonDS aims at providing fast and accurate Nintendo DS emulation. While it is still a work in progress, it has a pretty solid set of features:

• Nearly complete core (CPU, video, audio, ...)
• JIT recompiler for fast emulation
• OpenGL renderer, 3D upscaling
• RTC, microphone, lid close/open
• Joystick support
• Savestates
• Various display position/sizing/rotation modes
• (WIP) Wifi: local multiplayer, online connectivity
• (WIP) DSi emulation
• (WIP) GBA slot add-ons
• and more are planned!

Download melonDS

If you're running into trouble: Howto/FAQ
Breaking the silence
You may have noticed that there's one thing melonDS 0.1 lacks sorely: sound. It's an integral part of the gaming experience.

It's also one of the big items in the TODO list, so let's do this.

Getting basic sound playback going wasn't too difficult. The DS sound hardware is pretty simple: 16 channels that can play sound data encoded in PCM8, PCM16 or IMA-ADPCM. Channels 8 to 13 also support rectangular waves (PSG), and channels 14 and 15 can produce white noise.

I first worked on PSG as it's pretty simple, there would be less things that could go wrong. And indeed, the issues I got were mostly dumb little things like forgetting to clear intermediate buffers. Once that was working, I completed it with support for the remaining sound formats.

And there it was, sound in melonDS. That thing finally begins resembling a DS emulator :)

The sound core in melonDS is synchronous. The major downside is that it sounds like shit if emulation isn't running fullspeed. But it's been stated that the goal of melonDS is to do things right. There are other reasons why it has to be synchronous, too; the main one is sound capture.

The DS has two sound capture units, which can record audio output and write it to memory. Those are used in some games to apply a surround effect to the audio output, or to do reverb. The idea is to send the mixer output to the capture units instead of outputting directly, then use channels 1 and 3 to output the captured audio data after it's been altered by software.

Setups using sound capture expect that capture buffers will be filled at a fixed interval. This breaks apart if your sound core is asynchronous, because there is no guarantee that it will produce sound at a regular rate. What if you end up producing more sound than the game's buffer can hold? In these situations, the best way is to ignore those effects entirely. Same reason why the old HLE audio implementation of Dolphin didn't support reverb effects.

Anyway, sound output is still in the works, but it's fairly promising so far.

Oh by the way, have I mentioned that there are other DS emulators being worked on? Check out medusa!
melonDS 0.1 is out!

It's here, finally! Without further ado, check it out on the downloads page!

You can also read the release notes on the board for more information.
The aging cart
So I got the UI far enough to be able to run things again. Of course, I tried the aging cart.

It's a nice help when it comes to making emulators accurate. It has a nice big set of tests. The code is also well-structured and not too hard to understand. There is a table at 0x021F2FD0 that lists all the tests, pointing to each test's name and the corresponding function.

melonDS failed the DMA priority test, like DeSmuME.

The failure was actually not related to DMA priority, which is handled correctly in melonDS. The DMA priority test runs two DMA transfers, a long one that starts immediately and a short one that starts upon HBlank but has higher priority. Each DMA fills a buffer with values pulled from a shared timer. It then checks the continuity of the stored values to find out whether and when the long DMA was interrupted.

This pointed to something I wanted to do since a while: rework timer emulation in melonDS as it was a bit complex and grossly inaccurate. After doing so, melonDS passed the DMA priority test, but it also fixed a bunch of issues, like FMVs playing at shitty speeds.

After implementing some more obscure DMA types, I was able to pass more tests. For example, DMA type 3 is triggered at the start of each scanline, but it runs on scanlines 2 to 193 included, and, unlike HBlank DMA, it always stops on scanline 194. It's not clear what purpose this DMA type would serve -- maybe it was intended for some external device acquiring video from the screens.

Then came DMA type 4, which is used for feeding the display FIFO. The current implementation in melonDS is a gross hack, but it is pretty much impossible to use the display FIFO without DMA due to its tight timing, and emulating it properly would be resource-intensive. The display FIFO is another obscure feature -- I don't know of any retail game that uses it, but I have yet to be surprised.

At this point, melonDS gets to the capture control test, but fails it. Again, the issue is unrelated to the screen capture logic. The test renders 3D graphics, and checks correctness by checksumming the captured image. Which basically requires pixel-perfect 3D graphics.

The aging cart has been a fun ride so far, and it's still far from being finished :)
melonDS 0.1: soon a thing!
And yet, it may very well take a while.

As stated in the TODO list, the main remaining thing to do, besides fixes to timers, is building an actual UI for melonDS. The current one was something I had thrown together quickly early in development so I could see graphics. melonDS was barely beginning to run things, it supported VRAM display so it could run ARMWrestler, then got some extra graphics support, enough to render the DS firmware interface.

Things have changed a lot since then. melonDS now has an almost-complete 2D renderer with more accurate colors than the other emulators out there, and even a 3D renderer that is more than satisfying for a first release. It got support for a bunch of things that don't sound very exciting but are required to get games working. All in all, I believe we have a fairly solid emulator base.

But the interface is still lame. It still loads a ROM from a hardcoded filename. It's still a barebones video output and a console spewing nonsense as the game runs. It still has hardcoded (and retarded) key mappings.

The current interface is made of Windows-specific code, which is why I didn't build upon it; I want something cross-platform.

I'm still having trouble deciding what I will work with for this UI. I'm considering libui and SDL, if I can get them to cooperate. I want something lightweight, melonDS is going to stay pretty simple. As for SDL, I'm going to need it (or an equivalent library) for things like joystick input or audio output.

I initially hoped to be able to stay away from Visual Studio as far as Windows is concerned, but to my regret, alternate solutions are more or less of a headache to get working. So I'm likely going to ditch the CodeBlocks project and use CMake.

Which reminds me why I have been postponing the UI stuff: I would rather work on interesting emulation stuff than go through this trouble for a cross-platform UI. I recently discovered that there is an aging cart (Nintendo-internal test ROM) for the DS, and of course, I want to run it in melonDS to see how good it does. None of the emulators I know of pass the whole test, which means that either the test ROM is tricky or the emulators aren't as good as we think. Well, in its current state, melonDS wouldn't pass it either, but there's room for improvement.

No screenshots for this post, I'm keeping some surprise for the release ;)
VRAM? Lots of fun!
First of all, a little status update. From the previous list, DMA timings are covered, they're properly emulated except for cart DMA. I have also been fixing several GXFIFO related bugs, which lets most games run fine. Some badly programmed games (SM64DS or Rayman RR2, using immediate DMA instead of proper GXFIFO DMA) still overflow the FIFO a little, and since I haven't yet figured out why, I added a little hack to cover that for now.

Improving the 3D renderer, the other big TODO item, mostly means implementing textures. And also that weird focus I developed on making the renderer pixel-perfect.

Pixel perfection can be postponed. Most games would still be playable fine without it.

Textures mean supporting texture memory, which is a special case of VRAM mapping. I first want to revamp VRAM emulation to better match the hardware. There are notes about VRAM mapping in the melonDS code, and they have been there since a while now, waiting for a proper implementation.

Thing is, VRAM mapping on the DS isn't linear like with most old consoles. You get 9 VRAM banks of different sizes (from 16K to 128K), each can be mapped to different addresses for different purposes. GBAtek documents the mapping modes for each, but it's missing details like how the banks are mirrored and what happens if two or more VRAM banks overlap (which does happen in some games). So, I wanted to test that.

I first assumed the mapping was 1:1, as most DS emulators out there handle it. Which would mean that if two banks overlapped, it would either map the last one, or apply a priority order. So the first test was to map banks A and B to different addresses, write 0x1111 into A and 0x2222 into B, then map them at the same address and read, then do it again but map in a different order. The results would tell whether A has priority over B, or B over A, or whether it just maps the last bank.

The result wasn't quite what I expected. The tests didn't read 0x1111 or 0x2222, they both read 0x3333.

VRAM mapping isn't a 1:1 table. It basically just tells each bank which address range it should respond to. When two banks share an address range, they respond at the same time: writes go to both banks, and reads read from both banks too, ORing the values together, as shown above.

VRAM mirroring is also funky, each bank is mirrored in its own way, and the mirroring scheme doesn't depend on the bank's size. But for special cases like extended palettes or texture memory, mirroring doesn't matter.

I have yet to finish covering the VRAM mapping oddities without completely killing performance, and make the 2D GPU code suck less. Once that's done, we can get to the fun part of implementing textures in the 3D renderer.
On the way to 3D graphics
Unrelated note: I changed the way the site displays comments, to start from the oldest. It feels more natural this way, atleast to me.

So a while ago, I was at the point where getting further with melonDS required emulating the 3D engine.

As tempting as it is to hack things together to get some graphics showing up, I decided I'd take the time to do things right. Plus, GBAtek documents the 3D engine well, so let's make good use of it.

This also means that the renderer I'm building is a software one. This doesn't exclude the possibility of implementing hardware rendering for 3D or even 2D later on, but starting this way is more interesting than mapping the DS 3D features to OpenGL. I'm able to learn about deeper aspects of the 3D engine, and emulate it more closely than a hardware renderer can get. There are also features and details of the original hardware that can't be reproduced well with OpenGL, as is typical with older console GPUs, and it isn't always super-specific details, it can also be about basic features.

For example, the DS is able to draw triangles and quads natively, but modern GPUs can only draw triangles -- the more complex primitives supported by OpenGL are broken down into triangles. This can affect how vertex attributes (color and texture coordinates) are interpolated across a quad. Below are two renders of a quad with the same attributes:

The left one shows color interpolation across the original quad. The right one shows color interpolation after the quad was broken down into triangles. You can notice the difference.

At this point, melonDS's renderer is able to draw polygons without exploding, which is a good start. It can do color interpolation, but it lacks perspective correction for now. It also lacks more important features, like texturing.

Anyway, melonDS isn't too far away from a first release. Here's a quick list of the things that remain to be done before it can be shipped:

* a better 3D renderer, as explained above
* emulating DMA timings
* building a somewhat proper interface
* misc. tidbits: timers that suck less, a few missing bits of the 2D renderer, etc...

Stay tuned for more!
Deeper than it seems
I've been wanting to work out the DS's color precision. Incoming colors (palettes, vertex colors...) are all 15-bit, but the screens actually output 18-bit color. The 3D engine is well documented in this regard, we know that the colors are converted to 18-bit before being blended together and even how they're converted. However, details on the 2D engines are at a loss. GBAtek doesn't say much, other than that master brightness is applied to 18-bit color.

For reference, GBAtek's diagram of the whole video system.

I first tested master brightness. The idea is to configure it in "brightness decrease" mode with a factor of 8, such that incoming colors are halved. Then, fill two parts of the screen with colors 0,2,0 and 0,3,0 respectively. If the colors are processed as 15-bit, they will come out the same, but if they're converted to 18-bit beforehand, there will be a difference. Noting that I picked green colors to make the difference as visible as possible, as the human eye sees green best.

The test reveals that there is a difference, subtle but visible. Which confirms that master brightness is applied to 18-bit color.

To find out where the color conversion takes place, I did the test again, using the "brightness decrease" special effect instead of master brightness. It works the same, but it's applied earlier than master brightness. The test also showed a difference, meaning that color special effects are applied to 18-bit color.

So now we know that colors are converted as soon as possible, but there is one remaining detail to work out: how they're converted.

We know that the 3D engine converts color components the following way:

if (in == 0) out = 0;
else out = in*2 + 1;

From there, the idea is to display identical colors from the 2D and 3D engines, side by side, and compare them. By doing it for each possible intensity (from 0 to 31), we can work out where they differ and infer how the 2D engine converts colors.

The result of this test is a little surprising. For all the intensities above 0, the colors differ.

... read more
A lot closer to a finished product
Even if still very far.

After a while, melonDS finally boots commercial games. Among my small game library, the compatibility rate is encouraging, even. Here are a few screenshots, for example:

Getting there took a while of implementing new features, but also bashing my head against obscure bugs that often turn out to come from silly little things.

As an example, a bug that prevented games from booting.

On ARMv4/v5, the LDR opcode has the particularity that if you read from an address that isn't word-aligned, it aligns the address, and rotates the word it read so that the LSB is the byte pointed by the original address. In melonDS, it was implemented the following way:

u32 val = ROR(cpu->DataRead32(offset), ((offset&0x3)<<3));

At first glance, looks alright, doesn't it? Except ROR() is a macro, defined as follows:

#define ROR(x, n) (((x) >> (n)) | ((x) << (32-(n))))

This basically ends up calling cpu->DataRead32() twice. This isn't a big deal when reading from RAM, it only wastes some CPU time, but the bug goes unnoticed. However, it has nasty side-effects when reading from I/O registers like the IPC FIFO.

Next up, aside from GPU-related work, were features like touchscreen or save memory.

... read more
Getting somewhere
melonDS has progressed nicely since the last post. To give you an idea:

melonDS running the DS firmware

It's got some graphics capabilities, even though those are quite limited. Rotated/scaled sprites, like those used for the clock up there, gave me some trouble, but I eventually got it working.

Speaking of the clock, it's frozen in time. I had to implement the RTC to get the firmware to actually boot instead of constantly entering "please enter time/date" mode, but for now, I hardcoded the time/date. The RTC is real fun to work with btw-- DS software talks to it by bitbanging a GPIO register. From the emulator's point of view, you get a series of zeros and ones which you must put back together to get data you can work with.

I also implemented proper-ish support for the DS cart hardware. This is quite the fun too. There's an initialization sequence done by the BIOS, and two different encryption methods are used. The BIOS starts by retrieving the ROM header and chip ID, then switches to Key1-encrypted command mode and retrieves the secure area (a protected part of the ROM not readable via the normal read command), and finally switches to Key2-encrypted command mode, under which the game will operate.

It is also worth noting that on actual carts, the first 2KB of the secure area are Key1 encrypted. The first 8 bytes are a double-encrypted identifier (string 'encryObj') that is used by the BIOS to verify whether the decryption was successful. However, all the DS ROM dumps out there have that 2KB block decrypted. Thus, we need to re-encrypt it for it to be loaded successfully.

Getting Key1 to work took a while (and uncovered a bug in the CPU core). Key1 is based on Blowfish and is the most complicated encryption algorithm used. Key2 is based on a XOR stream generated from two 39-bit registers, but it can be ignored, it is entirely implemented in hardware.

The really hacky part in the current implementation is how cart DMA is implemented. Cart DMA basically works by automatically transferring a word from the cart data output register to memory as soon as there's data ready. The DMA engine doesn't know how long the transfer is, it only knows to wait until there's data available, transfer it, then repeat.

When you take the lazy approach of making cart reads return data instantly, you may run into trouble when implementing cart DMA properly. A read from the cart data output register would advance the read pointer, and if DMA is enabled, perform a DMA transfer, which would trigger another read, and so on until the recursion overflows the stack.

... read more
So what's melonDS?
melonDS is a new emulator project. My goals for it are to do things right and fast. Time will tell how far we can get in that direction.

If you know me, I'm not new in the emulation scene. I'm responsible for lolSNES/blargSNES, among others. I'm not new in the DS scene either, I worked a lot on DeSmuME back in the days. Why I'm straying away from DeSmuME is not something I will get into here.

So here I am, writing my own emulator for the second time. The hardest part in starting an emulator project from zero is managing to build something that resembles an emulator. It takes a fair amount of work before you can start getting results.

To this day, melonDS has gotten over the initial stage and does give some results. Nothing actually works aside from the very simple ARMWrestler CPU test, but hey, it's a start. melonDS has a 'good enough' subset of the ARM instruction set implemented, as well as a few hardware features, so getting things to run is mostly a matter of implementing the rest of the DS hardware.

One thing I want to do is being able to boot from the BIOS, like an actual DS. I was unable to get it to work in DeSmuME back then, but manually loading a DS firmware and booting it (thus skipping the BIOS) did work.

The progress of melonDS in regard to this is encouraging. The BIOS loads the firmware into memory and boots it. The firmware gets to the point where it tries to use the IPC FIFO, which I haven't implemented yet. Interesting things ahead!

Of course, melonDS will later have the option to boot a game directly, like all the emulators out there do. But for the sake of accuracy, I want to be able to boot from the BIOS.

The holy grail would be wifi emulation, especially local multiplayer, which I could never get working in DeSmuME. Time will tell if that goal is achievable.