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In an earlier article I showed how reading from VRAM with the CPU can be very slow. It however turns out there there are ways to make it less slow.
The key to this are instructions with non-temporal hints, in particular VMOVNTDQA. The Intel Instruction Manual says the following about this instruction:
“MOVNTDQA loads a double quadword from the source operand (second operand) to the destination operand (first operand) using a non-temporal hint if the memory source is WC (write combining) memory type. For WC memory type, the nontemporal hint may be implemented by loading a temporary internal buffer with the equivalent of an aligned cache line without filling this data to the cache. Any memory-type aliased lines in the cache will be snooped and flushed. Subsequent MOVNTDQA reads to unread portions of the WC cache line will receive data from the temporary internal buffer if data is available. “ (Intel® 64 and IA-32 Architectures Software Developer’s Manual Volume 2)
This sounds perfect for our VRAM and WC System Memory buffers as we typically only read 16-bytes per instruction and this allows us to read entire cachelines at time.
It turns out that Mesa already implemented a streaming memcpy using these instructions so all we had to do was throw that into our benchmark and write a corresponding memcpy that does non-temporal stores to benchmark writing to these memory regions.
As a reminder, we look into three allocation types that are exposed by the amdgpu Linux kernel driver:
VRAM. This lives on the GPU and is mapped with Uncacheable Speculative Write Combining (USWC) on the CPU. This means that accesses from the CPU are not cached, but writes can be write-combined.
Cacheable system memory. This is system memory that has caching enabled on the CPU and there is cache snooping to ensure the memory is coherent between the CPU and GPU (up till the top level caches. The GPU caches do not participate in the coherence).
USWC system memory. This is system memory that is mapped with Uncacheable Speculative Write Combining on the CPU. This can lead to slight performance benefits compared to cacheable system memory due to lack of cache snooping.
Furthermore this still uses a RX 6800 XT + a 2990WX with 4 channel 3200 MT/s RAM.
| method (MiB/s) | VRAM | Cacheable System Memory | USWC System Memory |
|---|---|---|---|
| read via memcpy | 15 | 11488 | 137 |
| write via memcpy | 10028 | 18249 | 11480 |
| read via streaming memcpy | 756 | 6719 | 4409 |
| write via streaming memcpy | 10550 | 14737 | 11652 |
Using this memcpy implementation we get significantly better performance in uncached memory situations, 50x for VRAM and 26x for USWC system memory. If this is a significant bottleneck in your workload this can be a gamechanger. Or if you were using SDMA to avoid this hit, you might be able to do things at significantly lower latency. That said it is not at a level where it does not matter. For big copies using DMA can still be a significant win.
Note that I initially gave an explanation on why the non-temporal loads should be faster, but the increases in performance are significantly above what something that just fiddles with loading entire cachelines would achieve. I have not dug into the why of the performance increase.
I have been claiming DMA is faster for CPU readbacks of VRAM in both this article and the previous article on the topic. One might ask how fast DMA is then. To demonstrate this I benchmarked VRAM<->Cacheable System Memory copies using the SDMA hardware block on Radeon GPUs.
Note that there is a significant overhead per copy here due to submitting work to the GPU, so I will shows results vs copy size. The rate is measured while doing a wait after each individual copy and taking the wall clock time as these usecases tend to be latency sensitive and hence batching is not too interesting.
| copy size | copy from VRAM (MiB/s) | copy to VRAM (MiB/s) |
|---|---|---|
| 4 KiB | 62 | 63 |
| 16 KiB | 245 | 240 |
| 64 KiB | 953 | 1015 |
| 256 KiB | 3106 | 3082 |
| 1 MiB | 6715 | 7281 |
| 4 MiB | 9737 | 11636 |
| 16 MiB | 12129 | 12158 |
| 64 MiB | 13041 | 12975 |
| 256 MiB | 13429 | 13387 |
This shows that for reads DMA is faster than a normal memcpy at 4 KiB and faster than a streaming memcpy at 64 KiB. Of course one still needs to do their CPU access at that point, but at both these thresholds even with an additional CPU memcpy the total process should still be fast with DMA.
This question probably seems absurd. An unoptimized memcpy is a simple loop that copies bytes. How hard can that be? Well...
There's a fascinating thread on llvm-dev started by George Mitenkov proposing a new family of "byte" types. I found the proposal and discussion difficult to follow. In my humble opinion, this is because the proposal touches some rather subtle and underspecified aspects of LLVM IR semantics, and rather than address those fundamentals systematically, it jumps right into the minutiae of the instruction set. I look forward to seeing how the proposal evolves. In the meantime, this article is a byproduct of me attempting to digest the problem space.
Here is a fairly natural way to (attempt to) implement memcpy in LLVM IR:
define void @memcpy(i8* %dst, i8* %src, i64 %n) {
entry:
%dst.end = getelementptr i8, i8* %dst, i64 %n
%isempty = icmp eq i64 %n, 0
br i1 %isempty, label %out, label %loop
loop:
%src.loop = phi i8* [ %src, %entry ], [ %src.next, %loop ]
%dst.loop = phi i8* [ %dst, %entry ], [ %dst.next, %loop ]
%ch = load i8, i8* %src.loop
store i8 %ch, i8* %dst.loop
%src.next = getelementptr i8, i8* %src.loop, i64 1
%dst.next = getelementptr i8, i8* %dst.loop, i64 1
%done = icmp eq i8* %dst.next, %dst.end
br i1 %done, label %out, label %loop
out:
ret void
}
Unfortunately, the copy that is written to the destination is not a perfect copy of the source.
Hold on, I hear you think, each byte of memory holds one of 256 possible bit patterns, and this bit pattern is perfectly copied by the `load`/`store` sequence! The catch is that in LLVM's model of execution, a byte of memory can in fact hold more than just one of those 256 values. For example, a byte of memory can be poison, which means that there are at least 257 possible values. Poison is forwarded perfectly by the code above, so that's fine. The trouble starts because of pointer provenance.
From a machine perspective, a pointer is just an integer that is interpreted as a memory address.
For the compiler, alias analysis -- that is, the ability to prove that different pointers point at different memory addresses -- is crucial for optimization. One basic tool in the alias analysis toolbox is to recognize that if pointers point into different "memory objects" -- different stack or heap allocations -- then they cannot alias.
Unfortunately, many pointers are obtained via getelementptr (GEP) using dynamic (non-constant) indices. These dynamic indices could be such that the resulting pointer points into a different memory object than the base pointer. This makes it nearly impossible to determine at compile time whether two pointers point into the same memory object or not.
Which is why there is a rule which says (among other things) that if a pointer P obtained via GEP ends up going out-of-bounds and pointing into a different memory object than the pointer on which the GEP was based, then dereferencing P is undefined behavior even though the pointer's memory address is valid from the machine perspective.
As a corollary, a situation is possible in which there are two pointers whose underlying memory address is identical but whose provenance is different. In that case, it's possible that one of them can be dereferenced while dereferencing the other is undefined behavior.
This only makes sense if, in the formal semantics of LLVM IR, pointer values carry more information than just an integer interpreted as a memory address. They also carry provenance information, which is essentially the set of memory objects that can be accessed via this pointer and any pointers derived from it.
What is the provenance of a pointer that results from a load instruction? In a clean operational semantics, the load must derive this provenance from the values stored in memory.
If bytes of memory can only hold one of 256 bit patterns (or poison), that doesn't give us much to work with. We could say that the provenance of the pointer is "empty", meaning the pointer cannot be used to access any memory objects -- but that's clearly useless. Or we could say that the provenance of the pointer is "all", meaning the pointer (or pointers derived from it) can be freely used to access all memory objects, assuming the underlying address is adjusted appropriately. That isn't much better.[0]
Instead, we must say that -- as far as LLVM IR semantics are concerned -- each byte of memory holds pointer provenance information in addition to its i8 content. The provenance information in memory is written by pointer store, and pointer load uses it to reconstruct the original provenance of the loaded pointer.
What happens to provenance information in non-pointer load/store? A load can simply ignore the additional information in memory. For store, I see 3 possible choices:
1. Leave the provenance information that already happens to be in memory unmodified.
2. Set the provenance to "empty".
3. Set the provenance to "all".
Looking back at our attempt to implement memcpy, there is no choice which results in a perfect copy. All of the choices lose provenance information.
Without major changes to LLVM IR, only the last choice is potentially viable because it is the only choice that allows dereferencing pointers that are loaded from the memcpy destination.
Without major changes to LLVM IR, we can only implement a memcpy that loses provenance information during the copy.
So what? Alias analysis around memcpy and code like it ends up being conservative, but reasonable people can argue that this doesn't matter. The burden of evidence lies on whoever wants to make a large change here in order to improve alias analysis.
That said, we cannot just call it a day and go (or stay) home either, because there are related correctness issues in LLVM today, e.g. bug 37469 mentioned in the initial email of that llvm-dev thread.
Here's a simpler example of a correctness issue using our hand-coded memcpy:
define i32 @sample(i32** %pp) {
%tmp = alloca i32*
%pp.8 = bitcast i32** %pp to i8*
%tmp.8 = bitcast i32** %tmp to i8*
call void @memcpy(i8* %tmp.8, i8* %pp.8, i64 8)
%p = load i32*, i32** %tmp
%x = load i32, i32* %p
ret i32 %x
}
A transform that should be possible is to eliminate the memcpy and temporary allocation:
define i32 @sample(i32** %pp) {
%p = load i32*, i32** %pp
%x = load i32, i32* %p
ret i32 %x
}
This transform is incorrect because it introduces undefined behavior.
To see why, remember that this is the world where we agree that integer stores write an "all" provenance to memory, so %p in the original program has "all" provenance. In the transformed program, this may no longer be the case. If @sample is called with a pointer that was obtained through an out-of-bounds GEP whose resulting address just happens to fall into a different memory object, then the transformed program has undefined behavior where the original program didn't.
We could fix this correctness issue by introducing an unrestrict instruction which elevates a pointer's provenance to the "all" provenance:
define i32 @sample(i32** %pp) {
%p = load i32*, i32** %pp
%q = unrestrict i32* %p
%x = load i32, i32* %q
ret i32 %x
}
Here, %q has "all" provenance and therefore no undefined behavior is introduced.
I believe that (at least for address spaces that are well-behaved?) it would be correct to fold inttoptr(ptrtoint(x)) to unrestrict(x). The two are really the same.
For that reason, unrestrict could also be used to fix the above-mentioned bug 37469. Several folks in the bug's discussion stated the opinion that the bug is caused by incorrect store forwarding that should be weakened via inttoptr(ptrtoint(x)). unrestrict(x) is simply a clearer spelling of the same idea.
A natural thought at this point is that the situation could be improved by adding provenance information to integers. This is technically correct: our hand-coded memcpy would then produce a perfect copy of the memory contents.
However, we would get into serious trouble elsewhere because global value numbering (GVN) and similar transforms become incorrect: two integers could compare equal using the icmp instruction, but still be different because of different provenance. Replacing one by the other could result in miscompilation.
GVN is important enough that adding provenance information to integers is a no-go.
I suspect that the unrestrict instruction would allow us to apply GVN to pointers, at the cost of making later alias analysis more conservative and sprinkling unrestrict instructions that may inhibit other transforms. I have no idea what the trade-off is on that.
With all the above in mind, I can see the first-principles appeal of the proposed "byte" types. They allow us to represent the contents of memory accurately in SSA values, and so they fill a real gap in the expressiveness of LLVM IR.
That said, the software development cost of adding a whole new family of types to LLVM is very high, so it better be justified by more than just aesthetics.
Our hand-coded memcpy can be turned into a perfect copier with straightforward replacement of i8 by b8:
define void @memcpy(b8* %dst, b8* %src, i64 %n) {
entry:
%dst.end = getelementptr b8, b8* %dst, i64 %n
%isempty = icmp eq i64 %n, 0
br i1 %isempty, label %out, label %loop
loop:
%src.loop = phi b8* [ %src, %entry ], [ %src.next, %loop ]
%dst.loop = phi b8* [ %dst, %entry ], [ %dst.next, %loop ]
%ch = load b8, b8* %src.loop
store b8 %ch, b8* %dst.loop
%src.next = getelementptr b8, b8* %src.loop, i64 1
%dst.next = getelementptr b8, b8* %dst.loop, i64 1
%done = icmp eq b8* %dst.next, %dst.end
br i1 %done, label %out, label %loop
out:
ret void
}
Looking at the concrete choices made in the proposal, I disagree with some of them.
Memory should not be typed. In the proposal, storing an integer always results in different memory contents than storing a pointer (regardless of its provenance), and implicitly trying to mix pointers and integers is declared to be undefined behavior. In other words, a sequence such as:
store i64 %x, i64* %p
%q = bitcast i64* %p to i8**
%y = load i8*, i8** %q
... is undefined behavior under the proposal instead of being effectively inttoptr(%x). That seems fine for C/C++, but is it going to be fine for other frontends?
The corresponding distinction between bytes-as-integers and bytes-as-pointers complicates the proposal overall, e.g. it forces them to add a bytecast instruction.
Conversely, the benefits of the distinction are unclear to me. One benefit appears to be guaranteed non-aliasing between pointer and non-pointer memory accesses, but that is a form of type-based alias analysis which in LLVM should idiomatically be done via TBAA metadata.
So let's keep memory untyped, please.
Bitwise poison in byte values makes me really nervous due to the arbitrary deviation from how poison works in other types. I don't see any justification for it in the proposal. I can kind of see how one could be motivated by implementing memcpy with vector intrinsics operating on, for example, <8 x b32>, but a simpler solution would be to just use <32 x b8> instead. And if poison is indeed bitwise, then certainly pointer provenance would also have to be bitwise!
Finally, no design discussion is complete without a little bit of bike-shedding. I believe the name "byte" is inspired by C++'s std::byte, but given that types such as b256 are possible, this name would forever be a source of confusion. Naming is hard, and I think we should at least try to look for a better one. Let me kick off the brainstorming by suggesting we think of them as "memory content" values, because that's what they are. The types could be spelled m8, m32, etc. in IR assembly.
In the llvm-dev thread, Jeroen Dobbelaere points out work being done to introduce explicit `ptr_provenance` operands on certain instructions, in service of C99's restrict keyword. I haven't properly digested this work, but it inspired the thoughts of this section.
Values of the proposed byte types have both a bit pattern and a pointer provenance. Do we really need to have both pieces of information in the same SSA value? We could instead split them up into an integer bit pattern value and a pointer provenance value with an explicit provenance type. Loads of integers could read out the provenance information stored in memory and provide it as a secondary result. Similarly, stores of integers could accept the desired provenance to be stored in memory as a secondary data operand. This would allow us to write a perfect memcpy by replacing the core load/store sequence with something like:
%ch, %provenance = load_with_provenance i8, i8* %src
store_with_provenance i8 %ch, provenance %provenance, i8* %dst
The syntax and instruction names in the example are very much straw men. Don't take them too seriously, especially because LLVM IR doesn't currently allow multiple result values.
Interestingly, this split allows the derivation of pointer provenance to follow a different path than the calculation of the pointer's bit pattern. This in turn allows us in principle to perform GVN on pointers without being conservative for alias analysis.
One of the steps in bug 37469 is not quite GVN, but morally similar. Simplifying a lot, the original program sequence:
%ch1 = load i8, i8* %p1
%ch2 = load i8, i8* %p2
%eq = icmp eq i8 %ch1, %ch2
%ch = select i1 %eq, i8 %ch1, i8 %ch2
store i8 %ch, i8* %p3
... is transformed into:
%ch2 = load i8, i8* %p2
store i8 %ch2, i8* %p3
This is correct for the bit patterns being loaded and stored, but the program also indirectly relies on pointer provenance of the data. Of course, there is no pointer provenance information being copied here because i8 only holds a bit pattern. However, with the "byte" proposal, all the i8s would be replaced by b8s, and then the transform becomes incorrect because it changes the provenance information.
If we split the proposed use of b8 into a use of i8 and explicit provenance values, the original program becomes:
%ch1, %prov1 = load_with_provenance i8, i8* %p1
%ch2, %prov2 = load_with_provenance i8, i8* %p2
%eq = icmp eq i8 %ch1, %ch2
%ch = select i1 %eq, i8 %ch1, i8 %ch2
%prov = select i1 %eq, provenance %prov1, provenance %prov2
store_with_provenance i8 %ch, provenance %prov, i8* %p3
This could be transformed into something like:
%prov1 = load_only_provenance i8* %p1
%ch2, %prov2 = load_with_provenance i8, i8* %p2
%prov = merge provenance %prov1, %prov2
store_with_provenance i8 %ch2, provenance %prov, i8* %p3
... which is just as good for code generation but loses only very little provenance information.
Without major changes to LLVM IR, a perfect memcpy cannot be implemented because pointer provenance information is lost.
Nevertheless, one could still define the @llvm.memcpy intrinsic to be a perfect copy. This helps memcpys in the original source program be less conservative in terms of alias analysis. However, it also makes it incorrect to replace a memcpy loop idiom with a use of @llvm.memcpy: without adding unrestrict instructions, the replacement may introduce undefined behavior; and there is no way to bound the locations where such unrestricts may be needed.
We could augment @llvm.memcpy with an immediate argument that selects its provenance behavior.
In any case, one can argue that bug 37469 is really a bug in the loop idiom recognizer. It boils down to the details of how everything is defined, and unfortunately, these weird corner cases are currently underspecified in the LangRef.
We started with the question of whether memcpy can be implemented in LLVM IR. The answer is a qualified Yes. It is possible, but the resulting copy is imperfect because pointer provenance information is lost. This has surprising implications which in turn happen to cause real miscompilation bugs -- although those bugs could be fixed even without a perfect memcpy.
The "byte" proposal has a certain aesthetic appeal because it fixes a real gap in the expressiveness of LLVM IR, but its software engineering cost is large and I object to some of its details. There are also alternatives to consider.
The miscompilation bugs obviously need to be fixed, but they can be fixed much less intrusively, albeit at the cost of more conservative alias analysis in the affected places. It is not clear to me whether improving alias analysis justifies the more complex solutions.
I would like to understand better how all of this interacts with the C99 restrict work. That work introduces mechanisms for explicitly talking about pointer provenance in the IR, which may allow us to kill two birds with one stone.
In any case, this is a fascinating topic and discussion, and I feel like we're only at the beginning.
[0] We could also say that the loaded pointer's provenance is magically the memory object that happens to be at the referenced memory address. Either way, provenance would become a useless no-op in most cases. For example, mem2reg would have to insert unrestrict instructions (defined later) everywhere because pointers become effectively "unrestricted" when loaded from alloca'd memory.
TL;DR: Tag your GPT partitions with the right, descriptive partition types, and the world will become a better place.
A number of years ago we started the Discoverable Partitions Specification which defines GPT partition type UUIDs and partition flags for the various partitions Linux systems typically deal with. Before the specification all Linux partitions usually just used the same type, basically saying "Hey, I am a Linux partition" and not much else. With this specification the GPT partition type, flags and label system becomes a lot more expressive, as it can tell you:
/home/ partition or a root file system?)/etc/fstab)By embedding all of this information inside the GPT partition table
disk images become self-descriptive: without requiring any other
source of information (such as /etc/fstab) if you look at a
compliant GPT disk image it is clear how an image is put together and
how it should be used and mounted. This self-descriptiveness in
particular breaks one philosophical weirdness of traditional Linux
installations: the original source of information which file system
the root file system is, typically is embedded in the root file system
itself, in /etc/fstab. Thus, in a way, in order to know what the
root file system is you need to know what the root file system is. 🤯
🤯 🤯
(Of course, the way this recursion is traditionally broken up is by
then copying the root file system information from /etc/fstab into
the boot loader configuration, resulting in a situation where the
primary source of information for this — i.e. /etc/fstab — is
actually mostly irrelevant, and the secondary source — i.e. the copy
in the boot loader — becomes the configuration that actually matters.)
Today, the GPT partition type UUIDs defined by the specification have been adopted quite widely, by distributions and their installers, as well as a variety of partitioning tools and other tools.
In this article I want to highlight how the various tools the systemd project provides make use of the concepts the specification introduces.
But before we start with that, let's underline why tagging partitions with these descriptive partition type UUIDs (and the associated partition flags) is a good thing, besides the philosophical points made above.
Simplicity: in particular OS installers become simpler — adjusting
/etc/fstab as part of the installation is not necessary anymore,
as the partitioning step already put all information into place for
assembling the system properly at boot. i.e. installing doesn't
mean that you always have to get fdisk and /etc/fstab into
place, the former suffices entirely.
Robustness: since partition tables mostly remain static after
installation the chance of corruption is much lower than if the
data is stored in file systems (e.g. in /etc/fstab). Moreover by
associating the metadata directly with the objects it describes the
chance of things getting out of sync is reduced. (i.e. if you lose
/etc/fstab, or forget to rerun your initrd builder you still know
what a partition is supposed to be just by looking at it.)
Programmability: if partitions are self-descriptive it's much easier to automatically process them with various tools. In fact, this blog story is mostly about that: various systemd tools can naturally process disk images prepared like this.
Alternative entry points: on traditional disk images, the boot
loader needs to be told which kernel command line option root= to
use, which then provides access to the root file system, where
/etc/fstab is then found which describes the rest of the file
systems. Where precisely root= is configured for the boot loader
highly depends on the boot loader and distribution used, and is
typically encoded in a Turing complete programming language
(Grub…). This makes it very hard to automatically determine the
right root file system to use, to implement alternative entry points
to the system. By alternative entry points I mean other ways to boot
the disk image, specifically for running it as a systemd-nspawn
container — but this extends to other mechanisms where the boot
loader may be bypassed to boot up the system, for example qemu
when configured without a boot loader.
User friendliness: it's simply a lot nicer for the user looking at a partition table if the partition table explains what is what, instead of just saying "Hey, this is a Linux partition!" and nothing else.
Now that we cleared up the Why?, lets have a closer look how this is
currently used and exposed in systemd's various components.
If a disk image follows the Discoverable Partition Specification then
systemd-nspawn
has all it needs to just boot it up. Specifically, if you have a GPT
disk image in a file foobar.raw and you want to boot it up in a
container, just run systemd-nspawn -i foobar.raw -b, and that's it
(you can specify a block device like /dev/sdb too if you like). It
becomes easy and natural to prepare disk images that can be booted
either on a physical machine, inside a virtual machine manager or
inside such a container manager: the necessary meta-information is
included in the image, easily accessible before actually looking into
its file systems.
/etc/fstab or kernel command line root=If a disk image follows the specification in many cases you can remove
/etc/fstab (or never even install it) — as the basic information
needed is already included in the partition table. The
systemd-gpt-auto-generator
logic implements automatic discovery of the root file system as well
as all auxiliary file systems. (Note that the former requires an
initrd that uses systemd, some more conservative distributions do not
support that yet, unfortunately). Effectively this means you can boot
up a kernel/initrd with an entirely empty kernel command line, and the
initrd will automatically find the root file system (by looking for a
suitably marked partition on the same drive the EFI System Partition
was found on).
(Note, if /etc/fstab or root= exist and contain relevant
information they always takes precedence over the automatic logic. This
is in particular useful to tweaks thing by specifying additional mount
options and such.)
The
systemd-dissect
tool may be used to introspect and manipulate OS disk images that
implement the specification. If you pass the path to a disk image (or
block device) it will extract various bits of useful information from
the image (e.g. what OS is this? what partitions to mount?) and display it.
With the --mount switch a disk image (or block device) can be
mounted to some location. This is useful for looking what is inside
it, or changing its contents. This will dissect the image and then
automatically mount all contained file systems matching their GPT
partition description to the right places, so that you subsequently
could chroot into it. (But why chroot if you can just use systemd-nspawn? 😎)
The
systemd-dissect
tool also has two switches --copy-from and --copy-to which allow
copying files out of or into a compliant disk image, taking all
included file systems and the resulting mount hierarchy into account.
The
RootImage=
setting in service unit files accepts paths to compliant disk images
(or block device nodes), and can mount them automatically, running
service binaries directly off them (in chroot() style). In fact,
this is the base for the Portable
Service concept of systemd.
systemd provides various tools that can run operations provisioning
disk images in an "offline" mode. Specifically:
systemd-tmpfilesWith the --image= switch
systemd-tmpfiles
can directly operate on a disk image, and for example create all
directories and other inodes defined in its declarative configuration
files included in the image. This can be useful for example to set up
the /var/ or /etc/ tree according to such configuration before
first boot.
systemd-sysusersSimilar, the --image= switch of
systemd-sysusers
tells the tool to read the declarative system user specifications
included in the image and synthesizes system users from it, writing
them to the /etc/passwd (and related) files in the image. This is
useful for provisioning these users before the first boot, for example
to ensure UID/GID numbers are pre-allocated, and such allocations not
delayed until first boot.
systemd-machine-id-setupThe --image= switch of
systemd-machine-id-setup
may be used to provision a fresh machine ID into
/etc/machine-id
of a disk image, before first boot.
systemd-firstbootThe --image= switch of
systemd-firstboot
may be used to set various basic system setting (such as root
password, locale information, hostname, …) on the specified disk
image, before booting it up.
The
journalctl
switch --image= may be used to show the journal log data included in
a disk image (or, as usual, the specified block device). This is very
useful for analyzing failed systems offline, as it gives direct access
to the logs without any further, manual analysis.
The
systemd-repart
tool may be used to repartition a disk or image in an declarative and
additive way. One primary use-case for it is to run during boot on
physical or VM systems to grow the root file system to the disk size,
or to add in, format, encrypt, populate additional partitions at boot.
With its --image= switch it the tool may operate on compliant disk
images in offline mode of operation: it will then read the partition
definitions that shall be grown or created off the image itself, and
then apply them to the image. This is particularly useful in
combination with the --size= which allows growing disk images to the
specified size.
Specifically, consider the following work-flow: you download a
minimized disk image foobar.raw that contains only the minimized
root file system (and maybe an ESP, if you want to boot it on
bare-metal, too). You then run systemd-repart --image=foo.raw
--size=15G to enlarge the image to the 15G, based on the declarative
rules defined in the
repart.d/
drop-in files included in the image (this means this can grow the root
partition, and/or add in more partitions, for example for /srv or
so, maybe encrypted with a locally generated key or so). Then, you
proceed to boot it up with systemd-nspawn --image=foo.raw -b, making
use of the full 15G.
Disk images implementing this specifications can carry OS executables in one of three ways:
Only a root file system
Only a /usr/ file system (in which case the root file system is automatically picked as tmpfs).
Both a root and a /usr/file system (in which case the two are
combined, the /usr/ file system mounted into the root file system,
and the former possibly in read-only fashion`)
They may also contain OS executables for different architectures,
permitting "multi-arch" disk images that can safely boot up on
multiple CPU architectures. As the root and /usr/ partition type
UUIDs are specific to architectures this is easily done by including
one such partition for x86-64, and another for aarch64. If the
image is now used on an x86-64 system automatically the former
partition is used, on aarch64 the latter.
Moreover, these OS executables may be contained in different versions,
to implement a simple versioning scheme: when tools such as
systemd-nspawn or systemd-gpt-auto-generator dissect a disk image,
and they find two or more root or /usr/ partitions of the same type
UUID, they will automatically pick the one whose GPT partition label
(a 36 character free-form string every GPT partition may have) is the
newest according to
strverscmp()
(OK, truth be told, we don't use strverscmp() as-is, but a modified
version with some more modern syntax and semantics, but conceptually
identical).
This logic allows to implement a very simple and natural A/B update
scheme: an updater can drop multiple versions of the OS into separate
root or /usr/ partitions, always updating the partition label to the
version included there-in once the download is complete. All of the
tools described here will then honour this, and always automatically
pick the newest version of the OS.
When building modern OS appliances, security is highly relevant. Specifically, offline security matters: an attacker with physical access should have a difficult time modifying the OS in a way that isn't noticed. i.e. think of a car or a cell network base station: these appliances are usually parked/deployed in environments attackers can get physical access to: it's essential that in this case the OS itself sufficiently protected, so that the attacker cannot just mount the OS file system image, make modifications (inserting a backdoor, spying software or similar) and the system otherwise continues to run without this being immediately detected.
A great way to implement offline security is via Linux' dm-verity
subsystem: it allows to securely bind immutable disk IO to a single,
short trusted hash value: if an attacker manages to offline modify the
disk image the modified disk image won't match the trusted hash
anymore, and will not be trusted anymore (depending on policy this
then just result in IO errors being generated, or automatic
reboot/power-off).
The Discoverable Partitions Specification declares how to include
Verity validation data in disk images, and how to relate them to the file
systems they protect, thus making if very easy to deploy and work with
such protected images. For example systemd-nspawn supports a
--root-hash= switch, which accepts the Verity root hash and then
will automatically assemble dm-verity with this, automatically
matching up the payload and verity partitions. (Alternatively, just
place a .roothash file next to the image file).
The above already is a powerful tool set for working with disk images. However, there are some more areas I'd like to extend this logic to:
bootctlSimilar to the other tools mentioned above,
bootctl
(which is a tool to interface with the boot loader, and install/update
systemd's own EFI boot loader
sd-boot)
should learn a --image= switch, to make installation of the boot
loader on disk images easy and natural. It would automatically find
the ESP and other relevant partitions in the image, and copy the boot
loader binaries into them (or update them).
coredumpctlSimilar to the existing journalctl --image= logic the coredumpctl
tool should also gain an --image= switch for extracting coredumps
from compliant disk images. The combination of journalctl --image=
and coredumpctl --image= would make it exceptionally easy to work
with OS disk images of appliances and extracting logging and debugging
information from them after failures.
And that's all for now. Please refer to the specification and the man pages for further details. If your distribution's installer does not yet tag the GPT partition it creates with the right GPT type UUIDs, consider asking them to do so.
Thank you for your time.
We’ve all been there. No matter how 10x someone is or feels, everyone has had a moment where abruptly they say to themselves, HOW THE FUCK DO THREADS EVEN WORK?
This may be precipitated by any number of events, including, but not limited to:
I’m not going to say that I’ve been there recently.
I’m not going to say that it was today, nor am I going to state, on the record, that at least one existing zink-wip snapshot may or may not be affected by an issue which may or may not be on the above list.
I’m not going to say any of these things.
What I am going to do is talk about a new oom handler I’ve been working on to handle the dreaded spec@!opengl 1.1@streaming-texture-leak case from piglit.
This test is annoying in that it is effectively a test of a driver’s ability to throttle itself when an app is generating and using $infinity textures without ever explicitly triggering a flush.
In short, it’s:
for (i = 0; i < 5000; i++) {
glGenTextures(1, &texture);
glBindTexture(GL_TEXTURE_2D, texture);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, TEX_SIZE, TEX_SIZE, 0, GL_RGBA, GL_UNSIGNED_BYTE, tex_buffer);
piglit_draw_rect_tex(0, 0, piglit_width, piglit_height, 0, 0, 1, 1);
glDeleteTextures(1, &texture);
}
The textures are “deleted”, yes, but because they’re in use, the driver can’t actually delete them at this point of call, meaning that they can only truly be deleted once they are no longer in use by the GPU. At some iteration, this will begin to oom the GPU, and the driver will have to determine how to handle things.
At present, mainline zink uses a hammer-and-nail methodology that I came up with last year: the total amount of GPU memory in use by resources in a given cmdbuf is tracked, and that amount is tracked per-context. If the in-use context memory exceeds a threshold of the total VRAM, the driver stalls, thereby freeing up all the resources that are in use so they can be recycled into new ones.
There’s a number of problems with this approach, but the biggest one is that it fails to account for cases like a AAA game that just uses as much memory as it can in order to optimize performance/resolution/graphics. I discovered such a case some time ago while running Tomb Raider, and then I set out to improve things since it was costing me about 10% of my perf on the title screen.
The annoying part of this problem is that the piglit test is a very uncommon case, and it’s tricky to handle it in a way that doesn’t also impact other cases which appear similar but need to not get memory-clamped. As a result, it’s tough to really do anything based on “overall” memory usage.
In the end, what I decided on was using the per-cmdbuf memory usage counter to trigger a check for completed cmdbufs on submit, iterating over all the pending ones to check whether they’ve completed, resetting them and freeing associated resources when possible. This yields good memory reclaiming behavior for problem cases while leaving games like Tomb Raider untouched and definitely not deadlocking or anything like that.
I said I’d be blogging every day about some changes? And that was a month ago or however long it’s been? And we all had a good chuckle at the idea that I could blog every day like how things used to be?
Yeah, I remember that too.
Anyway, Bas still hasn’t blogged, so let’s check the blogenda:
I guess it’s that time of the week again because the schedule says it’s time to talk about this week’s (or whenever it was) major rewrite of zink’s queue handling. But first, only 90s kids will remember that time I blogged about a major queue rewrite and was excited to almost be hitting 70% of native performance.
A common use of GL for big games is using multiple GL contexts to parallelize work. There’s a lot of tricky restrictions for this, both on the app side and the driver side, but this is sort of the closest thing to multiple cmdbufs that GL provides.
We all recall how zink now uses a monotonic queue: upon commencing recording, each cmdbuf gets tagged with a 32bit integer id that doubles as a timeline semaphore id for fencing. The queue iterates, the cmdbuf counter increments, queue submission is done per-context in a thread, the GPU gets triangles, everyone is happy.
But how well does that work out with multiple contexts?
Pretty well, it turns out, as long as you’re using a Vulkan driver that doesn’t actually check to ensure you’re using monotonic ids for your timeline values. Let’s check out a totally hypothetical scenario that isn’t just Steam:
So far so good. But then we get past the “Checking for updates” window:
So now context B’s submit thread is dumping cmdbuf 4’s triangles into the GPU, then context A’s submit thread is also trying to dump cmdbuf 3’s triangles into the GPU, but the wait order for the timeline is still A -> B, meaning that the values are not monotonic.
Will any drivers care?
Magic 8-ball says no, no drivers care about this and everything still works fine. That’s cool and interesting, but probably it’d be better to not do that.
The problem here is two problems:
The first problem is easy to fix: just deduplicate the thread and move the struct member.
The second one is trickier because everything in zink relies on cmdbufs getting an id as soon as they become active. This is done so that any resources written to by a given cmdbuf can have their usage tracked for synchronization purposes, e.g., reading back a buffer only after all its writes have landed.
The problem is further complicated by zink not having a great API barrier between directly accessing the “usage” for a resource and the value itself, by which I mean parts of the codebase directly reading the integer value vs having an API to wrap it; the latter would enable replacing the mechanism with whatever I wanted, so I decided to start by creating such a wrapper based on this:
struct zink_batch_usage {
uint32_t usage;
bool unflushed;
};
This is the existing struct zink_batch_usage but now with a bool value indicating that this cmdbuf is yet to be flushed. Each cmdbuf batch now has this sub-struct inlined onto it, and resources in zink can take references (pointers) to a specific cmdbuf’s usage struct. Because batches are never destroyed, this means the wrapper API can always dereference the struct to determine how to synchronize the usage: if it’s unflushed, it can flush or sync the flush thread; if it’s real, pending usage, it can safely wait on that usage as a timeline value and guarantee monotonic ordering.
bool
zink_screen_usage_check_completion(struct zink_screen *screen, const struct zink_batch_usage *u)
{
if (!zink_batch_usage_exists(u))
return true;
if (zink_batch_usage_is_unflushed(u))
return false;
return zink_screen_batch_id_wait(screen, u->usage, 0);
}
bool
zink_batch_usage_check_completion(struct zink_context *ctx, const struct zink_batch_usage *u)
{
if (!zink_batch_usage_exists(u))
return true;
if (zink_batch_usage_is_unflushed(u))
return false;
return zink_check_batch_completion(ctx, u->usage);
}
void
zink_batch_usage_wait(struct zink_context *ctx, const struct zink_batch_usage *u)
{
if (!zink_batch_usage_exists(u))
return;
if (zink_batch_usage_is_unflushed(u))
zink_fence_wait(&ctx->base);
else
zink_wait_on_batch(ctx, u->usage);
}
Now things render exactly the same, but with a truly monotonic queue underneath that’s conformant to specifications.
As the President of the GNOME Foundation Board of Directors, I’m really pleased to see the number and breadth of candidates we have for this year’s election. Thank you to everyone who has submitted their candidacy and volunteered their time to support the Foundation. Allan has recently blogged about how the board has been evolving, and I wanted to follow that post by talking about where the GNOME Foundation is in terms of its strategy. This may be helpful as people consider which candidates might bring the best skills to shape the Foundation’s next steps.
Around three years ago, the Foundation received a number of generous donations, and Rosanna (Director of Operations) gave a presentation at GUADEC about her and Neil’s (Executive Director, essentially the CEO of the Foundation) plans to use these funds to transform the Foundation. We would grow our activities, increasing the pace of events, outreach, development and infrastructure that supported the GNOME project and the wider desktop ecosystem – and, crucially, would grow our funding to match this increased level of activity.
I think it’s fair to say that half of this has been a great success – we’ve got a larger staff team than GNOME has ever had before. We’ve widened the GNOME software ecosystem to include related apps and projects under the GNOME Circle banner, we’ve helped get GTK 4 out of the door, run a wider-reaching program in the Community Engagement Challenge, and consistently supported better infrastructure for both GNOME and the Linux app community in Flathub.
Aside from another grant from Endless (note: my employer), our fundraising hasn’t caught up with this pace of activities. As a result, the Board recently approved a budget for this financial year which will spend more funds from our reserves than we expect to raise in income. Due to our reserves policy, this is essentially the last time we can do this: over the next 6-12 months we need to either raise more money, or start spending less.
For clarity – the Foundation is fit and well from a financial perspective – we have a very healthy bank balance, and a very conservative “12 month run rate” reserve policy to handle fluctuations in income. If we do have to slow down some of our activities, we will return to a “steady state” where our regular individual donations and corporate contributions can support a smaller staff team that supports the events and infrastructure we’ve come to rely on.
However, this isn’t what the Board wants to do – the previous and current boards were unanimous in their support of the idea that we should be ambitious: try to do more in the world and bring the benefits of GNOME to more people. We want to take our message of trusted, affordable and accessible computing to the wider world.
Typically, a lot of the activities of the Foundation have been very inwards-facing – supporting and engaging with either the existing GNOME or Open Source communities. This is a very restricted audience in terms of fundraising – many corporate actors in our community already support GNOME hugely in terms of both financial and in-kind contributions, and many OSS users are already supporters either through volunteer contributions or donating to those nonprofits that they feel are most relevant and important to them.
To raise funds from new sources, the Foundation needs to take the message and ideals of GNOME and Open Source software to new, wider audiences that we can help. We’ve been developing themes such as affordability, privacy/trust and education as promising areas for new programs that broaden our impact. The goal is to find projects and funding that allow us to both invest in the GNOME community and find new ways for FOSS to benefit people who aren’t already in our community.
Bringing it back to the election, I’d like to make clear that I see this – reaching the outside world, and finding funding to support that – as the main priority and responsibility of the Board for the next term. GNOME Foundation elections are a slightly unusual process that “filters” our board nominees by being existing Foundation members, which means that candidates already work inside our community when they stand for election. If you’re a candidate and are already active in the community – THANK YOU – you’re doing great work, keep doing it! That said, you don’t need to be a Director to achieve things within our community or gain the support of the Foundation: being a community leader is already a fantastic and important role.
The Foundation really needs support from the Board to make a success of the next 12-18 months. We need to understand our financial situation and the trade-offs we have to make, and help to define the strategy with the Executive Director so that we can launch some new programs that will broaden our impact – and funding – for the future. As people cast their votes, I’d like people to think about what kind of skills – building partnerships, commercial background, familiarity with finances, experience in nonprofit / impact spaces, etc – will help the Board make the Foundation as successful as it can be during the next term.
Specifically when it’s right outside my house and starts at 5:30AM with heavy machinery moving around.
With this said, I’m overdue for a post, and if I don’t set a good example by continuing to blog, why would anyone else? PS. BAS IT’S TIME.
Let’s see what’s on the agenda:
Looks like the next thing on the list is shader caching.
If you’re a long-time zink connoisseur, or if you’re just a casual reader of the blog, you know that zink has a shader cache.
But did you know that it doesn’t actually do anything at present?
Indeed, it was to my chagrin that, upon diving back into my slapdash pipeline cache implementation, I discovered that it was doing absolutely nothing. And this was a different nothing than that one time I didn’t actually pass the cache back to the vulkan driver! Yes, this was the nothing of I have a cache, why am I still compiling a hundred pipelines per frame? that the occasional lucky developer runs into every now and again.
But hwhy? Who would do such a thing?
Past recriminations aside, how does a shader/pipeline cache work, anyway? The gist of it in most Mesa drivers is this:
Thus a shader gets cached based on its text representation, enabling matching shaders across programs to use the same cache entry. After noting the success of Steam’s fossilize-based single file cache, I decided to use a single file for zink’s shader cache.
Oops.
The problem in this case was that I was just jamming all the pipelines into a single file, written once at program exit, and expecting the Vulkan driver to figure things out.
But what if the program didn’t exit cleanly? Or what if the write failed for some reason?
In short, the pipeline cache was mostly being written as a big block of garbage data. Not very useful.
Clearly I needed to reeducate myself in the ways of managing a cache, something that, in my former life as a GUI expert, I did routinely, but that I could no longer comprehend now that I only speak bitfields and command buffers.
I sought out the reclusive Timothy Arceri, a well-known sage in many esoteric, arcane arts, and, as I recall it, purveyor of great wisdom such as (paraphrased because the original text has been lost to the ages): We Both Know The GLSL Compiler Code For Uniform Blocks Is Unfathomable, Why Do You Insist On Attempting To Modify It?
The answers I received from my sojourn were swift and concise:
Stop that. Fossilize caching wasn’t meant to work that way.
My thoughts whirling, confidence badly shaken, I stumbled and fell from the summit of the mountain and dashed my heretical cache implementation against the solid foundation of git rebase -i.
What had I been thinking?
It was back to the charts for me, and this time I had a number of different goals:
Turns out this wasn’t actually as hard as expected?
Because we’re all big Vulkan adults, we do big Vulkan pipeline caches instead of wimpy OpenGL shader caches like so:
This has the added benefit of providing all the state variants for a given shader pipeline, saving additional lookups and ensuring that all the potential compiled pipelines are available at once. Furthermore, because there’s a (very) short delay between knowing what shaders are grouped together and needing the actual compiled pipeline, I can dump this all into a thread and handle the lookup while I update descriptors #2021 ASYNC THREADS++++++ BAYBEEEEEE.
But also, also, the one thing to absolutely not ever forget or else it’ll be really embarrassing is to ensure that you add your driver’s sha1 hash to your disk cache lookup, otherwise the whole thing explodes and @tarceri will frown down upon you.
I had planned to write more posts about some optimizations and whatever other cool stuff I’ve been working on.
I had planned to make more zink-wip snapshots.
I did shower; stop spamming frog emotes at me.
But I also encountered a bug so bizarre, so infruating, so esoteric, that I need to take a bit of a victory lap now that I’ve successfully corralled it. So let’s get into a real, vintage SGC blog post like we used to have back when SGC was a good blog and dive into what it took to fix a bug that took me four full days to resolve.
In the course of writing a suballocator, I ran zero tests, as is my way. When the coding fugue ended, I stumbled weakly to my local CI script and managed to hit the Enter key before collapsing into a restless sleep where I was chased by angry triangles. Things were different when I awoke; namely I now had a lot of failing tests.
But I fixed them, because that’s what driver developers do.
All except one, which I assumed was a flake after running it a few times and seeing no failures.
This was how I got to know the horror of dEQP-GLES3.functional.vertex_array_objects.all_attributes.
The test itself is awful to debug. It generates GL_MAX_VERTEX_ATTRIBS vertex attributes to use with the maximum number of vertex buffers and does a series of draws, verifying the results. Normal enough.
Except the attributes are completely randomized, even whether they’re enabled, so no two runs are the same.
And the bisect hit just right.
When a new bug is found with a driver, the first question is usually “Did this used to work?” followed quickly by “When did it start?” if the first answer was yes. The reason for this is that determining exactly when a problem began and what caused it to manifest gives the developer some vague starting point for determining what is happening to cause a bug.
So it was that I embarked on a bisect to figure out why dEQP-GLES3.functional.vertex_array_objects.all_attributes was suddenly failing. But obviously I couldn’t just bisect for this test. No, no, that would be far too easy.
This test only fails if run in conjunction with a series of other tests. Thus my deqp caselist file:
dEQP-GLES3.functional.vertex_array_objects.all_attributes
dEQP-GLES3.functional.vertex_arrays.single_attribute.first.byte.first6_offset1_stride2_quads256
dEQP-GLES3.functional.vertex_arrays.single_attribute.output_types.int.components2_ivec4_quads256
dEQP-GLES3.functional.vertex_arrays.single_attribute.usages.static_copy.stride32_fixed_quads1
The problem test always runs last, so something was clearly going on over time that was causing the failure. Armed with this knowledge, and so sure that this would end up being some trivial one-liner that I could fix in a few minutes, I set up my startpoint and endpoint for the bisect and went to work.
Generally speaking, I assume every bug I find is going to be a zink bug. Just by the numbers, that’s usually the case, but then also it’s just always the case. It was therefore no surprise that my bisect landed on a certain commit:
commit 6b13e7cede95504ce8309744d8b9d83c7dbab7c9
Author: Mike Blumenkrantz <michael.blumenkrantz@gmail.com>
Date: Mon May 17 08:44:02 2021 -0400
try better map flags
diff --git a/src/gallium/drivers/zink/zink_resource.c b/src/gallium/drivers/zink/zink_resource.c
index 55f37380d9f..121f6f0076e 100644
--- a/src/gallium/drivers/zink/zink_resource.c
+++ b/src/gallium/drivers/zink/zink_resource.c
@@ -1201,7 +1201,7 @@ buffer_transfer_map(struct zink_context *ctx, struct zink_resource *res, unsigne
/* At this point, the buffer is always idle (we checked it above). */
usage |= PIPE_MAP_UNSYNCHRONIZED;
}
- } else if ((usage & PIPE_MAP_READ) && !(usage & PIPE_MAP_PERSISTENT)) {
+ } else if (((usage & PIPE_MAP_READ) && !(usage & PIPE_MAP_PERSISTENT)) || !res->obj->host_visible) {
assert(!(usage & (TC_TRANSFER_MAP_THREADED_UNSYNC | PIPE_MAP_THREAD_SAFE)));
if (usage & PIPE_MAP_DONTBLOCK) {
/* sparse/device-local will always need to wait since it has to copy */
@@ -1209,7 +1209,7 @@ buffer_transfer_map(struct zink_context *ctx, struct zink_resource *res, unsigne
return NULL;
if (!zink_resource_usage_check_completion(ctx, res, ZINK_RESOURCE_ACCESS_WRITE))
return NULL;
- } else if (!res->obj->host_visible) {
+ } else if (!res->obj->host_visible || res->base.b.usage != PIPE_USAGE_STAGING) {
trans->staging_res = pipe_buffer_create(&screen->base, PIPE_BIND_LINEAR, PIPE_USAGE_STAGING, box->x + box->width);
if (!trans->staging_res)
return NULL;
@@ -1218,8 +1218,12 @@ buffer_transfer_map(struct zink_context *ctx, struct zink_resource *res, unsigne
zink_copy_buffer(ctx, NULL, staging_res, res, box->x, box->x, box->width);
res = staging_res;
zink_fence_wait(&ctx->base);
- } else
- zink_resource_usage_wait(ctx, res, ZINK_RESOURCE_ACCESS_WRITE);
+ } else {
+ if (!(usage & PIPE_MAP_WRITE))
+ zink_resource_usage_wait(ctx, res, ZINK_RESOURCE_ACCESS_WRITE);
+ else
+ zink_resource_usage_wait(ctx, res, ZINK_RESOURCE_ACCESS_RW);
+ }
}
if (!ptr) {
As clearly explained by my laconic commit log, this patch aims to improve non-persistent buffer mappings by forcing non-staging resources to use a snooped staging resource. For more details on why this is desirable, check out this encyclopedia of wisdom on the topic, written by RADV co-founder and Commander Of The Rays, Bas Nieuwenhuizen.
But somehow this small patch was breaking the test, so I set out to investigate.
Once a problem area is identified, it’s usually helpful to try and isolate the exact hunks of a patch which cause the problem. In this case, I had three distinct and only vaguely-related hunks, so it was an ideal case for this strategy. The middle hunk ended up being the culprit:
@@ -1209,7 +1209,7 @@ buffer_transfer_map(struct zink_context *ctx, struct zink_resource *res, unsigne
return NULL;
if (!zink_resource_usage_check_completion(ctx, res, ZINK_RESOURCE_ACCESS_WRITE))
return NULL;
- } else if (!res->obj->host_visible) {
+ } else if (!res->obj->host_visible || res->base.b.usage != PIPE_USAGE_STAGING) {
trans->staging_res = pipe_buffer_create(&screen->base, PIPE_BIND_LINEAR, PIPE_USAGE_STAGING, box->x + box->width);
if (!trans->staging_res)
return NULL;
It seemed a bit odd to me, but nothing that stood out as impossible; perhaps there was some manner of issue with buffer copying offsets for setting up the staging resource, or some synchronization issue, or whatever. There were options, and I now knew that the problem was caused by setting up a staging buffer. Further prinfs revealed that this conditional was only hit for read access, so it was now narrowed down even further.
Was it a buffer offset problem with copying the data for the staging resource?
Well.
No.
As interesting as it would’ve been for that to have been the case, there’s zero chance that this one test case was invoking a magical offset that wasn’t also triggered in other cases. If the general buffer copying code here was broken, it was probably broken everywhere in zink, so there would’ve been many, many more failures. There was only this one case, however, and deeper investigation confirmed this, as I directly mapped both buffers and compared the data ranges, which matched.
Synchronization it was, then, and I can hear the disembodied voice of Dave Airlie now shouting “Barriers!” before vanishing off into the ether.
First, I tried adding more GPU stalls. Like, lots more. Like, so many that the test took minutes to complete. There was no change, however. Just for hahas, I even added some usleep calls around.
Still nothing.
At this point I was seriously stumped. By now I’d fully instrumented all of the buffer access codepaths with asserts to verify the mapped contents matched the real buffer contents in all cases, and none of the asserts were ever hit.
But if it wasn’t actually an issue with synchronizing the staging buffer, what could it be?
I decided to check the test with with ANV at this point, being the case that I always run CTS against lavapipe to avoid killing my session in case I’ve foolished and added some code which triggers hangs, and…
And the test passed with ANV.
This was a real thinker, so I went to get a second opinion from Bas and RADV. RADV told me that ANV didn’t know what it was talking about, and the test was definitely failing, so I went with that answer because it seemed more sane.
As a final idea, I did the truly unthinkable: I threw in a malloc call, allocated some host memory, and copied the map contents directly into that buffer.
And leaked it.
Yes, I know, I know, We Don’t Do That, but it was just this one time. Just a little bit. Just to see if I could valg—Of course valgrind crashes when running anything in lavapipe due to unimplemented instructions, so why did I bother?
There comes a time when saying We Need To Go Deeper isn’t just a meme. That time was now, and I was about to get, as they say in technical terms when such depth is approached, deep as fuck.
Continuing to experiment with my memory leaking, the conditional block in question had by now degenerated into spaghetti:
trans->staging_res = pipe_buffer_create(&screen->base, PIPE_BIND_LINEAR, PIPE_USAGE_STAGING, box->x + box->width);
if (!trans->staging_res)
return NULL;
struct zink_resource *staging_res = zink_resource(trans->staging_res);
trans->offset = staging_res->obj->offset;
uint8_t *p = map_resource(screen, res);
trans->data = malloc(box->x + box->width);
trans->data2 = malloc(box->x + box->width);
memset(trans->data, 0, box->x + box->width);
memset(trans->data2, 0, box->x + box->width);
memcpy(trans->data, p, box->x + box->width);
memcpy(trans->data2, p, box->x + box->width);
printf("SIZE NEEDED %u\n", box->x + box->width);
for (unsigned i = 0; i < box->x + box->width; i++) {
uint8_t *map = res->obj->map;
assert(trans->data[i] == trans->data2[i]);
assert(map[i] == trans->data2[i]);
printf("MAP[%u] = %u\n", i, trans->data2[i]);
}
//zink_copy_buffer(ctx, NULL, staging_res, res, box->x, box->x, MIN2(box->width + 4, res->base.b.width0-box->x));
//zink_copy_buffer(ctx, NULL, staging_res, res, box->x, box->x, box->width);
ptr = trans->data;
res = staging_res;
zink_fence_wait(&ctx->base);
Obviously I’m gonna double buffer my memory leak so I can verify that it’s not secretly being modified on unmap (it wasn’t), and then also verify that the data matches before returning the pointer. And print it all, of course, because if you can actually read your terminal when you reach this sort of depth in the course of a debugging session, probably you’re doing it wrong.
But the time had come to start applying hacks elsewhere: namely the test itself. Being a random test case made it impossible to figure out what was going on between runs, but I’d determined one thing of interest: no matter what, unless I returned the direct mapping for the buffer, the test failed.
Let’s see what Mr. Crowbar had to say about that though when I applied him to the CTS case:
diff --git a/modules/gles3/functional/es3fVertexArrayObjectTests.cpp b/modules/gles3/functional/es3fVertexArrayObjectTests.cpp
index 82578b1ce..e231c4b1a 100644
--- a/modules/gles3/functional/es3fVertexArrayObjectTests.cpp
+++ b/modules/gles3/functional/es3fVertexArrayObjectTests.cpp
@@ -765,14 +765,14 @@ void MultiVertexArrayObjectTest::init (void)
m_spec.buffers.push_back(shortCoordBuffer48);
m_spec.state.attributes.push_back(Attribute());
- m_spec.state.attributes[attribNdx].enabled = (m_random.getInt(0, 4) == 0) ? GL_FALSE : GL_TRUE;
- m_spec.state.attributes[attribNdx].size = m_random.getInt(2,4);
- m_spec.state.attributes[attribNdx].stride = 2*m_random.getInt(1, 3);
+ m_spec.state.attributes[attribNdx].enabled = GL_TRUE;
+ m_spec.state.attributes[attribNdx].size = (attribNdx % 2) + 2;
+ m_spec.state.attributes[attribNdx].stride = 2 * ((attribNdx % 2) + 1);
m_spec.state.attributes[attribNdx].type = GL_SHORT;
- m_spec.state.attributes[attribNdx].integer = m_random.getBool();
- m_spec.state.attributes[attribNdx].divisor = m_random.getInt(0, 1);
- m_spec.state.attributes[attribNdx].offset = 2*m_random.getInt(0, 2);
- m_spec.state.attributes[attribNdx].normalized = m_random.getBool();
+ m_spec.state.attributes[attribNdx].integer = attribNdx % 3 == 1;
+ m_spec.state.attributes[attribNdx].divisor = 0;
+ m_spec.state.attributes[attribNdx].offset = attribNdx % 5;
+ m_spec.state.attributes[attribNdx].normalized = attribNdx % 3 == 1;
m_spec.state.attributes[attribNdx].bufferNdx = attribNdx+1;
if (attribNdx == 0)
@@ -783,14 +783,14 @@ void MultiVertexArrayObjectTest::init (void)
}
m_spec.vao.attributes.push_back(Attribute());
- m_spec.vao.attributes[attribNdx].enabled = (m_random.getInt(0, 4) == 0) ? GL_FALSE : GL_TRUE;
- m_spec.vao.attributes[attribNdx].size = m_random.getInt(2,4);
- m_spec.vao.attributes[attribNdx].stride = 2*m_random.getInt(1, 3);
+ m_spec.vao.attributes[attribNdx].enabled = GL_TRUE;
+ m_spec.vao.attributes[attribNdx].size = (attribNdx % 2) + 2;
+ m_spec.vao.attributes[attribNdx].stride = 2 * ((attribNdx % 2) + 1);
m_spec.vao.attributes[attribNdx].type = GL_SHORT;
- m_spec.vao.attributes[attribNdx].integer = m_random.getBool();
- m_spec.vao.attributes[attribNdx].divisor = m_random.getInt(0, 1);
- m_spec.vao.attributes[attribNdx].offset = 2*m_random.getInt(0, 2);
- m_spec.vao.attributes[attribNdx].normalized = m_random.getBool();
+ m_spec.vao.attributes[attribNdx].integer = attribNdx % 3 == 1;
+ m_spec.vao.attributes[attribNdx].divisor = 0;
+ m_spec.vao.attributes[attribNdx].offset = attribNdx % 5;
+ m_spec.vao.attributes[attribNdx].normalized = attribNdx % 3 == 1;
m_spec.vao.attributes[attribNdx].bufferNdx = attribCount - attribNdx;
if (attribNdx == 0)
Now I had a consistently failing test (as long as I ran it with the other test cases so it didn’t feel too lonely and accidentally pass) with consistent data, and I was dumping it all to logs that I could compare if I returned the direct pointer for the map to legitimately pass the test.
Naturally the output data that I was printing matched. It’d be pretty weird if it didn’t considering all the asserts that I had in the code, right? Hah, yeah, that’d be… That’d be pretty weird, all right…
By this point I had determined that it was a specific range of buffer mappings causing the problem, specifically those sized between 50 and 100 bytes. I also knew that these buffers were being mapped by u_vbuf, also known colloquially as the hinterlands of Gallium, an obscure component used to handle translating unsupported vertex buffer formats.
Veteran Mesa developers reading along are going full sensiblechuckle.gif right now, but I’ll request that we continue our no spoiler policy.
If the buffer contents were the same as the mapped contents but the test was still failing, then there had to be a reason for that. I fumbled my way over to the vertex attribute translator and fingerpainted in a printf to dump the translated vertex attributes. This enabled me to diff between a good run and a bad run.
It was then that I made a bewildering discovery.
Any time I had a 96-byte buffer map, the attributes starting at offset 92 didn’t match in cases when the test failed.
This was another thinker, so I decided to enhance my memory leaks a bit to copy more buffer since this was all 4096-aligned and it wasn’t like I was going to be copying out of bounds. This was when things started to get really weird.
Returning a copy of the resquested 96 bytes of the buffer failed the test, but returning 100 bytes passed it.
Uh-oh.
Now that I took a closer look at those vertex attribs, I realized that the ones which were failing were the ones that were read from bytes 96 and 97 of the buffer. The buffer which only had 96 bytes mapped, meaning that only the range of [0..95] was valid…
Resolution. What I had tripped over was a buffer overrun, one that was undetectable through normal means because of reasons like:
Iteration on various fixes finally yielded a patch that was upstreamable; the crux of the problem here was that the stride of vertex attributes was being used to calculate the size of the region to map, but the stride only determines the number of bytes between elements, not their size. For example, if the stride was 4 bytes but the element was 8 bytes, the overrun would be 4 bytes for the last element. The solution was to calculate the offset of the last element being mapped, then add the size of the element using the attribute’s format block size, which guarantees that the last attribute won’t be truncated.
Fuck that bug.
So we are looking to hire quite a few people into the Desktop team currently. First of all we are looking to hire two graphics engineers to help us work on Linux Graphics drivers. The first of those two jobs is now online on the Red Hat jobs site. This is a job in our core graphics team focusing on RHEL, Fedora and upstream around the Intel, AMD and NVidia open source drivers. This is an opportunity to join a team of incredibly talented engineers working on everything from the graphics system of the Linux kernel and on the userspace bits like Vulkan, OpenGL and Wayland. The job is listed as Senior Engineer, but for the right candidate we have flexibility there. We also have flexibility for people who want to work remotely, so as long as there is a Red Hat office in your home country you can work remotely for us. The second job, which we hope to have up soon, will be looking more at ARM graphics and be tied to our automotive effort, but we will be looking at the applications for either position in combination so feel free to apply for the already listed job even if you are more interested in the second one as we will discuss both jobs with potential candidates.
The second job we have up is for – Software Engineer – GPU, Input and Multimedia which is also for joining our Graphics team. This job is targetted at our office in Brno, Czechia and is a great entry level position if you are interested in the field of graphics. The job listing can be found here and outlines the kind of things we want you to look at, but do expect initially your job will be focused on helping the rest of the team manage their backlog and then grow from there.
The last job we have online now is for the automotive team, where we are looking for someone at the Senior/Principal level to join our Infotainment team, working with car makers around issues related to multimedia and help identifying needs and gaps and then work with upstream communities to figure out how we can resolve those issues. The job is targeted at Madrid, Spain as it is where we hope to center some of the infotainment effort and it makes things easier in terms of hardware access and similar, but for the right candidate we might be open to looking for candidates wanting to work remote or in another Red Hat office. You can find this job listing here.
We expect to be posting further jobs for the infotainment team within a week or two, so I will update once they are up.
There’s no shortage of very smart people working on Mesa. One of those, aspiring benchmark-quadrupler Marek Olšák, had a novel idea some time ago: Could C++ function templates were used to optimize draw dispatch in driver?
The answer was yes, and so began what was probably five or ten minutes of furiously jamming brackets and braces into a C++ file in order to achieve the intended result. Let’s check out what’s going on here.
To start, the templates must be accessible from C, as this is what the driver is written in. The methodology here is simple: Generate the templates as an array of function pointers such that they can be accessed by indexing the arrays with the template values. Here’s what the code looks like:
template <chip_class GFX_VERSION, si_has_tess HAS_TESS, si_has_gs HAS_GS,
si_has_ngg NGG, si_has_prim_discard_cs ALLOW_PRIM_DISCARD_CS>
static void si_init_draw_vbo(struct si_context *sctx)
{
/* Prim discard CS is only useful on gfx7+ because gfx6 doesn't have async compute. */
if (ALLOW_PRIM_DISCARD_CS && GFX_VERSION < GFX7)
return;
if (NGG && GFX_VERSION < GFX10)
return;
sctx->draw_vbo[GFX_VERSION - GFX6][HAS_TESS][HAS_GS][NGG][ALLOW_PRIM_DISCARD_CS] =
si_draw_vbo<GFX_VERSION, HAS_TESS, HAS_GS, NGG, ALLOW_PRIM_DISCARD_CS>;
}
template <chip_class GFX_VERSION, si_has_tess HAS_TESS, si_has_gs HAS_GS>
static void si_init_draw_vbo_all_internal_options(struct si_context *sctx)
{
si_init_draw_vbo<GFX_VERSION, HAS_TESS, HAS_GS, NGG_OFF, PRIM_DISCARD_CS_OFF>(sctx);
si_init_draw_vbo<GFX_VERSION, HAS_TESS, HAS_GS, NGG_OFF, PRIM_DISCARD_CS_ON>(sctx);
si_init_draw_vbo<GFX_VERSION, HAS_TESS, HAS_GS, NGG_ON, PRIM_DISCARD_CS_OFF>(sctx);
si_init_draw_vbo<GFX_VERSION, HAS_TESS, HAS_GS, NGG_ON, PRIM_DISCARD_CS_ON>(sctx);
}
template <chip_class GFX_VERSION>
static void si_init_draw_vbo_all_pipeline_options(struct si_context *sctx)
{
si_init_draw_vbo_all_internal_options<GFX_VERSION, TESS_OFF, GS_OFF>(sctx);
si_init_draw_vbo_all_internal_options<GFX_VERSION, TESS_OFF, GS_ON>(sctx);
si_init_draw_vbo_all_internal_options<GFX_VERSION, TESS_ON, GS_OFF>(sctx);
si_init_draw_vbo_all_internal_options<GFX_VERSION, TESS_ON, GS_ON>(sctx);
}
static void si_init_draw_vbo_all_families(struct si_context *sctx)
{
si_init_draw_vbo_all_pipeline_options<GFX6>(sctx);
si_init_draw_vbo_all_pipeline_options<GFX7>(sctx);
si_init_draw_vbo_all_pipeline_options<GFX8>(sctx);
si_init_draw_vbo_all_pipeline_options<GFX9>(sctx);
si_init_draw_vbo_all_pipeline_options<GFX10>(sctx);
si_init_draw_vbo_all_pipeline_options<GFX10_3>(sctx);
}
static void si_invalid_draw_vbo(struct pipe_context *pipe,
const struct pipe_draw_info *info,
const struct pipe_draw_indirect_info *indirect,
const struct pipe_draw_start_count *draws,
unsigned num_draws)
{
unreachable("vertex shader not bound");
}
extern "C"
void si_init_draw_functions(struct si_context *sctx)
{
si_init_draw_vbo_all_families(sctx);
/* Bind a fake draw_vbo, so that draw_vbo isn't NULL, which would skip
* initialization of callbacks in upper layers (such as u_threaded_context).
*/
sctx->b.draw_vbo = si_invalid_draw_vbo;
sctx->blitter->draw_rectangle = si_draw_rectangle;
si_init_ia_multi_vgt_param_table(sctx);
}
This calls through a series of functions, ultimately reaching si_init_draw_vbo where a template is set to a member of the function pointer array based on the template parameters. Specialized functions can then be generated based on hardware type, pipeline shader presence, and more.
Once initialized, there’s an inline function used to set the current function pointer:
static inline void si_select_draw_vbo(struct si_context *sctx)
{
sctx->b.draw_vbo = sctx->draw_vbo[sctx->chip_class - GFX6]
[!!sctx->shader.tes.cso]
[!!sctx->shader.gs.cso]
[sctx->ngg]
[si_compute_prim_discard_enabled(sctx)];
assert(sctx->b.draw_vbo);
}
Thus the parameters are pulled directly from the context, and the function can be called whenever the draw function pointer needs to be updated, such as when new shaders are bound or primitive discard is enabled.
The result is that now the draw dispatch can be fully optimized for the codepath required by the active hardware and graphics pipeline, reducing the CPU overhead and making the draw code the tiniest bit faster. For example, here’s just the top part of the templated function:
template <chip_class GFX_VERSION, si_has_tess HAS_TESS, si_has_gs HAS_GS, si_has_ngg NGG,
si_has_prim_discard_cs ALLOW_PRIM_DISCARD_CS>
static void si_draw_vbo(struct pipe_context *ctx,
const struct pipe_draw_info *info,
unsigned drawid_offset,
const struct pipe_draw_indirect_info *indirect,
const struct pipe_draw_start_count_bias *draws,
unsigned num_draws)
{
/* Keep code that uses the least number of local variables as close to the beginning
* of this function as possible to minimize register pressure.
*
* It doesn't matter where we return due to invalid parameters because such cases
* shouldn't occur in practice.
*/
struct si_context *sctx = (struct si_context *)ctx;
/* Recompute and re-emit the texture resource states if needed. */
unsigned dirty_tex_counter = p_atomic_read(&sctx->screen->dirty_tex_counter);
if (unlikely(dirty_tex_counter != sctx->last_dirty_tex_counter)) {
sctx->last_dirty_tex_counter = dirty_tex_counter;
sctx->framebuffer.dirty_cbufs |= ((1 << sctx->framebuffer.state.nr_cbufs) - 1);
sctx->framebuffer.dirty_zsbuf = true;
si_mark_atom_dirty(sctx, &sctx->atoms.s.framebuffer);
si_update_all_texture_descriptors(sctx);
}
unsigned dirty_buf_counter = p_atomic_read(&sctx->screen->dirty_buf_counter);
if (unlikely(dirty_buf_counter != sctx->last_dirty_buf_counter)) {
sctx->last_dirty_buf_counter = dirty_buf_counter;
/* Rebind all buffers unconditionally. */
si_rebind_buffer(sctx, NULL);
}
si_decompress_textures(sctx, u_bit_consecutive(0, SI_NUM_GRAPHICS_SHADERS));
si_need_gfx_cs_space(sctx, num_draws);
/* If we're using a secure context, determine if cs must be secure or not */
if (GFX_VERSION >= GFX9 && unlikely(radeon_uses_secure_bos(sctx->ws))) {
bool secure = si_gfx_resources_check_encrypted(sctx);
if (secure != sctx->ws->cs_is_secure(&sctx->gfx_cs)) {
si_flush_gfx_cs(sctx, RADEON_FLUSH_ASYNC_START_NEXT_GFX_IB_NOW |
RADEON_FLUSH_TOGGLE_SECURE_SUBMISSION, NULL);
}
}
if (HAS_TESS) {
struct si_shader_selector *tcs = sctx->shader.tcs.cso;
/* The rarely occuring tcs == NULL case is not optimized. */
bool same_patch_vertices =
GFX_VERSION >= GFX9 &&
tcs && info->vertices_per_patch == tcs->info.base.tess.tcs_vertices_out;
if (sctx->same_patch_vertices != same_patch_vertices) {
sctx->same_patch_vertices = same_patch_vertices;
sctx->do_update_shaders = true;
}
if (GFX_VERSION == GFX9 && sctx->screen->info.has_ls_vgpr_init_bug) {
/* Determine whether the LS VGPR fix should be applied.
*
* It is only required when num input CPs > num output CPs,
* which cannot happen with the fixed function TCS. We should
* also update this bit when switching from TCS to fixed
* function TCS.
*/
bool ls_vgpr_fix =
tcs && info->vertices_per_patch > tcs->info.base.tess.tcs_vertices_out;
if (ls_vgpr_fix != sctx->ls_vgpr_fix) {
sctx->ls_vgpr_fix = ls_vgpr_fix;
sctx->do_update_shaders = true;
}
}
Note that the hardware version parts are templated, as is the HAS_TESS conditional, enabling it to be skipped entirely if there’s no tessellation shader active.
With techniques like this, it’s no surprise that RadeonSI is the driver to beat in performance and low overhead. The latest zink-wip snapshots include similar work, skipping considerable amounts of the draw dispatch when possible, and (hopefully) lowering the CPU overhead of the draw dispatch.
TL;DR: don't use select() + bump the RLIMIT_NOFILE soft limit to
the hard limit in your modern programs.
The primary way to reference, allocate and pin runtime OS resources on
Linux today are file descriptors ("fds"). Originally they were used to
reference open files and directories and maybe a bit more, but today
they may be used to reference almost any kind of runtime resource in
Linux userspace, including open devices, memory
(memfd_create(2)),
timers
(timefd_create(2))
and even processes (with the new
pidfd_open(2)
system call). In a way, the philosophically skewed UNIX concept of
"everything is a file" through the proliferation of fds actually
acquires a bit of sensible meaning: "everything has a file
descriptor" is certainly a much better motto to adopt.
Because of this proliferation of fds, non-trivial modern programs tend to have to deal with substantially more fds at the same time than they traditionally did. Today, you'll often encounter real-life programs that have a few thousand fds open at the same time.
Like on most runtime resources on Linux limits are enforced on file
descriptors: once you hit the resource limit configured via
RLIMIT_NOFILE
any attempt to allocate more is refused with the EMFILE error —
until you close a couple of those you already have open.
Because fds weren't such a universal concept traditionally, the limit
of RLIMIT_NOFILE used to be quite low. Specifically, when the Linux
kernel first invokes userspace it still sets RLIMIT_NOFILE to a low
value of 1024 (soft) and 4096 (hard). (Quick explanation: the soft
limit is what matters and causes the EMFILE issues, the hard limit
is a secondary limit that processes may bump their soft limit to — if
they like — without requiring further privileges to do so. Bumping the
limit further would require privileges however.). A limit of 1024 fds
made fds a scarce resource: APIs tried to be careful with using fds,
since you simply couldn't have that many of them at the same
time. This resulted in some questionable coding decisions and
concepts at various places: often secondary descriptors that are very
similar to fds — but were not actually fds — were introduced
(e.g. inotify watch descriptors), simply to avoid for them the low
limits enforced on true fds. Or code tried to aggressively close fds
when not absolutely needing them (e.g. ftw()/nftw()), losing the
nice + stable "pinning" effect of open fds.
Worse though is that certain OS level APIs were designed having only
the low limits in mind. The worst offender being the BSD/POSIX
select(2)
system call: it only works with fds in the numeric range of 0…1023
(aka FD_SETSIZE-1). If you have an fd outside of this range, tough
luck: select() won't work, and only if you are lucky you'll detect
that and can handle it somehow.
Linux fds are exposed as simple integers, and for most calls it is
guaranteed that the lowest unused integer is allocated for new
fds. Thus, as long as the RLIMIT_NOFILE soft limit is set to 1024
everything remains compatible with select(): the resulting fds will
also be below 1024. Yay. If we'd bump the soft limit above this
threshold though and at some point in time an fd higher than the
threshold is allocated, this fd would not be compatible with
select() anymore.
Because of that, indiscriminately increasing the soft RLIMIT_NOFILE
resource limit today for every userspace process is problematic: as
long as there's userspace code still using select() doing so will
risk triggering hard-to-handle, hard-to-debug errors all over the
place.
However, given the nowadays ubiquitous use of fds for all kinds of resources (did you know, an eBPF program is an fd? and a cgroup too? and attaching an eBPF program to cgroup is another fd? …), we'd really like to raise the limit anyway. 🤔
So before we continue thinking about this problem, let's make the
problem more complex (…uh, I mean… "more exciting") first. Having just
one hard and one soft per-process limit on fds is boring. Let's add
more limits on fds to the mix. Specifically on Linux there are two
system-wide sysctls: fs.nr_open and fs.file-max. (Don't ask me why
one uses a dash and the other an underscore, or why there are two of
them...) On today's kernels they kinda lost their relevance. They had
some originally, because fds weren't accounted by any other
counter. But today, the kernel tracks fds mostly as small pieces of
memory allocated on userspace requests — because that's ultimately
what they are —, and thus charges them to the memory accounting done
anyway.
So now, we have four limits (actually: five if you count the memory accounting) on the same kind of resource, and all of them make a resource artificially scarce that we don't want to be scarce. So what to do?
Back in systemd v240 already (i.e. 2019) we decided to do something about it. Specifically:
Automatically at boot we'll now bump the two sysctls to their maximum, making them effectively ineffective. This one was easy. We got rid of two pretty much redundant knobs. Nice!
The RLIMIT_NOFILE hard limit is bumped substantially to 512K. Yay,
cheap fds! You may have an fd, and you, and you as well,
everyone may have an fd!
But … we left the soft RLIMIT_NOFILE limit at 1024. We weren't
quite ready to break all programs still using select() in 2019
yet. But it's not as bad as it might sound I think: given the hard
limit is bumped every program can easily opt-in to a larger number
of fds, by setting the soft limit to the hard limit early on —
without requiring privileges.
So effectively, with this approach fds should be much less scarce (at least for programs that opt into that), and the limits should be much easier to configure, since there are only two knobs now one really needs to care about:
Configure the RLIMIT_NOFILE hard limit to the maximum number of
fds you actually want to allow a process.
In the program code then either bump the soft to the hard limit, or
not. If you do, you basically declare "I understood the problem, I
promise to not use select(), drown me fds please!". If you don't
then effectively everything remains as it always was.
Apparently this approach worked, since the negative feedback on change was even scarcer than fds traditionally were (ha, fun!). We got reports from pretty much only two projects that were bitten by the change (one being a JVM implementation): they already bumped their soft limit automatically to their hard limit during program initialization, and then allocated an array with one entry per possible fd. With the new high limit this resulted in one massive allocation that traditionally was just a few K, and this caused memory checks to be hit.
Anyway, here's the take away of this blog story:
Don't use select() anymore in 2021. Use poll(), epoll,
iouring, …, but for heaven's sake don't use select(). It might
have been all the rage in the 1990s but it doesn't scale and is
simply not designed for today's programs. I wished the man page of
select() would make clearer how icky it is and that there are
plenty of more preferably APIs.
If you hack on a program that potentially uses a lot of fds, add
some simple
code
somewhere to its start-up that bumps the RLIMIT_NOFILE soft limit
to the hard limit. But if you do this, you have to make sure your
code (and any code that you link to from it) refrains from using
select(). (Note: there's at least one glibc NSS plugin using
select() internally. Given that NSS modules can end up being
loaded into pretty much any process such modules should probably
be considered just buggy.)
If said program you hack on forks off foreign programs, make sure to
reset the RLIMIT_NOFILE soft limit back to
1024
for them. Just because your program might be fine with fds >= 1024
it doesn't mean that those foreign programs might. And unfortunately
RLIMIT_NOFILE is inherited down the process tree unless explicitly
set.
And that's all I have for today. I hope this was enlightening.
It’s been a while.
I meant to blog. I meant to make new zink-wip snapshots. I meant to shower.
Look, none of us are perfect, and I’m just gonna get into some graphics so nobody remembers how this post started.
Boom, beautiful triangles. Look at that ultra smooth fps in mangohud. Protip: if you’re seeing weird flickering or misrenders in your app/game, try throwing mangohud in front of the zink bus to see if it fixes them.
So what has been going on for the past however since the last post?
In a word: lots.
Here’s the rundown.
The 20210517 zink-wip snapshot is the biggest one in history. I say this with no exaggeration.
Changes since the last snapshot include:
One way or another, this is going to feel like a new driver. Ideally I’ll be doing a post every day detailing one of the items on that list, but for now I’ll close the post by saying that zink should be 100%-1000% faster (not a typo) in most scenarios where it was previously much slower than native GL drivers.
Yeah, Big Triangle knows who we are now.
0xC521 One Of: WIFI, VarStoreInfo (VarOffset/VarName): 0x110, VarStore: 0x1, QuestionId: 0x1AB, Size: 1, Min: 0x0, Max 0x2, Step: 0x0 {05 91 53 03 54 03 AB 01 01 00 10 01 10 10 00 02 00}
0xC532 One Of Option: RTL8723, Value (8 bit): 0x1 (default) {09 07 55 03 10 00 01}
0xC539 One Of Option: AP6330, Value (8 bit): 0x2 {09 07 56 03 00 00 02}
0xC540 One Of Option: Disabled, Value (8 bit): 0x0 {09 07 01 04 00 00 00}
0xC547 End One Of {29 02}0x9560 One Of: USB OTG Support, VarStoreInfo (VarOffset/VarName): 0xDA, VarStore: 0x1, QuestionId: 0xA5, Size: 1, Min: 0x0, Max 0x1, Step: 0x0 {05 91 DE 02 DF 02 A5 00 01 00 DA 00 10 10 00 01 00}
0x9571 Default: DefaultId: 0x0, Value (8 bit): 0x1 {5B 06 00 00 00 01}
0x9577 One Of Option: PCI mode, Value (8 bit): 0x1 {09 07 E0 02 00 00 01}
0x957E One Of Option: Disabled, Value (8 bit): 0x0 {09 07 3B 03 00 00 00}
0x9585 End One Of {29 02}1. For some reason I decided that I did not have enough projects going on at the same time already and I started looking into improving support for the G15 family of keyboards. 2. I started studying the g15daemon code and did a build of it to check that it actually works. I believe making sure that you have a known-to-work codebase as a starting point, even if it is somewhat crufty and ugly, is important. This way you know you have code which speaks the right protocol and you can try to slowly morph it into what you want it to become (making small changes testing every step). Even if you decide to mostly re-implement from scratch, then you will likely use the old code as a protocol documentation and it is important to know it actually works. 3. There were number of things which I did not like about g15daemon: 3.1 It uses libusb, taking control of the entire USB-interface used for the gaming functionality away from the kernel. 3.2 As part of this it was not just dealing with the LCD, it also was acting as a dispatches for G-key key-presses. IMHO the key-press handling clearly belonged in the kernel. These keys are just extra keys, all macro functionality is handled inside software on the host/PC side. So as a kernel dev I found that these really should be handled as normal keys and emit normal evdev event with KEY_FOO codes from a /dev/input/event# kernel node. 3.3 It is a daemon, rather then a library; and most other code which would deal with the LCD such as lcdproc was a daemon itself too, so now we would have lcdproc's LCDd talking to g15daemon to get to the LCD which felt rather roundabout. So I set about tackling all of these 4. Kernel changes: I wrote a new drivers/hid/hid-lg-g15.c kernel driver: https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/drivers/hid/hid-lg-g15.c Which sends KEY_MACRO1 .. KEY_MACRO18, KEY_MACRO_PRESET1 .. KEY_MACRO_PRESET3, KEY_MACRO_RECORD_START, KEY_KBD_LCD_MENU1 .. KEY_KBD_LCD_MENU4 keypresses for all the special keys. Note this requires that the kernel HID driver is left attached to the USB interface, which required changes on the g15dameon/lcdproc side. This kernel driver also offers a /sys/class/leds/g15::kbd_backlight/ interface which allows controller the backlight intensity through e.g. GNOME kbd-backlight slider in the power pane of the control-center. It also offers a bunch of other LED interfaces under /sys/class/leds/ for controlling things like the LEDs under the M1 - M3 preset selection buttons. The idea here being that the kernel abstract the USB protocol for these gaming-kbd away and that a single userspace daemon for doing gaming kbd macro functionality can be written which will rely only on the kernel interfaces and will thus work with any kbd which has kernel support. 5. lcdproc changes 5.1 lcdproc already did have a g15 driver, which talked to g15daemon. So at first I started testing with this (at this point all my kernel work would not work, since g15daemon would take full control of the USB interface unbinding my kernel driver). I did a couple of bug-fixes / cleanups in this setup to get the code to a starting point where I could run it and it would not show any visible rendering bugs in any of the standard lcdproc screens 5.2 I wrote a little lcdproc helper library, lib_hidraw, which can be used by lcdproc drivers to open a /dev/hidraw device for them. The main feature is, you give the lib_hidraw_open() helper a list of USB-ids you are interested in; and it will then find the right /dev/hidraw# device node (which may be different every boot) and open it for you. 5.3 The actual sending of the bitmap to the LCD screen is quite simple, but it does need to be a very specific format. The format rendering is done by libg15render. So now it was time to replace the code talking to g15daemon with code to directly talk to the LCD through a /dev/hidraw# interface. I kept the libg15render dependency since that was fine. After a bit of refactoring, the actual change over to directly sending the data to the LCD was not that big. 5.4 The change to stop using the g15daemon meant that the g15 driver also lost support for detecting presses on the 4 buttons directly under the LCD which are meant for controlling the menu on the LCD. But now that the code is using /dev/hidraw# the kernel driver I wrote would actually work and report KEY_KBD_LCD_MENU1 .. KEY_KBD_LCD_MENU4 keypresses. So I did a bunch of cleanup / refactoring of lcdproc's linux_input driver and made it take over the reporting of those button presses. 5.5 I wanted everything to just work out of the box, so I wrote some udev rules which automatically generate a lcdproc.conf file configuring the g15 + linux_input drivers (including the key-mapping for the linux_input driver) when a G15 keyboard gets plugged in and the lcdproc.conf file does not exist yet. All this together means that users under Fedora, where I also packaged all this can now do "dnf install lcdproc", pluging their G15 keyboard and everything will just work.
In Turnips in the wild (Part 1) we walked through two issues, one in TauCeti Benchmark and the other in Genshin Impact. Today, I have an update about the one I didn’t have plan to fix, and a showcase of two remaining issues I met in Genshin Impact.
In the previous post I said that I’m not planning to fix the broken water effect since it relied on undefined behavior.
However, I was notified that same issue was fixed in OpenGL driver for Adreno (Freedreno) and the fix is rather easy. Even though for Vulkan it is clearly an undefined behavior, with other APIs it might not be so clear. Thus, given that we want to support translation from other APIs, there are already apps which rely on this behavior, and it would be just a bit more performant - I made a fix for it.
The issue was fixed by “tu: do not corrupt unwritten render targets (!10489)”
The login screen welcomes us with not-so-healthy colors:
And with a few failures to allocate registers in the logs. The failure to allocate registers isn’t good and may cause some important shader not to run, but let’s hope it’s not that. Thus, again, we should take a closer look at the frame.
Once the frame is loaded I’m staring at an empty image at the end of the frame… Not a great start.
Such things mostly happen due to a GPU hang. Since I’m inspecting frames on Linux I took a look at dmesg and confirmed the hang:
[drm:a6xx_irq [msm]] *ERROR* gpu fault ring 0 fence ...
Fortunately, after walking through draw calls, I found that the mis-rendering happens before the call which hangs. Let’s look at it:
Draw call right before
Draw call with the issue
It looks like some fullscreen effect. As in the previous case - the inputs are fine, the only image input is a depth buffer. Also, there are always uniforms passed to the shaders, but when there is only a single problematic draw call - they are rarely an issue (also they are easily comparable with the proprietary driver if I spot some nonsensical values among them).
Now it’s time to look at the shader, ~150 assembly instructions, nothing fancy, nothing obvious, and a lonely kill near the top. Before going into the most “fun” part, it’s a good idea to make sure that the issue is 99% in the shader. RenderDoc has a cool feature which allows to debug shader (its SPIRV code) at a certain fragment (or vertex, or CS invocation), it does the evaluation on CPU, so I can use it as some kind of a reference implementation. In our case the output between RenderDoc and actual shader evaluation on GPU is different:
Evaluation on CPU: color = vec4(0.17134, 0.40289, 0.69859, 0.00124)
On GPU: color = vec4(3.1875, 4.25, 5.625, 0.00061)
Knowing the above there is only one thing left to do - reduce the shader until we find the problematic instruction(s). Fortunately there is a proprietary driver which renders the scene correctly, therefor instead of relying on intuition, luck, and persistance - we could quickly bisect to the issue by editing and comparing the edited shader with a reference driver. Actually, it’s possible to do this with shader debugging in RenderDoc, but I had problems with it at that moment and it’s not that easy to do.
The process goes like this:
This way I bisected to this fragment:
_243 = clamp(_243, 0.0, 1.0);
_279 = clamp(_279, 0.0, 1.0);
float _290;
if (_72.x) {
_290 = _279;
} else {
_290 = _243;
}
color0 = vec4(_290);
return;
Writing _279 or _243 to color0 produced reasonable results, but writing _290 produced nonsense. The difference was only the presence of condition. Now, having a minimal change which reproduces the issue, it’s possible to compare native assembly.
Bad:
mad.f32 r0.z, c0.y, r0.x, c6.w
sqrt r0.y, r0.y
mul.f r0.x, r1.y, c1.z
(ss)(nop2) mad.f32 r1.z, c6.x, r0.y, c6.y
(nop3) cmps.f.ge r0.y, r0.x, r1.w
(sat)(nop3) sel.b32 r0.w, r0.z, r0.y, r1.z
Good:
(sat)mad.f32 r0.z, c0.y, r0.x, c6.w
sqrt r0.y, r0.y
(ss)(sat)mad.f32 r1.z, c6.x, r0.y, c6.y
(nop2) mul.f r0.y, r1.y, c1.z
add.f r0.x, r0.z, r1.z
(nop3) cmps.f.ge r0.w, r0.y, r1.w
cov.u r1.w, r0.w
(rpt2)nop
(nop3) add.f r0.w, r0.x, r1.w
By running them in my head I reasoned that they should produce the same results. Something works not as expected. After a bit more changes in GLSL, it became apparent that something wrong with clamp(x, 0, 1) which is translated into (sat) modifier for instructions. A bit more digging and I found out that hardware doesn’t understand saturation modifier being placed on sel. instruction (sel is a selection between two values based on third).
Disallowing compiler to place saturation on sel instruction resolved the bug:
Login screen after the fix
The issue was fixed by “ir3: disallow .sat on SEL instructions (!9666)”
The trees and grass are seem to be rendered incorrectly. After looking through the trace and not finding where they were actually rendered, I studied the trace on proprietary driver and found them. However, there weren’t any such draw calls on Turnip!
The answer was simple, shaders failed to compile due to the failure in a register allocation I mentioned earlier… The general solution would be an implementation of register spilling. However in this case there is a pending merge request that implements a new register allocator, which later would help us implement register spilling. With it shaders can now be compiled!
More Turnip adventures to come!
After a traumatic, tearful goodbye to weird glxgears which took more out of me than expected, I’m back and blogging again.
It’s been…
Well, I guess it’s been a while since my last post, huh.
So what’s happened since then?
Lots? Yeah, definitely lots. It’s May now. And there’s even been a new Mesa release since then.
Quick zink roundup in case you missed any of these:
Cool.
The truth is that I’ve been taking some time off from zink in a completely futile attempt to make progress on something else while zink-wip continues to land. Inspired by this ticket describing issues getting CS:GO working, I decided to tackle part of Mesa that I haven’t worked on much and that hasn’t seen much work in a long time:
PBOs.
Pixel Buffer Objects are used when an application needs to perform a transfer of an image from host memory to the GPU or vice versa. A PBO is said to be downloaded when it is copied from the GPU into a host memory buffer, and it is uploaded when it is copied from a memory buffer into GPU memory. PBO uploads are a common way to load assets from disk (e.g., textures), and PBO downloads are common for…ideally nothing performance related, but RPCS3 uses them in such a way.
Uploading of textures in Mesa can take a number of different codepaths depending on various factors using this priority chain:
The reason CS:GO takes forever to start with zink is because it performs texture uploads of formats which zink does not support, namely alpha and luminance formats that cannot be emulated in Vulkan, during startup in order to load assets onto the GPU. This hits the CPU copy path 100% of the time, which is actually going to be slower than using something like llvmpipe because GPU-based graphics drivers are not intended to be doing everything on the CPU.
I spent a while considering the problem at hand, then decided to start in the place where I could understand what was going on: namely texture downloads. In contrast to uploads, downloads have fewer and simpler codepaths to choose from:
So to effectively improve this with a new mechanism, all I had to do was meet two criteria:
There was also, of course, the additional checklist item of Don’t Be Slower Than The Existing Semi-Fastpath Implementation, but I figured I could get to that later.
The implementation I settled on, after much trial and error, was to set up a SSBO descriptor and then use the source texture as a sampler to texelFetch from in a compute shader. A small, vec4-sized constant buffer is passed to the shader, and then everything is done on the GPU to convert the image to the requested pixel format. The SSBO can then be copied to the output memory buffer, and boom, done.
It took some time to get right, but the results are already quite promising. Here’s some results from pbobench, a tool I’m working on to help measure PBO performance. At present, it populates a 1024x1024 pixel texture using GL_R32F data, then downloads (glGetTextureSubImage) it as fast as possible and measures the number of calls per second, iterating over a number of different formats and types for the download.
Here’s the latest results that I’ve run on IRIS using GL_PACK_ALIGNMENT==4 and GL_PACK_SWAP_BYTES==1 for variety.
32x32
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 1 | GL_R32F | GL_FLOAT | 458692 | 20171 |
| 2 | GL_RGBA8 | GL_UNSIGNED_BYTE | 22263 | 20857 |
| 3 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 22234 | 20211 |
| 4 | GL_RGBA4 | GL_UNSIGNED_BYTE | 22301 | 20247 |
| 5 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 22088 | 20324 |
| 6 | GL_RGBA8_SNORM | GL_BYTE | 22320 | 20315 |
| 7 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 22644 | 20094 |
| 8 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 23189 | 20229 |
| 9 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 23678 | 19763 |
| 10 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 23618 | 19914 |
| 11 | GL_RGBA16F | GL_HALF_FLOAT | 208212 | 19306 |
| 12 | GL_RGBA32F | GL_FLOAT | 231616 | 19411 |
| 13 | GL_RGBA16F | GL_FLOAT | 227953 | 18887 |
| 14 | GL_RGB8 | GL_UNSIGNED_BYTE | 22917 | 19691 |
| 15 | GL_RGB565 | GL_UNSIGNED_BYTE | 23000 | 20002 |
| 16 | GL_SRGB8 | GL_UNSIGNED_BYTE | 22852 | 20011 |
| 17 | GL_RGB8_SNORM | GL_BYTE | 26064 | 20006 |
| 18 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 24226 | 19813 |
| 19 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 140785 | 19755 |
| 20 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 221776 | 17852 |
| 21 | GL_R11F_G11F_B10F | GL_FLOAT | 193169 | 19660 |
| 22 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 18616 | 18715 |
| 23 | GL_RGB9_E5 | GL_HALF_FLOAT | 207255 | 18441 |
| 24 | GL_RGB9_E5 | GL_FLOAT | 221998 | 19171 |
| 25 | GL_RGB16F | GL_HALF_FLOAT | 228688 | 18704 |
| 26 | GL_RGB32F | GL_FLOAT | 215211 | 19294 |
| 27 | GL_RGB16F | GL_FLOAT | 233145 | 18858 |
| 28 | GL_RG8 | GL_UNSIGNED_BYTE | 21850 | 18832 |
| 29 | GL_RG8_SNORM | GL_BYTE | 19445 | 18902 |
| 30 | GL_RG16F | GL_HALF_FLOAT | 248270 | 18413 |
| 31 | GL_RG32F | GL_FLOAT | 270652 | 19426 |
| 32 | GL_RG16F | GL_FLOAT | 286874 | 18964 |
| 33 | GL_R8 | GL_UNSIGNED_BYTE | 22093 | 20270 |
| 34 | GL_R8_SNORM | GL_BYTE | 21951 | 20154 |
| 35 | GL_R16F | GL_HALF_FLOAT | 300217 | 19514 |
| 36 | GL_R16F | GL_FLOAT | 454349 | 19784 |
| 37 | GL_RGBA | GL_UNSIGNED_BYTE | 21023 | 19926 |
| 38 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 21408 | 19664 |
| 39 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 22183 | 19090 |
| 40 | GL_RGB | GL_UNSIGNED_BYTE | 21791 | 20054 |
| 41 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 23290 | 19164 |
| 42 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 21032 | 20300 |
| 43 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 21897 | 20565 |
| 44 | GL_ALPHA | GL_UNSIGNED_BYTE | 21941 | 20049 |
The 32x32 size is not very favorable for the new implementation. Drivers are already extremely optimized for small PBO operations, so at best, my work here manages to keep up with the existing codebase for some cases.
Let’s go up a power of two to 64x64.
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 45 | GL_R32F | GL_FLOAT | 187911 | 18895 |
| 46 | GL_RGBA8 | GL_UNSIGNED_BYTE | 21094 | 18852 |
| 47 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 20121 | 18515 |
| 48 | GL_RGBA4 | GL_UNSIGNED_BYTE | 19995 | 18532 |
| 49 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 20829 | 19453 |
| 50 | GL_RGBA8_SNORM | GL_BYTE | 21167 | 18914 |
| 51 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 5547 | 19544 |
| 52 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 5686 | 19762 |
| 53 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 5934 | 18229 |
| 54 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 5917 | 18035 |
| 55 | GL_RGBA16F | GL_HALF_FLOAT | 69373 | 17646 |
| 56 | GL_RGBA32F | GL_FLOAT | 66885 | 18507 |
| 57 | GL_RGBA16F | GL_FLOAT | 69091 | 17522 |
| 58 | GL_RGB8 | GL_UNSIGNED_BYTE | 5529 | 18198 |
| 59 | GL_RGB565 | GL_UNSIGNED_BYTE | 5489 | 19197 |
| 60 | GL_SRGB8 | GL_UNSIGNED_BYTE | 5735 | 19455 |
| 61 | GL_RGB8_SNORM | GL_BYTE | 6496 | 19538 |
| 62 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 5971 | 19152 |
| 63 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 40364 | 19262 |
| 64 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 76933 | 18650 |
| 65 | GL_R11F_G11F_B10F | GL_FLOAT | 67688 | 18642 |
| 66 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 4957 | 18894 |
| 67 | GL_RGB9_E5 | GL_HALF_FLOAT | 73775 | 17660 |
| 68 | GL_RGB9_E5 | GL_FLOAT | 69293 | 18703 |
| 69 | GL_RGB16F | GL_HALF_FLOAT | 74131 | 17808 |
| 70 | GL_RGB32F | GL_FLOAT | 67877 | 18735 |
| 71 | GL_RGB16F | GL_FLOAT | 68759 | 17787 |
| 72 | GL_RG8 | GL_UNSIGNED_BYTE | 21194 | 19150 |
| 73 | GL_RG8_SNORM | GL_BYTE | 20644 | 19174 |
| 74 | GL_RG16F | GL_HALF_FLOAT | 90086 | 19010 |
| 75 | GL_RG32F | GL_FLOAT | 88349 | 19285 |
| 76 | GL_RG16F | GL_FLOAT | 89450 | 19041 |
| 77 | GL_R8 | GL_UNSIGNED_BYTE | 21215 | 19813 |
| 78 | GL_R8_SNORM | GL_BYTE | 21280 | 19457 |
| 79 | GL_R16F | GL_HALF_FLOAT | 107419 | 19180 |
| 80 | GL_R16F | GL_FLOAT | 189485 | 19045 |
| 81 | GL_RGBA | GL_UNSIGNED_BYTE | 20784 | 19454 |
| 82 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 5645 | 19375 |
| 83 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 5625 | 19078 |
| 84 | GL_RGB | GL_UNSIGNED_BYTE | 5753 | 19196 |
| 85 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 5917 | 17889 |
| 86 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 5553 | 19014 |
| 87 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 21420 | 18528 |
| 88 | GL_ALPHA | GL_UNSIGNED_BYTE | 21506 | 19944 |
64x64 starts to show some interesting results, cases like GL_SRGB8 where the compute implementation has dominant performance.
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 89 | GL_R32F | GL_FLOAT | 55577 | 16096 |
| 90 | GL_RGBA8 | GL_UNSIGNED_BYTE | 17315 | 15264 |
| 91 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 17735 | 15541 |
| 92 | GL_RGBA4 | GL_UNSIGNED_BYTE | 17191 | 15486 |
| 93 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 17343 | 14831 |
| 94 | GL_RGBA8_SNORM | GL_BYTE | 17362 | 15710 |
| 95 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 1367 | 15981 |
| 96 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 1367 | 16372 |
| 97 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 1475 | 15181 |
| 98 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 1482 | 14789 |
| 99 | GL_RGBA16F | GL_HALF_FLOAT | 19254 | 14916 |
| 100 | GL_RGBA32F | GL_FLOAT | 18465 | 13109 |
| 101 | GL_RGBA16F | GL_FLOAT | 18141 | 13075 |
| 102 | GL_RGB8 | GL_UNSIGNED_BYTE | 1439 | 16143 |
| 103 | GL_RGB565 | GL_UNSIGNED_BYTE | 1441 | 16252 |
| 104 | GL_SRGB8 | GL_UNSIGNED_BYTE | 1407 | 16106 |
| 105 | GL_RGB8_SNORM | GL_BYTE | 1583 | 16071 |
| 106 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 1520 | 16246 |
| 107 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 10888 | 16137 |
| 108 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 22128 | 14779 |
| 109 | GL_R11F_G11F_B10F | GL_FLOAT | 18807 | 13986 |
| 110 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 1251 | 15138 |
| 111 | GL_RGB9_E5 | GL_HALF_FLOAT | 22464 | 14482 |
| 112 | GL_RGB9_E5 | GL_FLOAT | 18562 | 14075 |
| 113 | GL_RGB16F | GL_HALF_FLOAT | 22072 | 15038 |
| 114 | GL_RGB32F | GL_FLOAT | 18801 | 14100 |
| 115 | GL_RGB16F | GL_FLOAT | 18774 | 13864 |
| 116 | GL_RG8 | GL_UNSIGNED_BYTE | 18446 | 16890 |
| 117 | GL_RG8_SNORM | GL_BYTE | 18493 | 17353 |
| 118 | GL_RG16F | GL_HALF_FLOAT | 26391 | 15989 |
| 119 | GL_RG32F | GL_FLOAT | 25502 | 15230 |
| 120 | GL_RG16F | GL_FLOAT | 25498 | 15027 |
| 121 | GL_R8 | GL_UNSIGNED_BYTE | 18754 | 17213 |
| 122 | GL_R8_SNORM | GL_BYTE | 16275 | 17254 |
| 123 | GL_R16F | GL_HALF_FLOAT | 31097 | 16525 |
| 124 | GL_R16F | GL_FLOAT | 54923 | 16005 |
| 125 | GL_RGBA | GL_UNSIGNED_BYTE | 17905 | 15956 |
| 126 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 1434 | 16266 |
| 127 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 1462 | 16251 |
| 128 | GL_RGB | GL_UNSIGNED_BYTE | 1465 | 16370 |
| 129 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 1525 | 16550 |
| 130 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 1416 | 15919 |
| 131 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 18876 | 16872 |
| 132 | GL_ALPHA | GL_UNSIGNED_BYTE | 17523 | 16271 |
By the 128x128 texture size, the massive performance lead that the existing glGetTextureSubImage handling had has dwindled to 20-50% for some cases, while the compute shader is now outperforming by a factor of ten or more for other cases.
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 133 | GL_R32F | GL_FLOAT | 14768 | 8850 |
| 134 | GL_RGBA8 | GL_UNSIGNED_BYTE | 10980 | 9142 |
| 135 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 11034 | 9063 |
| 136 | GL_RGBA4 | GL_UNSIGNED_BYTE | 11104 | 9160 |
| 137 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 11196 | 9085 |
| 138 | GL_RGBA8_SNORM | GL_BYTE | 10843 | 9139 |
| 139 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 500 | 10001 |
| 140 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 496 | 9775 |
| 141 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 484 | 8868 |
| 142 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 508 | 8994 |
| 143 | GL_RGBA16F | GL_HALF_FLOAT | 5025 | 7952 |
| 144 | GL_RGBA32F | GL_FLOAT | 4731 | 6635 |
| 145 | GL_RGBA16F | GL_FLOAT | 4722 | 6519 |
| 146 | GL_RGB8 | GL_UNSIGNED_BYTE | 497 | 9356 |
| 147 | GL_RGB565 | GL_UNSIGNED_BYTE | 499 | 9181 |
| 148 | GL_SRGB8 | GL_UNSIGNED_BYTE | 479 | 9067 |
| 149 | GL_RGB8_SNORM | GL_BYTE | 784 | 9704 |
| 150 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 527 | 9569 |
| 151 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 1396 | 8938 |
| 152 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 5697 | 8283 |
| 153 | GL_R11F_G11F_B10F | GL_FLOAT | 4760 | 6599 |
| 154 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 444 | 8123 |
| 155 | GL_RGB9_E5 | GL_HALF_FLOAT | 5836 | 8305 |
| 156 | GL_RGB9_E5 | GL_FLOAT | 4782 | 6944 |
| 157 | GL_RGB16F | GL_HALF_FLOAT | 5669 | 8313 |
| 158 | GL_RGB32F | GL_FLOAT | 4759 | 6819 |
| 159 | GL_RGB16F | GL_FLOAT | 4779 | 6912 |
| 160 | GL_RG8 | GL_UNSIGNED_BYTE | 11772 | 10298 |
| 161 | GL_RG8_SNORM | GL_BYTE | 11771 | 10555 |
| 162 | GL_RG16F | GL_HALF_FLOAT | 6900 | 9324 |
| 163 | GL_RG32F | GL_FLOAT | 6601 | 7928 |
| 164 | GL_RG16F | GL_FLOAT | 6461 | 7965 |
| 165 | GL_R8 | GL_UNSIGNED_BYTE | 12249 | 10936 |
| 166 | GL_R8_SNORM | GL_BYTE | 12423 | 11080 |
| 167 | GL_R16F | GL_HALF_FLOAT | 8790 | 10254 |
| 168 | GL_R16F | GL_FLOAT | 15005 | 7751 |
| 169 | GL_RGBA | GL_UNSIGNED_BYTE | 11094 | 8086 |
| 170 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 506 | 9767 |
| 171 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 494 | 9790 |
| 172 | GL_RGB | GL_UNSIGNED_BYTE | 497 | 9689 |
| 173 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 532 | 9917 |
| 174 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 487 | 10353 |
| 175 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 12297 | 10944 |
| 176 | GL_ALPHA | GL_UNSIGNED_BYTE | 12310 | 10940 |
256x256 is the point at which the difference starts to become even more pronounced. The cases where the compute implementation is definitively worse are few and far between, and many of the cases in which it was previously worse are now neck and neck.
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 177 | GL_R32F | GL_FLOAT | 3739 | 3348 |
| 178 | GL_RGBA8 | GL_UNSIGNED_BYTE | 4533 | 3409 |
| 179 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 4327 | 3354 |
| 180 | GL_RGBA4 | GL_UNSIGNED_BYTE | 4609 | 3274 |
| 181 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 4520 | 3333 |
| 182 | GL_RGBA8_SNORM | GL_BYTE | 4296 | 3437 |
| 183 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 236 | 3614 |
| 184 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 237 | 3512 |
| 185 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 235 | 2715 |
| 186 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 230 | 3331 |
| 187 | GL_RGBA16F | GL_HALF_FLOAT | 1291 | 2694 |
| 188 | GL_RGBA32F | GL_FLOAT | 1127 | 1020 |
| 189 | GL_RGBA16F | GL_FLOAT | 1127 | 1000 |
| 190 | GL_RGB8 | GL_UNSIGNED_BYTE | 223 | 3648 |
| 191 | GL_RGB565 | GL_UNSIGNED_BYTE | 225 | 3550 |
| 192 | GL_SRGB8 | GL_UNSIGNED_BYTE | 227 | 3487 |
| 193 | GL_RGB8_SNORM | GL_BYTE | 358 | 3586 |
| 194 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 252 | 3567 |
| 195 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 661 | 3084 |
| 196 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 1509 | 3055 |
| 197 | GL_R11F_G11F_B10F | GL_FLOAT | 1164 | 1222 |
| 198 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 209 | 2636 |
| 199 | GL_RGB9_E5 | GL_HALF_FLOAT | 1499 | 2571 |
| 200 | GL_RGB9_E5 | GL_FLOAT | 1182 | 1234 |
| 201 | GL_RGB16F | GL_HALF_FLOAT | 1510 | 2955 |
| 202 | GL_RGB32F | GL_FLOAT | 1179 | 1112 |
| 203 | GL_RGB16F | GL_FLOAT | 1172 | 1247 |
| 204 | GL_RG8 | GL_UNSIGNED_BYTE | 5019 | 3572 |
| 205 | GL_RG8_SNORM | GL_BYTE | 5043 | 4201 |
| 206 | GL_RG16F | GL_HALF_FLOAT | 1796 | 3471 |
| 207 | GL_RG32F | GL_FLOAT | 1677 | 2701 |
| 208 | GL_RG16F | GL_FLOAT | 1668 | 2638 |
| 209 | GL_R8 | GL_UNSIGNED_BYTE | 5374 | 4084 |
| 210 | GL_R8_SNORM | GL_BYTE | 5409 | 2985 |
| 211 | GL_R16F | GL_HALF_FLOAT | 2222 | 880 |
| 212 | GL_R16F | GL_FLOAT | 3689 | 2904 |
| 213 | GL_RGBA | GL_UNSIGNED_BYTE | 4490 | 3179 |
| 214 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 220 | 3366 |
| 215 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 237 | 3405 |
| 216 | GL_RGB | GL_UNSIGNED_BYTE | 228 | 3392 |
| 217 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 253 | 3180 |
| 218 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 229 | 3763 |
| 219 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 5400 | 4099 |
| 220 | GL_ALPHA | GL_UNSIGNED_BYTE | 5473 | 3543 |
512x512 is even better for the compute-based implementation, which remains extremely consistent across nearly all cases. It now exhibits a commanding lead of almost 1500% for some cases, while at worst, it maintains a consistent rate and achieves only 60% of baseline performance for a few cases.
| # | Format | Type | calls/s current | calls/s compute |
|---|---|---|---|---|
| 221 | GL_R32F | GL_FLOAT | 831 | 711 |
| 222 | GL_RGBA8 | GL_UNSIGNED_BYTE | 839 | 724 |
| 223 | GL_RGB5_A1 | GL_UNSIGNED_BYTE | 856 | 707 |
| 224 | GL_RGBA4 | GL_UNSIGNED_BYTE | 831 | 644 |
| 225 | GL_SRGB8_ALPHA8 | GL_UNSIGNED_BYTE | 869 | 679 |
| 226 | GL_RGBA8_SNORM | GL_BYTE | 827 | 730 |
| 227 | GL_RGBA4 | GL_UNSIGNED_SHORT_4_4_4_4 | 77 | 709 |
| 228 | GL_RGB5_A1 | GL_UNSIGNED_SHORT_5_5_5_1 | 77 | 718 |
| 229 | GL_RGB10_A2 | GL_UNSIGNED_INT_2_10_10_10_REV | 75 | 664 |
| 230 | GL_RGB5_A1 | GL_UNSIGNED_INT_2_10_10_10_REV | 75 | 662 |
| 231 | GL_RGBA16F | GL_HALF_FLOAT | 304 | 550 |
| 232 | GL_RGBA32F | GL_FLOAT | 253 | 403 |
| 233 | GL_RGBA16F | GL_FLOAT | 253 | 358 |
| 234 | GL_RGB8 | GL_UNSIGNED_BYTE | 74 | 522 |
| 235 | GL_RGB565 | GL_UNSIGNED_BYTE | 74 | 594 |
| 236 | GL_SRGB8 | GL_UNSIGNED_BYTE | 74 | 618 |
| 237 | GL_RGB8_SNORM | GL_BYTE | 156 | 575 |
| 238 | GL_RGB565 | GL_UNSIGNED_SHORT_5_6_5 | 80 | 593 |
| 239 | GL_R11F_G11F_B10F | GL_UNSIGNED_INT_10F_11F_11F_REV | 160 | 585 |
| 240 | GL_R11F_G11F_B10F | GL_HALF_FLOAT | 353 | 489 |
| 241 | GL_R11F_G11F_B10F | GL_FLOAT | 282 | 366 |
| 242 | GL_RGB9_E5 | GL_UNSIGNED_INT_5_9_9_9_REV | 67 | 518 |
| 243 | GL_RGB9_E5 | GL_HALF_FLOAT | 352 | 488 |
| 244 | GL_RGB9_E5 | GL_FLOAT | 279 | 365 |
| 245 | GL_RGB16F | GL_HALF_FLOAT | 356 | 472 |
| 246 | GL_RGB32F | GL_FLOAT | 282 | 352 |
| 247 | GL_RGB16F | GL_FLOAT | 269 | 322 |
| 248 | GL_RG8 | GL_UNSIGNED_BYTE | 936 | 273 |
| 249 | GL_RG8_SNORM | GL_BYTE | 954 | 354 |
| 250 | GL_RG16F | GL_HALF_FLOAT | 434 | 494 |
| 251 | GL_RG32F | GL_FLOAT | 393 | 384 |
| 252 | GL_RG16F | GL_FLOAT | 392 | 284 |
| 253 | GL_R8 | GL_UNSIGNED_BYTE | 1398 | 624 |
| 254 | GL_R8_SNORM | GL_BYTE | 1415 | 630 |
| 255 | GL_R16F | GL_HALF_FLOAT | 535 | 530 |
| 256 | GL_R16F | GL_FLOAT | 819 | 490 |
| 257 | GL_RGBA | GL_UNSIGNED_BYTE | 861 | 504 |
| 258 | GL_RGBA | GL_UNSIGNED_SHORT_4_4_4_4 | 76 | 540 |
| 259 | GL_RGBA | GL_UNSIGNED_SHORT_5_5_5_1 | 78 | 685 |
| 260 | GL_RGB | GL_UNSIGNED_BYTE | 74 | 676 |
| 261 | GL_RGB | GL_UNSIGNED_SHORT_5_6_5 | 82 | 706 |
| 262 | GL_LUMINANCE_ALPHA | GL_UNSIGNED_BYTE | 75 | 825 |
| 263 | GL_LUMINANCE | GL_UNSIGNED_BYTE | 1431 | 997 |
| 264 | GL_ALPHA | GL_UNSIGNED_BYTE | 1399 | 962 |
1024x1024 is the true gauntlet for PBO downloads, and it’s really not something that is likely to be seen in many places. But pbobench covers it because why not, so here we are. The results here are much less pronounced just because the amount of time spent in memcpy on the CPU ends up being so large for both implmentations that the GPU doesn’t get much time to do work.
Improvements are ongoing for compute-accelerated PBOs, and performance continues to rise. I’m looking forward to tackling uploads next, as that should directly improve load times for GL-based games across the board.
As part of the ongoing saga of working for a company that has an interest in gaming, games have been played recently.
One of those games is Tomb Raider (2013), and until very recently it had some issues when run on zink:
Here we see the wild triangle in its native habitat, foraging for sustenance among its siblings.
All of that changed today, however, when I rebased zink-wip from a couple weeks ago and then hucked it back into the repo with a new snapshot name and zero testing.
I was subsequently informed that I had broken our beautiful triangle princess, and Senior Misrendering Connoisseur Witold Baryluk has provided us with actual gameplay footage with all settings set to EXTREME:
glxgears rendered on an Apple M1
After beginning a compiler for the Apple M1 GPU, the next step is to develop a graphics driver exercising the compiler. Since the last post two weeks ago, I’ve begun a Gallium driver for the M1, implementing much of the OpenGL 2.1 and ES 2.0 specifications. With the compiler and driver together, we’re now able to run OpenGL workloads like glxgears and scenes from glmark2 on the M1 with an open source stack. We are passing about 75% of the OpenGL ES 2.0 tests in the drawElements Quality Program used to establish Khronos conformance. To top it off, the compiler and driver are now upstreamed in Mesa!
Gallium is a driver framework inside Mesa. It splits drivers into frontends, like OpenGL and OpenCL, and backends, like Intel and AMD. In between, Gallium has a common caching system for graphics and compute state, reducing the CPU overhead of every Gallium driver. The code sharing, central to Gallium’s design, allows high-performance drivers to be written at a low cost. For us, that means we can focus on writing a Gallium backend for Apple’s GPU and pick up OpenGL and OpenCL support “for free”.
More sharing is possible. A key responsibility of the Gallium backend is to translate Gallium’s state objects into hardware packets, so we need a good representation of hardware packets. While packed bitfields can work, C’s bitfields have performance and safety (overflow) concerns. Hand-coded C structures lack pretty-printing needed for efficient debugging. Finally, while reverse-engineering, hand-coded C structures tend to accumulate random magic numbers in driver code, which is undesirable. These issues are not new; systems like Intel’s GenXML and Nouveau’s envytools solve them by allowing the hardware packets to be described as XML while all necessary C code is auto-generated. For Asahi, I’ve opted to use GenXML, providing a concise description of my reverse-engineering results and an ergonomic API for the driver.
The XML contains recently reverse-engineered packets, like those describing textures and samplers. Fortunately, these packets map closely to both Metal and Gallium, allowing a natural translation. Coupled with Dougall Johnson’s latest notes on texture instructions, adding texture support to the Gallium driver and NIR compiler was a cinch.
The resulting XML is somewhat smaller than that of other reverse-engineered drivers of similar maturity. As discussed in the previous post, Apple relies on shader code in lieu of fixed-function graphics hardware for tasks like vertex attribute fetch and blending. Apple’s design reduces the hardware surface area, in turn reducing the number of packets in the XML at the expense of extra driver code to produce the needed shader variants. Here is yet another win for code sharing: the most complex code needed is for blending and logic operations, for which Mesa already has lowering code. Mali (Panfrost) needs some blending lowered to shader code, and all Mesa drivers need advanced blending equations lowered (modes like overlay, colour dodge, and screen). As a result, it will be a simple task to wire in the “load tilebuffer to register” instruction and Mesa’s blending code and see a thousand more tests pass.
Although Apple culled a great deal of legacy functionality from their GPU, some features are retained to support older APIs like compatibility contexts of desktop OpenGL, even when the features are inaccessible from Metal. Index buffers and primitive types exhibit this phenomenon. In Metal, an application can draw using a 16-bit or 32-bit index buffer, selecting primitives like triangles and triangle strips, with primitive restart always enabled. Most graphics developers want to use this fast path; by only supporting the fast path, Metal prevents a game developer from accidentally introducing slow code. However, this limits our ability to implement Khronos APIs like OpenGL and Vulkan on top of the Apple hardware… or does it?
In addition to the subset supported by Metal, the Khronos APIs also support 8-bit index buffers, additional primitive types like triangle fans, and an option to disable primitive restart. True, some of this functionality is unnecessary. Real geometry usually requires more than 256 vertices, so 8-bit index buffers are a theoretical curiosity. Primitives like triangle fans can bring a hardware penalty relative to triangle strips due to poor cache locality while offering no generality over indexed triangles. Well-written apps generally require primitive restart, and it’s almost free for apps that don’t need it. Even so, real applications (and the Khronos conformance tests) do use these features, so we need to support them in our OpenGL and Vulkan drivers. The issue does not only affect us – drivers layered on top of Metal like MoltenVK struggle with these exact gaps.
If Apple left these features in the hardware but never wired them into Metal, we’d like to know. But clean room reverse-engineering the hardware requires observing the output of the proprietary driver and looking for patterns, so if the proprietary (Metal) driver doesn’t use the functionality, how can we ever know it exists?
This is a case for an underappreciated reverse-engineering technique: guesswork. Hardware designers are logical engineers. If we can understand how Apple approached the hardware design, we can figure out where these hidden features should be in the command stream. We’re looking for conspicuous gaps in our understanding of the hardware, like looking for black holes by observing the absence of light. Consider index buffers, which are configured by an indexed draw packet with a field describing the size. After trying many indexed draws in Metal, I was left with the following reverse-engineered fragment:
<enum name="Index size">
<value name="U16" value="1"/>
<value name="U32" value="2"/>
</enum>
<struct name="Indexed draw" size="32">
...
<field name="Index size" size="2" start="2:17" type="Index size"/>
...
</struct>If the hardware only supported what Metal supports, this fragment would be unusual. Note 16-bit and 32-bit index buffers are encoded as 1 and 2. In binary, that’s 01 and 10, occupying two different bits, so we know the index size is at least 2 bits wide. That leaves 00 (0) and 11 (3) as possible unidentified index sizes. Now observe index sizes are multiples of 8 bits and powers of two, so there is a natural encoding as the base-2 logarithm of the index size in bytes. This matches our XML fragment, since log2(16 / 8) = 1 and log2(32 / 8) = 2. From here, we make our leap of faith: if the hardware supports 8-bit index buffers, it should be encoded with value log2(8 / 8) = 0. Sure enough, if we try out this guess, we’ll find it passes the relevant OpenGL tests. Success.
Finding the missing primitive types works the same way. The primitive type field is 4-bits in the hardware, allowing for 16 primitive types to be encoded, while Metal only uses 5, leaving only 11 to brute force with the tests in hand. Likewise, few bits vary between an indexed draw of triangles (no primitive restart) and an indexed draw of triangle strips (with primitive restart), giving us a natural candidate for a primitive restart enable bit. Our understanding of the hardware is coming together.
One outstanding difficulty is ironically specific to macOS: the IOGPU interface with the kernel. Traditionally, open source drivers on Linux use simple kernel space drivers together with complex userspace drivers. The userspace (Mesa) handles all 3D state, and the kernel simply handles memory management and scheduling. However, macOS does not follow this model; the IOGPU kernel extension, common to all GPUs on macOS, is made aware of graphics state like surface dimensions and even details about mipmapping. Many of these mechanisms can be ignored in Mesa, but there is still an uncomfortably large volume of “magic” to interface with the kernel, like the memory mapping descriptors. The good news is many of these elements can be simplified when we write a Linux kernel driver. The bad news is that they do need to be reverse-engineered and implemented in Mesa if we would like native Vulkan support on Macs. Still, we know enough to drive the GPU from macOS… and hey, soon enough, we’ll all be running Linux on our M1 machines anyway :-)
As you may know, I’ve been working on VK-GL-CTS for some time now. VK-GL-CTS the Conformance Test Suite for Vulkan and OpenGL, a large collection of tests used to verify implementations of the Vulkan and OpenGL APIs work as intended by the specification. My work has been mainly focused on the Vulkan side of things as part of Igalia's ongoing collaboration with Valve.
Last year, Khronos released the official specification of the Vulkan ray tracing extensions and I had the chance to participate in the final stages of the process by improving test coverage and fixing bugs in existing CTS tests, which is work that continues to this day mixed with other types of tasks in my backlog.
As part of this effort I learned many bits of the new Vulkan Ray Tracing API and even provided some very minor feedback about the spec, which resulted in me being listed as contributor to the VK_KHR_acceleration_structure extension.
Now that the waters are a bit more calm, I wanted to give you a list of resources and a small overview of the main concepts behind the Vulkan version of ray tracing.
There are a few basic resources that can help you get acquainted with the new APIs.
The official Khronos blog published an overview of the ray tracing extensions that explains some of the basic concepts like acceleration structures, ray tracing pipelines (and what their different shader stages do) and ray queries.
Intel’s Jason Ekstrand gave an excellent talk about ray tracing in Vulkan in XDC 2020. I highly recommend you to watch it if you’re interested.
For those wanting to get their hands on some code, the Khronos official Vulkan Samples repository includes a basic ray tracing sample.
The official Vulkan specification text (warning: very large HTML document), while intimidating, is actually a good source to learn many new parts of the API. If you’re already familiar with Vulkan, the different sections about ray tracing and ray tracing pipelines are worth reading.
The basic idea of ray tracing, as a tool, is that you must be able to choose an arbitrary point in space as the ray origin and a direction vector, and ask your implementation if that ray intersects anything along the way given a minimum and maximum distance.
In a modern computer or console game the number of triangles present in a scene is huge, so you can imagine detecting intersections between them and your ray can be very expensive. The implementation typically needs to organize the scene geometry in a hierarchical tree-like structure that can be traversed more efficiently by discarding large amounts of geometry with some simple tests. That’s what an Acceleration Structure is.
Fortunately, you don’t have to organize the scene geometry yourself. Implementations are free to choose the best and most suitable acceleration structure format according to the underlying hardware. They will build this acceleration structure for you and give you an opaque handle to it that you can use in your app with the rest of the API. You’re only required to provide the long list of geometries making up your scene.
You may be thinking, and you’d be right, that building the acceleration structure must be a complex and costly process itself, and it is. For this reason, you must try to avoid rebuilding them completely all the time, in every frame of the app. This is why acceleration structures are divided in two types: bottom level and top level.
Bottom level acceleration structures (BLAS) contain lists of geometries and typically represent whole models in your scene: a building, a tree, an object, etc.
Top level acceleration structures (TLAS) contain lists of “pointers” to bottom level acceleration structures, together with a transformation matrix for each pointer.
In the diagram below, taken from Jason Ekstrand’s XDC 2020 talk[1], you can see the blue square representing the TLAS, the red squares representing BLAS and the purple squares representing geometries.
The whole idea behind this is that you may be able to build the bottom level acceleration structure for each model only once as long as the model itself does not change, and you will include this model in your scene one or more times. Each time, it will have an associated transformation matrix that will allow you to translate, rotate or scale the model without rebuilding it. So, in each frame, you may only have to rebuild the top level acceleration structure while keeping the bottom level ones intact. Other tricks you can use include rebuilding the top level acceleration structure in a reduced frame rate compared to the app, or using a simplified version of the world geometry when tracing rays instead of the more detailed model used when rendering the scene normally.
Acceleration structures, ray origins and direction vectors typically use world-space coordinates.
In its most basic form, you can access the ray tracing facilities of the implementation by using ray queries. Before ray tracing, Vulkan already had graphics and compute pipelines. One of the main components of those pipelines are shader programs: application-provided instructions that run on the GPU telling it what to do and, in a graphics pipeline, how to process geometry data (vertex shaders) and calculate the color of each pixel that ends up on the screen (fragment shaders).
When ray queries are supported, you can trace rays from those “classic” shader programs for any purpose. For example, to implement lighting effects in a fragment shader.
The full power of ray tracing in Vulkan comes in the form of a completely new type of pipeline, the ray tracing pipeline, that complements the existing compute and graphics pipelines.
Most Vulkan ray tracing tutorials, including the Khronos blog post I mentioned before, explain the basics of these pipelines, including the new shader stages (ray generation, intersection, any hit, closest hit, etc) and how they work together. They cover acceleration structure traversal for each ray and how that triggers execution of a particular shader program provided by your app. The image below, taken from the official Vulkan specification[2], contains the typical representation of this traversal process.
The main difference between the traditional graphics pipelines and ray tracing pipelines is the following one. If you’re familiar with the classic graphics pipelines, you know the app decides and has full control over what is being drawn at any moment. Your command stream usually looks like this.
Begin render pass (I’ll be using this depth buffer to discard overlapping geometry on the screen and the resulting pixels need to be written to this image)
Bind descriptor sets (I’ll be using these textures and data buffers)
Bind pipeline (This is how the whole process looks like, including the crucial part of shader programs: let me tell you what to do with each vertex and how to calculate the color of each resulting pixel)
Draw this
Draw that
Bind pipeline (I’ll be using different shader programs for the next draws, thank you)
Draw some more
Draw even more
Bind descriptor sets (The textures and other data will be different from now on)
Bind pipeline (The shaders will be different too)
Additional draws
Final draws (Almost there, buddy)
End render pass (I’m done)
Each draw command in the command stream instructs the GPU to draw an object and, because the app is recording that command, the app knows what that object is and the appropriate resources that need to be used to draw that object, including textures, data buffers and shader programs. Before recording the draw command, the app can prepare everything in advance and tell the implementation which shaders and resources will be used with the draw command.
In a ray tracing pipeline, the scene geometry is organized in an acceleration structure. When tracing a ray, you don’t know, in advance, which geometry it’s going to intersect. Each geometry may need a particular set of resources and even the shader programs may need to change with each geometry or geometry type.
For this reason, ray tracing APIs need you to create a Shader Binding Table or SBT for short. SBTs represent (potentially) large arrays of shaders organized in shader groups, where each shader group has a handle that sits in a particular position in the array. The implementation will access this table, for example, when the ray hits a particular piece of geometry. The index it will use to access this table or array will depend on several parameters. Some of them come from the ray tracing command call in a ray generation shader, and others come from the index of the geometry and instance data in the acceleration structure.
There’s a formula to calculate that index and, while it’s not very complex, it will determine the way you must organize your shader binding table so it matches your acceleration structure, which can be a bit of a headache if you’re new to the process.
I highly recommend to take a look at Will Usher’s Shader Binding Table Tutorial, which includes an interactive SBT builder tool that will let you get an idea of how things work and fit together.
The Shader Binding Table is complemented in Vulkan by a Shader Record Buffer. The concept is that entries in the Shader Binding Table don’t have a fixed size that merely corresponds to the size of a shader group handle identifying what to run when the ray hits that particular piece of geometry. Instead, each table entry can be a bit larger and you can put arbitrary data after each handle. That data block is called the Shader Record Buffer, and can be accessed from shader programs when they run. They may be used, for example, to store indices to resources and other data needed to draw that particular piece of geometry, so the shaders themselves don’t have to be completely unique per geometry and can be reused more easily.
As you can see, ray tracing can be more complex than usual but it’s a very powerful tool. I hope the basic explanations and resources I linked above help you get to know it better. Happy hacking!
RIP weird glxgears 2018-2021.
The Meson Build System provides support for running on Microsoft Windows, including support for Microsoft Visual Studio C++. GitHub Actions provides public access to CI machines running Microsoft Windows. But trying to tie both together is not as straightforward as it sounds.
Sometimes you stumble over a task you never thought you have to deal with. This story is about one of those times. In particular, I was faced with running CI tests for a simple C library on Microsoft Visual Studio C++ (MSVC). Gladly, GitHub already provides simple access to machines running Microsoft Windows Server 2016 and 2019, so this sounded like a straightforward task. Unfortunately, my infinite ignorance of anything Windows made this harder than it should have been.
The root of this problem is that the Meson Build System needs to run in the MSVC Developer Shell. This shell has all the necessary environment variables prepared for a particular install of MSVC. Since you can have multiple versions installed in parallel, Meson cannot know which install to use if run outside of such a shell. Unfortunately, GitHub Actions has no simple way to enter this shell. Therefore, running Meson on GitHub Actions will end up using GCC rather than MSVC, since this is what it detects by default in the GitHub Actions Environment. This is not what we wanted, so adjustments are needed.
Luckily, Microsoft provides a tool called
vswhere
which finds MSVC installs on a Windows system. We can use this to find the
required setup scripts and then import the environment variables into our
GitHub Actions setup. This tool is pre-deployed on GitHub Actions, so we can
simply invoke it to find a suitable MSVC install. From there on, we look for
DevShell.dll, which provides the required integration. We load it into
PowerShell and invoke the provided Enter-VsDevShell function. By comparing
our own environment variables before and after that call, we can extract the
changes and export them into the GitHub Actions environment. Thus,
the following workflow-steps will have access to those variables as well.
I plugged this into a re-usable GitHub Action using the new composite type. To use it in a GitHub Actions workflow, simply use:
- name: Prepare MSVC
uses: bus1/cabuild/action/msdevshell@v1
with:
architecture: x64
This queries the MSVC environment and exports it to your GitHub Actions job. Following steps will thus run as if in an MSVC Developer Shell. A full example is appended at the bottom, which shows how to get Meson to compile and test a project on MSVC for both Windows Server 2016 and 2019.
If you rather import the code into your own project, you can find it on GitHub. Note that this uses PowerShell syntax, so it might look alien to linux developers.
While this is only roughly 50 lines of PowerShell scripting, it still feels a bit too hacky. The Meson developers are aware of this, but so far no patches have found their way upstream. Lets hope that this workaround will one day be obsolete and Meson invokes vswhere itself.
Following a full example workflow:
name: Continuous Integration
on: [push, pull_request]
jobs:
ci-msvc:
name: CI with MSVC
runs-on: $
strategy:
matrix:
os: [windows-2016, windows-latest]
steps:
- name: Fetch Sources
uses: actions/checkout@v2
- name: Setup Python
uses: actions/setup-python@v2
with:
python-version: '3.x'
- name: Install Python Dependencies
run: pip install meson ninja
- name: Prepare MSVC
uses: bus1/cabuild/action/msdevshell@v1
with:
architecture: x64
- name: Prepare Build
run: meson setup build
- name: Run Build
run: meson compile -v -C build
- name: Run Test Suite
run: meson test -v -C build
Running games and benchmarks is much more exciting than trying to fix a handful of remaining synthetic tests. Turnip, which is an open-source Vulkan driver for recent Adreno GPUs, should already be capable of running real world applications, and they always have a way to break the driver in a new, unexpected ways.
The benchmark greeted me with this wonderful field which looked a little blocky:
It’s not a crash, it’s not a hang, there is something wrong either with textures or with a shader. So, let’s take a closer look at a frame. Here is the first major draw call which looks wrong:
Now, let’s take a look at textures used by the draw:
That’s a lot of textures! But all of them look fine; yes, there are some textures that look blocky, but these textures are just small, so nothing wrong here.
The next stop is the fragment shader, I recently implemented an extension which helps with that. VK_KHR_pipeline_executable_properties allows the reporting of additional information about shaders in a pipeline. In case of Turnip it is statistics about registers and assembly of the shader:
Excerpt from the problematic shader
sam.base0 (f32)(xy)r0.x, r0.z, a1.x ; no field 'HAS_SAMP', WARNING: unexpected bits[0:7] in #cat5-samp-s2en-bindless-a1: 0x6 vs 0x0
Bingo! Usually when the issue is in a shader I have to either make educated guesses and/or reduce the shader until the issue is apparent. However, here we can immediately spot instructions with a warning. It may not be the cause of earth mis-rendering, but these instructions do sampling from textures, soooo.
After fixing their encoding, which was caused by a mistake in the XML definition, the ground is now rendered correctly:
After looking a bit more at the frame I saw that the same issue plagued all rock formations, and now it is gone too. The final fix could be seen at
ir3/isa,parser: fix encoding and parsing of bindless s2en SAM (!9628)
Now it’s time for a more heavyweight opponent - Genshin Impact, one of the most popular mobile games at the moment. Genshin Impact supports both GLES and Vulkan, and defaults to GLES on all but several devices. In any case, Vulkan could be enabled by editing a config file.
There are several mis-renderings in the game, however here I would describe the one which shows why it is important to use all available validation tooling for such complex API as Vulkan. Other mis-renderings would be a matter for the second post.
Proceeding to the gameplay and running around for a bit revealed a major artifacts on the water surface:
This one was a multiframe effect so I had to capture a trace of all frames and then find the one where issue began. The draw call I found:
It adds water to the first framebuffer and a lot of artifacts to the second one. Looking at the framebuffer configuration - I could see that the fragment shader doesn’t write to the second framebuffer. Is it allowed? Yes. Is the behavior defined? No! VK_LAYER_KHRONOS_validation warns us about it, if warnings are enabled:
UNASSIGNED-CoreValidation-Shader-InputNotProduced(WARN / SPEC): Validation Warning:
Attachment 1 not written by fragment shader; undefined values will be written to attachment
“undefined values will be written to attachment” may mean that nothing is written into it, like expected by the game, or that random values are written to the second attachment, like Turnip does. Such behavior should not be relied upon, so Turnip does not contradict the specification here and there is nothing to fix. Case closed.
More mis-renderings and investigations to come in the next post(s).
Last year I worked on implementing in Turnip the support for a HW feature present in Qualcomm Adreno GPUs: the low-resolution Z buffer (aka LRZ). This is a HW feature already supported in Freedreno, which is the open-source OpenGL driver for these GPUs.
Low-resolution Z buffer is very similar to a depth prepass that helps the HW avoid executing the fragment shader on those fragments that will be subsequently discarded by the depth test afterwards (Hidden surface removal). This feature comes with some limitations though, such as the fragment shader not being allowed to have side effects (writing to SSBOs, atomic operations, etc) among others.
The interesting part of this feature is that it allows the applications to submit the vertices in any order (saving CPU time that was otherwise used on ordering them) and the HW will process them in the binning pass as explained below, detecting which ones are occluded and giving an increase in performance in some specific use cases due to this.
To understand better how LRZ works, we need to talk a bit about tiled-based rendering. This is a way of rendering based on subdividing the framebuffer in tiles and rendering each tile separately. The advantage of this design is that the amount of memory and bandwidth is reduced compared to immediate mode rendering systems that draw the entire frame at once. Tile-based rendering is very popular on embedded GPUs, including Qualcomm Adreno.
Entering into more details, the graphics pipeline is divided into three different passes executed per tile of the frame.
 |
|---|
| Tiled-rendering architecture diagram. |
The binning pass. This pass processes the geometry of the scene and records in a table on which tiles a primitive will be rendered. By doing this, the HW only needs to render the primitives that affect a specific tile when is processed.
The rendering pass. This pass gets the rasterized primitives and executes all the fragment related processes of the pipeline (fragment shader execution, depth pass, stencil pass, blending, etc). Once it finishes, the resolve pass starts.
The resolve pass. It first resolves the tile buffer (GMEM) if it is multisample, and copy the final color and depth values for all tile pixels back to system memory. If it is the last tile of the framebuffer, it swap buffers and start the binning pass for next frame.
Where is LRZ used then? Well, in both binning and rendering passes. In the binning pass, it is possible to store the depth value of each vertex of the geometries of the scene in a buffer as the HW has that data available. That is the depth buffer used internally for LRZ. It has lower resolution as too much detail is not needed, which helps to save bandwidth while transferring its contents to system memory.
Thanks to LRZ, the rendering pass is only executed on the fragments that are going to be visible at the end. However, there are some limitations as mentioned before: if a fragment shader has collateral effects, such as writing SSBO, atomics, etc; or if blending is enabled, or if the fragment shader could modify the fragment’s depth… then LRZ cannot be used as the results may be wrong.
However, LRZ brings a couple of things on the table that makes it interesting. One is that applications don’t need to reorder their primitives before submission to be more efficient, that is done by the HW with LRZ automatically. Another one is performance improvements in some use cases. For example, imagine a fragment shader discards parts of fragments but it doesn’t have any other collateral effect otherwise. In that case, although we cannot do early depth testing, we can do early LRZ as we know that some fragments won’t pass a depth test even if they are not discarded by the fragment shader.
Talking about the LRZ implementation, I took Freedreno’s code as a starting point to implement LRZ on Turnip. After some months of work, it finally landed in Mesa master.
Last week, more patches related to LRZ landed in Mesa master: the ones fixing LRZ interactions with VK_EXT_extended_dynamic_state, as with this extension the application can change some states in command buffer time that could affect LRZ state and, therefore, we need to track them accordingly.
I also implemented some LRZ improvements that are currently under review also landed (thanks Eric Anholt!), such as the support to do early-LRZ-late-depth test that I mentioned before, which could bring a performance improvement in some applications.
 |
|---|
| Left: original vulkan tutorial demo implementation. Right: same demo modified to discard fragments with red component lower than 0.5f. |
For instance, I did some measurements in a vulkan-tutorial.com implementation of my own that I modified to discard a significant amount of fragments (see previous figure). This is one of the cases that early-LRZ-late-depth test helps to improve performance.
When running the modified demo with these patches, I found a performance improvement between 13-16%.
All this LRZ work was my first big contribution to this open-source reverse engineered driver! I don’t want to finish this post without thanking publicly Rob Clark for the original Freedreno implementation and his reviews of my work, as well as Jonathan Marek and Connor Abbott for their insightful reviews, advice and tips to make it working. Edited: Many thanks to Eric Anholt for his reviews in the last two patch series!
Happy hacking!
For the fun of it I decided to run some real apps on lavapipe.
Talos Principle is still rando crashing on startup, occasionally whatever magic value ends up being right in uninit memory and it suddenly runs fine.
I started Rise of the Tomb Raider, and it renders really slowly up to the menu.
Then I gave DOOM 2016 with the Vulkan renderer a go, and with a few lavapipe hacks to enable some feature bits, I managed to get it to load a game image. It's taking 5-6s per frame to render. However most of the slowness in the frame is the BPTC texture loading which is a path that I've done no tuning for so it definitely running very slowly. I think RoTR is also hitting that slow path so I guess I've some incentive to look at cleaning it up.
Shaded cube rendered on an Apple M1
After a few weeks of investigating the Apple M1 GPU in January, I was able to draw a triangle with my own open source code. Although I began dissecting the instruction set, the shaders there were specified as machine code. A real graphics driver needs a compiler from high-level shading languages (GLSL or Metal) to a native binary. Our understanding of the M1 GPU’s instruction set has advanced over the past few months. Last week, I began writing a free and open source shader compiler targeting the Apple GPU. Progress has been rapid: at the end of its first week, it can compile both basic vertex and fragment shaders, sufficient to render 3D scenes. The spinning cube pictured above has its shaders written in idiomatic GLSL, compiled with the nascent free software compiler, and rendered with native code like the first triangle in January. No proprietary blobs here!
Over the past few months, Dougall Johnson has investigated the instruction set in-depth, building on my initial work. His findings on the architecture are outstanding, focusing on compute kernels to complement my focus on graphics. Armed with his notes and my command stream tooling, I could chip away at a compiler.
The compiler’s design must fit into the development context. Asahi Linux aims to run a Linux desktop on Apple Silicon, so our driver should follow Linux’s best practices like upstream development. That includes using the New Intermediate Representation (NIR) in Mesa, the home for open source graphics drivers. NIR is a lightweight library for shader compilers, with a GLSL frontend and backend targets including Intel and AMD. NIR is an alternative to LLVM, the compiler framework used by Apple. Just because Apple prefers LLVM doesn’t mean we have to. A team at Valve famously rewrote AMD’s LLVM backend as a NIR compiler, improving performance. If it’s good enough for Valve, it’s good enough for me.
Supporting NIR as input does not dictate our compiler’s own intermediate representation, which reflects the hardware’s design. The instruction set of AGX2 (Apple’s GPU) has:
Each hardware property induces a compiler property:
Putting it together, a design for an AGX compiler emerges: a code generator translating NIR to an SSA-based intermediate representation, optimized by instruction combining passes, scheduled to minimize register pressure, register allocated while going out of SSA, scheduled again to maximize instruction-level parallelism, and finally packed to binary instructions.
These decisions reflect the hardware traits visible to software, which are themselves “shadows” cast by the hardware design. Investigating these traits offers insight into the hardware itself. Consider the register file. While every thread can access up to 256 half-word registers, there is a performance penalty: the more registers used, the fewer concurrent threads possible, since threads share a register file. The number of threads allowed in a given shader is reported in Metal as the maxTotalThreadsPerThreadgroup property. So, we can study the register pressure versus occupancy trade-off by varying the register pressure of Metal shaders (confirmed via our disassembler) and correlating with the value of maxTotalThreadsPerThreadgroup:
| Registers | Threads |
|---|---|
| <= 104 | 1024 |
| 112 | 896 |
| 120, 128 | 832 |
| 136 | 768 |
| 144 | 704 |
| 152, 160 | 640 |
| 168-184 | 576 |
| 192-208 | 512 |
| 216-232 | 448 |
| 240-256 | 384 |
From the table, it’s clear that up until a threshold, it doesn’t matter how many registers the program uses; occupancy is unaffected. Most well-written shaders fall in this bracket and need not worry. After hitting the threshold, other GPUs might spill registers to memory, but Apple doesn’t need to spill until more than 256 registers are required. Between 112 and 256 registers, the number of threads decreases in an almost linear fashion, in increments of 64 threads. Carefully considering rounding, it’s easy to recover the formula Metal uses to map register usage to thread count.
What’s less obvious is that we can infer the size of the machine’s register file. On one hand, if 256 registers are used, the machine can still support 384 threads, so the register file must be at least 256 half-words * 2 bytes per half-word * 384 threads = 192 KiB large. Likewise, to support 1024 threads at 104 registers requires at least 104 * 2 * 1024 = 208 KiB. If the file were any bigger, we would expect more threads to be possible at higher pressure, so we guess each threadgroup has exactly 208 KiB in its register file.
The story does not end there. From Apple’s public specifications, the M1 GPU supports 24576 = 1024 * 24 simultaneous threads. Since the table shows a maximum of 1024 threads per threadgroup, we infer 24 threadgroups may execute in parallel across the chip, each with its own register file. Putting it together, the GPU has 208 KiB * 24 = 4.875 MiB of register file! This size puts it in league with desktop GPUs.
For all the visible hardware features, it’s equally important to consider what hardware features are absent. Intriguingly, the GPU lacks some fixed-function graphics hardware ubiquitous among competitors. For example, I have not encountered hardware for reading vertex attributes or uniform buffer objects. The OpenGL and Vulkan specifications assume dedicated hardware for each, so what’s the catch?
Simply put – Apple doesn’t need to care about Vulkan or OpenGL performance. Their only properly supported API is their own Metal, which they may shape to fit the hardware rather than contorting the hardware to match the API. Indeed, Metal de-emphasizes vertex attributes and uniform buffers, favouring general constant buffers, a compute-focused design. The compiler is responsible for translating the fixed-function attribute and uniform state to shader code. In theory, this has a slight runtime cost; conventional wisdom says dedicated hardware is faster and lower power than software emulation. In practice, the code is so simple it may make no difference, although application developers should be mindful of the vertex formats used in case conversion code is inserted. As always, there is a trade-off: omitting features allows Apple to squeeze more arithmetic logic units (or register file!) onto the chip, speeding up everything else.
The more significant concern is the increased time on the CPU spent compiling shaders. If changing fixed-function attribute state can affect the shader, the compiler could be invoked at inopportune times during random OpenGL calls. Here, Apple has another trick: Metal requires the layout of vertex attributes to be specified when the pipeline is created, allowing the compiler to specialize formats at no additional cost. The OpenGL driver pays the price of the design decision; Metal is exempt from shader recompile tax.
The silver lining is that there is nothing to reverse-engineer for “missing” features like attributes and uniform buffers. As long as we know how to access memory in compute kernels, we can write the lowering code ourselves with no hardware mysteries. So far, I’ve implemented enough to spin a cube.
At present, the in-progress compiler supports most arithmetic and input/output instructions found in OpenGL ES 2.0, with a simple optimizer and native instruction packing. Support for control flow, textures, scheduling, and register allocation will come further down the line as we work towards a real driver.
Given that the new RDNA2 GPUs provide some support for hardware accelerated raytracing and there is even a new shiny Vulkan extension for it, it may not be a surprise that we’re working on implementing raytracing support in RADV.
Already some time ago I wrote documentation for the hardware raytracing support. As these GPUs contain quite minimal hardware to implement things there is a large software and shader side to implementing this.
And that is what I’ve been up to for the last couple of weeks. And I now have achieved my first personal milestones for the implementation:
This involves writing initial versions for a lot of the software infrastructure needed, so really shows that the basis is getting there.
At the same time we’re quite a ways off from really testing using CTS or running our first real demos. In particular we are missing things like
and much more, in addition to some of these initial implementations likely not really being performant.
I’m typing this up between loads and runs of various games I’m testing, since bug reports for games are somehow already a thing, and there’s a lot of them.
The worst part about testing games is the unbelievably long load times (and startup videos) most of them have, not to mention those long, panning camera shots at the start of the game before gameplay begins and I can start crashing.
But this isn’t a post about games.
No, no, there’s plenty of time for such things.
This is a combo post: part roundup because blogging has been sporadic the past couple weeks, and part feature.
The big Mesa 21.1 branchpoint happened yesterday, and I’m pretty pleased with the state of zink in this upcoming release.
Things you should expect to see:
Things you should not expect to see:
And here’s the zink-wip roundup from the past however long since I did the last one:
Yeah, I’m talking to you.
I fixed a ton of bugs. Like, actually a ton. Tomb Raider went from an all-you-can-crash buffet to…well, I’ll leave it as a fun surprise for anyone feeling especially intrepid, but it’s definitely playable. So are things that use queries. Don’t ask.
There’s totally some other stuff, but I’m too fried to remember it.
Everything up there was just fluff, but this is where the post gets real.
Zink supports formats with alpha-to-one, e.g., RGBX, BGRX, and even (on zink-wip, very illegal) XRGB and XBGR. This is handy for 24bit visuals, such as (probably) all your windows in Xorg. But the method by which these formats are supported comes with its own issues, part of which I’d fixed some time ago in my quest to reduce GPU overhead, and the other part I discovered more recently.
In zink, an alpha-to-one format is just the equivalent format with alpha. So RGBX is just RGBA. This is due to Vulkan not having format equivalents for these types; when sampling from them, a swizzle is applied to force the alpha channel to the maximum value, which yields the correct result.
But what happens when an RGBX framebuffer attachment is used in a blending operation?
Let’s look at VK_BLEND_OP_ADD as a very simple example. The spec defines this operation as:
As0 × Sa + Ad × Da
That’s alpha-of-src times src-alpha-blend-factor plus alpha-of-dest times dest-alpha-blend-factor yielding the resulting pixel color that gets written to the attachment.
But what if the dest value is expected to always one, and the actual buffer is always zero because its alpha channel is never written?
Such is the case with RGBX and the like, and so more steps are required here for full emulation.
Here’s how I went about solving the issue.
First, framebuffer attachments have to be monitored when they’re updated, and any time an alpha-to-one attachment is bound, I set a bitflag for it in the pipeline state. This then triggers a pipeline update for the blend state at the time of draw, where I apply clamping to the appropriate blend factors like so:
if (state->zero_alpha_attachments) {
for (unsigned i = 0; i < state->num_attachments; i++) {
blend_att[i] = state->blend_state->attachments[i];
if (state->zero_alpha_attachments & BITFIELD_BIT(i)) {
blend_att[i].dstAlphaBlendFactor = VK_BLEND_FACTOR_ZERO;
blend_att[i].srcColorBlendFactor = clamp_zero_blend_factor(blend_att[i].srcColorBlendFactor);
blend_att[i].dstColorBlendFactor = clamp_zero_blend_factor(blend_att[i].dstColorBlendFactor);
}
}
blend_state.pAttachments = blend_att;
} else
blend_state.pAttachments = state->blend_state->attachments;
For any of the attachments in the bitfield, three clamps are performed:
dstAlphaBlendFactor is clamped to zero, because there will never be any contribution from the dest component of alpha blendingsrcColorBlendFactor and dstColorBlendFactor are both clamped using the following check:if (f == VK_BLEND_FACTOR_ONE_MINUS_DST_ALPHA)
return VK_BLEND_FACTOR_ZERO;
if (f == VK_BLEND_FACTOR_DST_ALPHA)
return VK_BLEND_FACTOR_ONE;
return f;
Thus, alpha blending is a passthrough operation from the src component, and for color blending, the dest component is always one or zero. This yields correct results in piglit’s spec@arb_texture_float@fbo-blending-formats test, and also potentially enables the hardware to employ some optimizations to reduce the burden of blending.
Exciting.
With dbus-broker we have introduced the resource-accounting of bus1 into the D-Bus world. We believe it greatly improves and strengthens the resource distribution of the D-Bus messages bus, and we have already found a handful of resource leaks that way. However, it can be a daunting task to solve resource exhaustion bugs, so I decided to describe the steps we took to resolve a recent resource-leak in the openQA package.
A few days ago, Adam Williamson approached me 1 with a bug in the openQA package, where he saw the log stream filled with messages like:
dbus-broker[<pid>]: Peer :1.<id> is being disconnected as it does not have the resources to receive a reply or unicast signal it expects.
dbus-broker[<pid>]: UID <uid> exceeded its 'bytes' quota on UID <uid>.
This is the typical sign of a resource exhaustion in dbus-broker. When the message broker generates or forwards messages to an individual client, it will queue them as outgoing-messages and push them into the unix-socket of the client. If this client does not dequeue messages, this queue might fill up. If a limit is reached, something needs to be done. Since D-Bus is not a lossy protocol, dropping messages is not an option. Instead, the message broker will either refuse new incoming operations or disconnect a client. All resources are accounted on UIDs, this means multiple clients of the same user will share the same resource limits.
Depending on what message is sent, it is accounted either on the receiver or sender. Furthermore, some messages can be refused by the broker, others cannot. The exact rules are described in the wiki 2.
In the case of openQA, the first step was to query the accounting information of the running message broker:
sudo dbus-send --system --dest=org.freedesktop.DBus --type=method_call --print-reply /org/freedesktop/DBus org.freedesktop.DBus.Debug.Stats.GetStats
(Replace --system with --session to query the session or user bus.)
While preferably this query is performed when the resource exhaustion happens, it will often yield useful information under normal operation as well. Resources are often consumed slowly, so the accumulation will still show up.
The output 3 of this query shows a list of all D-Bus clients with their
accounting information. Furthermore, it lists all UIDs that have clients
connected to this message bus, again with all accounting information. The
challenge is to find suspicious entries in this huge data dump. The most
promising solution so far was to search for "OutgoingBytes" and check for
big numbers. This shows the number of bytes queued in the message broker for
a particular client. It is usually 0, since the kernel queues are big enough
to hold most normal messages. Even if it is not 0, it is usually just a couple
of KiB.
In this case, we checked for "OutgoingBytes", and found:
dict entry(
string "OutgoingBytes"
uint32 62173024
)
62 MiB of messages are waiting to be delivered to that client. Expanding the logs to show the surrounding block, we see:
struct {
string ":1.211366"
array [
dict entry(
string "UnixUserID"
variant uint32 991
)
dict entry(
string "ProcessID"
variant uint32 674968
)
[...]
]
array [
[...]
dict entry(
string "Matches"
uint32 1
)
[...]
dict entry(
string "OutgoingBytes"
uint32 62173024
)
[...]
]
}
This tells us the PID 674968 of user 991 has roughly 62 MiB of data queued,
and it is likely not dequeuing the data. Furthermore, we see it has 1 message
filter (D-Bus match rule) installed. D-Bus message filters will cause matching
D-Bus signals to be delivered to a client. So a likely problem is that this
client keeps receiving signals, but does not dispatch its client socket.
We digged further, and the data dump includes more such clients. Matching back
the PIDs to processes via ps auxf, we found that each and every of those
suspicious entries was /usr/bin/isotovideo: backend. The code of this process
is part of the os-autoinst repository, in this case qemu.pm. A quick look
showed only a single use of D-Bus 4. At a first glance, this looks alright.
It creates a system-bus connection via the Net::DBus perl module, dispatches
a method-call, and returns the result. However, we know this process has a
match-rule installed (assuming the dbus-broker logs are correct), so we checked
further and found that the Net::DBus module always installs a match-rule on
NameOwnerChanged. Furthermore, it caches the system-bus connection in a
global variable, sharing it across users in the same code-base.
Long story short, the os-autoinst qemu module created a D-Bus connection
which was idle in the background and never dispatched by any code. However, the
connection has a match-rule installed, and the message broker kept sending
matching signals to that connection. This data accumulated and eventually
exceeded the resource quota of that client. A workaround was quickly provided,
and it will hopefully resolve this problem 5.
Hopefully, this short recap will be helpful to debug other similar situations. You are always welcome to message us on bus1-devel@googlegroups or on the dbus-broker GitHub issue tracker if you need help.
In RADV we just added an option to speed up rendering by rendering less pixels.
These kinds of techniques have become more common over the past decade with techniques such as checkerboarding, TAA based upscaling and recently DLSS. Fundamentally all they do is trading off rendering quality for rendering cost and many of them include some amount of postprocessing to try to change the curve of that tradeoff. Most notably DLSS has been wildly successful at that to the point many people claim it is barely a quality regression.
Of course increasing GPU performance by up to 50% or so with barely any quality regression seems like must have and I think it would be pretty cool if we could have the same improvements on Linux. I think it has the potential to be a game changer, making games playable on APUs or playing with really high resolution or framerates on desktops.
And today we took our first baby steps in RADV by allowing users to force Variable Rate Shading (VRS) with an experimental environment variable:
RADV_FORCE_VRS=2x2
VRS is a hardware capability that allows us to reduce the number of fragment shader invocations per pixel rendered. So you could say configure the hardware to use one fragment shader invocation per 2x2 pixels. The hardware still renders the edges of geometry exactly, but the inner area of each triangle is rendered with a reduced number of fragment shader invocations.
There are a couple of ways this capability can be configured:
This is a new feature for AMD on RDNA2 hardware.
With RADV_FORCE_VRS we use this to improve performance at the cost of visual quality. Since we did not implement any postprocessing the quality loss can be pretty bad, so we restricted the reduce shading rate when we detect one of the following
As a result there are some games where this has barely any effect but you also don’t notice the quality regression and there are games where it really improves performance by 30%+ but you really notice the quality regression.
VRS is by far the easiest thing to make work in almost all games. Most alternatives like checkerboarding, TAA and DLSS need modified render target size, significant shader fixups, or even a proprietary integration with games. Making changes that deeply is getting more complicated the more advanced the game is.
If we want to reduce render resolution (which would be a key thing in e.g. checkerboarding or DLSS) it is very hard to confidently tie all resolution dependent things together. For example a big cost for some modern games is raytracing, but the information flow to the main render targets can be very hard to track automatically and hence such a thing would require a lot of investigation or a bunch of per game customizations.
And hence we decided to introduce this first baby step. Enjoy!
The lavapipe vulkan software rasterizer in Mesa is now reporting Vulkan 1.1 support.
It passes all CTS tests for those new features in 1.1 but it stills fails all the same 1.0 tests so isn't that close to conformant. (lines/point rendering are the main areas of issue).
There are also a bunch of the 1.2 features implemented so that might not be too far away though 16-bit shader ops and depth resolve are looking a bit tricky.
If there are any specific features anyone wants to see or any crazy places/ideas for using lavapipe out there, please either file a gitlab issue or hit me up on twitter @DaveAirlie
The great thing about tomorrow is that it never comes.
Let’s talk about sparse buffers.
What is a sparse buffer? A sparse buffer is a buffer that is not required to be contiguously or fully backed. This means that a buffer larger than the GPU’s available memory can be created, and only some parts of it are utilized at any given time. Because of the non-resident nature of the backing memory, they can never be mapped, instead needing to go through a staging buffer for any host read/write.
In a gallium-based driver, provided that an effective implementation for staging buffers exists, sparse buffer implementation goes almost exclusively through the pipe_context::resource_commit hook, which manages residency of a sparse resource’s backing memory, passing a range to change residency for and an on/off switch.
In zink(-wip), the hook looks like this:
static bool
zink_resource_commit(struct pipe_context *pctx, struct pipe_resource *pres, unsigned level, struct pipe_box *box, bool commit)
{
struct zink_context *ctx = zink_context(pctx);
struct zink_resource *res = zink_resource(pres);
struct zink_screen *screen = zink_screen(pctx->screen);
/* if any current usage exists, flush the queue */
if (zink_batch_usage_matches(&res->obj->reads, ctx->curr_batch) ||
zink_batch_usage_matches(&res->obj->writes, ctx->curr_batch))
zink_flush_queue(ctx);
VkBindSparseInfo sparse;
sparse.sType = VK_STRUCTURE_TYPE_BIND_SPARSE_INFO;
sparse.pNext = NULL;
sparse.waitSemaphoreCount = 0;
sparse.bufferBindCount = 1;
sparse.imageOpaqueBindCount = 0;
sparse.imageBindCount = 0;
sparse.signalSemaphoreCount = 0;
VkSparseBufferMemoryBindInfo sparse_bind;
sparse_bind.buffer = res->obj->buffer;
sparse_bind.bindCount = 1;
sparse.pBufferBinds = &sparse_bind;
VkSparseMemoryBind mem_bind;
mem_bind.resourceOffset = box->x;
mem_bind.size = box->width;
mem_bind.memory = commit ? res->obj->mem : VK_NULL_HANDLE;
mem_bind.memoryOffset = box->x;
mem_bind.flags = 0;
sparse_bind.pBinds = &mem_bind;
VkQueue queue = util_queue_is_initialized(&ctx->batch.flush_queue) ? ctx->batch.thread_queue : ctx->batch.queue;
VkResult ret = vkQueueBindSparse(queue, 1, &sparse, VK_NULL_HANDLE);
if (!zink_screen_handle_vkresult(screen, ret)) {
check_device_lost(ctx);
return false;
}
return true;
}
Naturally there’s a need to enjoy the verbosity of Vulkan structs here, but there’s two key takeaways.
The first is that this implementation is likely suboptimal; it should be making better use of semaphores to avoid having to flush the queue if the resource has current-batch usage. That’s complex to implement, however, so I took the same shortcut that RadeonSI does here.
The second is that this is just copying the pipe_box struct to the VkSparseMemoryBind struct. The reason this works with a 1:1 mapping is because the backing resource is allocated with a 1:1 range mapping, so the values can be directly used.
Other than that, the only changes required for this implementation were to add a bunch of checks for the sparse flag on resources during map/unmap to force staging buffers and to use device-local memory instead of host-visible.
Sometimes zink can be simple!
The crocus project was recently mentioned in a phoronix article. The article covered most of the background for the project.
Crocus is a gallium driver to cover the gen4-gen7 families of Intel GPUs. The basic GPU list is 965, GM45, Ironlake, Sandybridge, Ivybridge and Haswell, with some variants thrown in. This hardware currently uses the Intel classic 965 driver. This is hardware is all gallium capable and since we'd like to put the classic drivers out to pasture, and remove support for the old infrastructure, it would be nice to have these generations supported by a modern gallium driver.
The project was initiated by Ilia Mirkin last year, and I've expended some time in small bursts to moving it forward. There have been some other small contributions from the community. The basis of the project is a fork of the iris driver with the old relocation based batchbuffer and state management added back in. I started my focus mostly on the older gen4/5 hardware since it was simpler and only supported GL 2.1 in the current drivers. I've tried to cleanup support for Ivybridge along the way.
The current status of the driver is in my crocus branch.
Ironlake is the best supported, it runs openarena and supertuxkart, and piglit has only around 100 tests delta vs i965 (mostly edgeflag related) and there is only one missing feature (vertex shader push constants).
Ivybridge just stop hanging on second batch submission now, and glxgears runs on it. Openarena starts to the menu but is misrendering and a piglit run completes with some gpu hangs and a quite large delta. I expect IVB to move faster now that I've solved the worst hang.
Haswell runs glxgears as well.
I think once I take a closer look at Ivybridge/Haswell and can get Ilia (or anyone else) to do some rudimentary testing on Sandybridge, I will start taking a closer look at upstreaming it into Mesa proper.
After last week’s post touting the “final” features being added to the upcoming Mesa release, naturally now that this is a new week, I have to outdo myself.
I’ve heard some speculation about zink’s future regarding features. Specifically regarding all the mesamatrix features that aren’t green-ified for zink yet.
So you want features is what you’re saying.
Let’s see where things stand in today’s zink-wip snapshot:
By my calculations, that’s 11 TODO, 10 not supported, 2 advanced blend, and 1 final boss, a total of 24 out-of-version-extensions not yet implemented out of 54, meaning that 30 are done, tying with i965 and second only to RadeonSI at 33.
New in today’s snapshot: GL_ARB_fragment_shader_interlock, GL_ARB_sparse_buffer, GL_ARB_sample_locations, GL_ARB_shader_ballot, GL_ARB_shader_clock, GL_ARB_texture_filter_minmax
Writing blog posts like this is easy, but you know what’s not easy?
Writing good blog posts.
And new to the blogging game is the one, the only, Bas Nieuwenhuizen of RADV founding fame! If you’re at all curious about how drivers actually work, his is definitely a site to follow, as he’s already gone much deeper into explaining my RPCS3 memcpy fail than I ever did.
Is sparse buffer implementation 101. I’ve said it, so now the blog post has to happen.
In this article I show how reading from VRAM can be a catastrophe for game performance and why.
To illustrate I will go back to fall 2015. AMDGPU was just released, it didn’t even have re-clocking yet and I was just a young student trying to play Skyrim on my new AMD R9 285.
Except it ran slowly. 10-15 FPS slowly. Now one might think that is no surprise as due to lack of re-clocking the GPU ran with a shader clock of 300 MHz. However the real surprise was that the game was not at all GPU bound.
As usual with games of that era there was a single thread doing a lot of the work and that thread was very busy doing something inside the game binary. After a bunch of digging with profilers and gdb, it turned out that the majority of time was spent in a single function that accessed less than 1 MiB from a GPU buffer each frame.
At the time DXVK was not a thing yet and I ran the game with wined3d on top of OpenGL. In OpenGL an application does not specify the location of GPU buffers directly, but specifies some properties about how it is going to be used and the driver decides. Poorly in this case.
There was a clear tweak to the driver heuristics that choose the memory location and the frame rate of the game more than doubled and was now properly GPU bound.
After the anecdote above you might be wondering how slow reading from VRAM can really be? 1 MiB is not a lot of data so even if it is slow it cannot be that bad right?
To show you how bad it can be I ran some benchmarks on my system (Threadripper 2990wx, 4 channel DDR4-3200 and a RX 6800 XT). I checked read/write performance using a 16 MiB buffer (512 MiB for system memory to avoid the test being contained in L3 cache)
We look into three allocation types that are exposed by the amdgpu Linux kernel driver:
VRAM. This lives on the GPU and is mapped with Uncacheable Speculative Write Combining (USWC) on the CPU. This means that accesses from the CPU are not cached, but writes can be write-combined.
Cacheable system memory. This is system memory that has caching enabled on the CPU and there is cache snooping to ensure the memory is coherent between the CPU and GPU (up till the top level caches. The GPU caches do not participate in the coherence).
USWC system memory. This is system memory that is mapped with Uncacheable Speculative Write Combining on the CPU. This can lead to slight performance benefits compared to cacheable system memory due to lack of cache snooping.
For context, in Vulkan this would roughly correspond to the following memory types:
| Hardware | Vulkan |
|---|---|
| VRAM | VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT |
| Cacheable system memory | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT | VK_MEMORY_PROPERTY_HOST_CACHED_BIT |
| USWC system memory | VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT |
The benchmark resulted in the following throughput numbers:
| method (MiB/s) | VRAM | Cacheable System Memory | USWC System Memory |
|---|---|---|---|
| read via memcpy | 15 | 11488 | 137 |
| write via memcpy | 10028 | 18249 | 11480 |
I furthermore tested handwritten for-loops accessing 8,16,32 and 64-bit elements at a time and those got similar performance.
This clearly shows that reads from VRAM using memcpy are ~766x slower than memcpy reads from cacheable system memory and even non-cacheable system memory is ~91x slower than cacheable system memory. Reading even small amounts from these can cause severe performance degradations.
Writes show a difference as well, but the difference is not nearly as significant. So if an application does not select the best memory location for their data for CPU access it is still likely to result in a reasonable experience.
Even though APUs do not have VRAM they still are affected by the same issue. Typically the GPU gets a certain amount of memory pre-allocated at boot time as a carveout. There are some differences in how this is accessed from the GPU so from the perspective of the GPU this memory can be faster.
At the same time the Linux kernel only gives uncached access to that region from the CPU, so one could expect similar performance issues to crop up.
I did the same test as above on a laptop with a Ryzen 5 2500U (Raven Ridge) APU, and got results that are are not dissimilar from my workstation.
| method (MiB/s) | Carveout | Snooped System Memory | USWC System Memory |
|---|---|---|---|
| read via memcpy | 108 | 10426 | 108 |
| write via memcpy | 11797 | 20743 | 11821 |
The carveout performance is virtually identical to the uncached system memory now, which is still ~97x slower than cacheable system memory. So even though it is all system memory on an APU care still has to be taken on how the memory is allocated.
Since the performance cliff is so large it is recommended to avoid this issue if at all possible. The following three methods are good ways to avoid the issue:
If the data is only written from the CPU, it is advisable to use a shadow buffer in cacheable system memory (can even be outside of the graphics API, e.g. malloc) and read from that instead.
If this is written by the GPU but not frequently, one could consider putting the buffer in snooped system memory. This makes the GPU traffic go over the PCIE bus though, so it has a trade-off.
Let the GPU copy the data to a buffer in snooped system memory. This is basically an extension of the previous item by making sure that the GPU accesses the data exactly once in system memory. The GPU roundtrip can take a non-trivial wall-time though (up to ~0.5 ms measured on some low end APUs), some of which is size-independent, such as command submission. Additionally this may need to wait till the hardware unit used for the copy is available, which may depend on other GPU work. The SDMA unit (Vulkan transfer queue) is a good option to avoid that.
Another problem with CPU access from VRAM is the BAR size. Typically only the first 256 MiB of VRAM is configured to be accessible from the CPU and for anything else one needs to use DMA.
If the working set of what is allocated in VRAM and accessed from the CPU is large enough the kernel driver may end up moving buffers frequently in the page fault handler. System memory would be an obvious target, but due to the GPU performance trade-off that is not always the decision that gets made.
Luckily, due to the recent push from AMD for Smart Access Memory, large BARs that encompass the entire VRAM are now much more common on consumer platforms.
This is the first post of this blog and with it being past midnight I couldn’t be bothered making one about a technical topic. So instead here is an explanation of my plans with the blog.
I got inspired by the prolific blogging of Mike Blumenkrantz and some discussion on the VKx discord that some actually written updates can be very useful, and that I don’t need to make a paper out of each one.
At the same time I have been involved in some longer running things on the driver side which I think could really use some updates as progress is made. Consider for example raytracing, DRM format modifiers, RGP support and more.
I have no plans at all to be as prolific as Mike by a long shot, but I think the style of articles is probably a good template of what to expect from this blog.
Blogging is tough, but I’m getting the posts out there one way or another.
Today marks what is likely to be the last of the “big” changes to zink in Mesa 21.1 before the merge window closes in less than two weeks, and what changes they were.
Threaded context support is now implemented, which, on its own, makes zink vaguely competitive against native GL drivers. I’d expect that for many scenarios, people should start seeing upwards of 60-70% native perf when previously the numbers were much lower, excepting things like furmark, where a weird problem with alpha blending is still causing a massive perf hit.
If that wasn’t enough, my timeline semaphore handling also snuck in, providing a reduction in CPU overhead for asynchronous queue-related operations where supported. Special thanks to Vulkan crash test dummy and uninitialized variable enthusiast Lionel Landwerlin for tripping and falling over basically every line of code in this implementation to help get it to the finish line for your consumption.
And if that still wasn’t enough, my RADV draw dispatch refactor also landed yesterday, both paving the way for some totally secret future work of mine and also bringing a 3-4% reduction in CPU overhead for draws that will make your gaming feel faster now that you’re aware of it but realistically won’t have any discernible effect. Basically racing stripes.
Today, a brief post and lamentation.
I’m sure everyone is well aware of Vulkan semantics regarding array vs non-array image types: when using an array type, e.g., VK_IMAGE_TYPE_2D with VkImageCreateInfo::arrayLayers > 1, always use array members for accessing/copying/blitting, and when using a 3D type, always use depth members.
This means array types should use baseArrayLayer and layerCount for copying/blitting and arrayPitch for accessing subresource regions. Non-array types, specifically 3D types, should use VkExtent3D::depth and VkSubresourceLayout::depthPitch.
This is really important, as I’ve found out over the past week, given that this has not been handled as it should’ve in many places throughout the zink stack. Some drivers were cool and didn’t make a big deal about it. Other drivers were more accurate and have just been failing all along.
I was recently interviewed by Boiling Steam, a small Linux gaming-oriented news site focused on creating original content and interviewing only the most important figures within the community (like me). If you’ve ever wanted to know more about the rich open source pedigree of Super Good Code, the interview goes deep into the back catalogue of how things got to this point.
It’s been a while since I blogged about descriptors, so let’s fix that since this site may as well be called Super Good Descriptors.
Last time, I talked a bit about descriptors 3.0: lazy descriptors. The idea I settled on here was to do templated updates, and to do the absolute minimal amount of work possible for each draw while still never reusing any written-to descriptor sets once they’d been cycled out.
Lazy descriptors worked out great, and I’m sure many of you have grown to enjoy the ZINK: USING LAZY DESCRIPTORS log message that got spammed on startup over the past couple months of zink-wip.
Well, times have changed, and this message will no longer fill your terminal by default after today’s (20210330) zink-wip snapshot.
New today is the ZINK_DESCRIPTORS environment variable, supporting three modes of operation:
auto - the default, which attempts to detect system capabilities and use caching with templated updateslazy - the mode we all know and love from the past few monthsnotemplates - this is the old-style caching mechanismauto mode moves zink one step closer to my eventual goal, which is to be able to use driconf to do application-based mode changes to disable caching for apps which never reuse resources. Also potentially useful would be the ability to dynamically disable caching on a pipeline-by-pipeline basis while an application is running if too many cache misses are detected.
With that said, I’ve come to the conclusion that any form of caching may actually be, at best, equivalent to uncached mode for the general desktop user, and it may only be worthwhile for special cases, like Vulkan drivers which can’t do descriptor templates or embedded devices. In my latest testing (on desktop systems), I have yet to see any scenarios where lazy mode fails to provide the best performance.
ARM in particular seems to gain a lot from it, as the post shows a ~40% perf improvement. It’s unclear to me, however, whether any benchmarking was done against a highly optimized uncached implementation like I’ve done. The overhead from doing basic descriptor updating without templates is definitely significant, so it might just be that things are different now that more functionality is available. On Linux systems, at least, every Vulkan driver that matters supports descriptor templates, so this is functionality that can be relied upon.
No.
The goal of zink-wip is to provide an optimal testing environment with the absolute bleeding edge in terms of performance and features. The auto mode should provide that, and the cases I’ve seen where its performance is noticeably worse number exactly one, and it’s a subtest for drawoverhead. If anyone finds any other cases where auto is worse than lazy, I’m interested, but it shouldn’t be a concern.
With that said, it might be worth doing some benchmarking between the two for some extremely high CPU usage scenarios, as that’s the only case where it may be possible to detect a difference. Gone are the days of zink(-wip) hogging the whole CPU, so probably this is just useless pontificating to fill more of a blog page.
But also, if you’re doing any kind of benchmarking on a high-end CPU, I’d probably recommend going with the lazy mode for now.
I’m pleased with the current state of descriptor caching, but it does bother me that it isn’t dramatically better than the uncached mode on my desktop. I think this ultimately just comes down to the current cache implementation being split into two steps:
This effectively sits on top of the lazy mode, moving work out of the Vulkan driver and into the cache lookup any time there’s a cache hit. As such, I’ve been considering working to shift some of this work into threads, though this is somewhat challenging given the current gallium API. Specifically, only SSBOs and shader images can be per-stage updated immediately after bind, as both UBOs and samplers bind only a single descriptor slot at a time, meaning there’s no way to know when the “final” one is bound.
But then again, I’ve certainly reached the point of diminishing returns now. Most applications that I test have minimal CPU usage for the zink driver thread (e.g., Unigine Superposition is only at about 10% utilization on a i7-6700K), and are instead bottlenecking hard in the GPU, so I think it’s time to call things “good enough” here unless things change in a significant way.
A restrictive end-user license agreement is one way a company can exert power over the user. When the free software movement was founded thirty years ago, these restrictive licenses were the primary user-hostile power dynamic, so permissive and copyleft licenses emerged as synonyms to software freedom. Licensing does matter; user autonomy is lost with subscription models, revocable licenses, binary-only software, and onerous legal clauses. Yet these issues pertinent to desktop software do not scratch the surface of today’s digital power dynamics.
Today, companies exert power over their users by: tracking, selling data, psychological manipulation, intrusive advertising, planned obsolescence, and hostile Digital “Rights” Management (DRM) software. These issues affect every digital user, technically inclined or otherwise, on desktops and smartphones alike.
The free software movement promised to right these wrongs via free licenses on the source code, with adherents arguing free licenses provide immunity to these forms of malware since users could modify the code. Unfortunately most users lack the resources to do so. While the most egregious violations of user freedom come from companies publishing proprietary software, these ills can remain unchecked even in open source programs, and not all proprietary software exhibits these issues. The modern browser is nominally free software containing the trifecta of telemetry, advertisement, and DRM; a retro video game is proprietary software but relatively harmless.
As such, it’s not enough to look at the license. It’s not even enough to consider the license and a fixed set of issues endemic to proprietary software; the context matters. Software does not exist in a vacuum. Just as proprietary software tends to integrate with other proprietary software, free software tends to integrate with other free software. Software freedom in context demands a gentle nudge towards software in user interests, rather than corporate interests.
How then should we conceptualize software freedom?
Consider the three adherents to free software and open source: hobbyists, corporations, and activists. Individual hobbyists care about tinkering with the software of their choice, emphasizing freely licensed source code. These concerns do not affect those who do not make a sport out of modifying code. There is nothing wrong with this, but it will never be a household issue.
For their part, large corporations claim to love “open source”. No, they do not care about the social movement, only the cost reduction achieved by taking advantage of permissively licensed software. This corporate emphasis on licensing is often to the detriment of software freedom in the broader context. In fact, it is this irony that motivates software freedom beyond the license.
It is the activist whose ethos must apply to everyone regardless of technical ability or financial status. There is no shortage of open source software, often of corporate origin, but this is insufficient – it is the power dynamic we must fight.
We are not alone. Software freedom is intertwined with contemporary social issues, including copyright reform, privacy, sustainability, and Internet addiction. Each issue arises as a hostile power dynamic between a corporate software author and the user, with complicated interactions with software licensing. Disentangling each issue from licensing provides a framework to address nuanced questions of political reform in the digital era.
Copyright reform generalizes the licensing approaches of the free software and free culture movements. Indeed, free licenses empower us to freely use, adapt, remix, and share media and software alike. However, proprietary licenses micromanaging the core of human community and creativity are doomed to fail. Proprietary licenses have had little success preventing the proliferation of the creative works they seek to “protect”, and the rights to adapt and remix media have long been exercised by dedicated fans of proprietary media, producing volumes of fanfiction and fan art. The same observation applies to software: proprietary end-user license agreements have stopped neither file sharing nor reverse-engineering. In fact, a unique creative fandom around proprietary software has emerged in video game modding communities. Regardless of legal concerns, the human imagination and spirit of sharing persists. As such, we need not judge anyone for proprietary software and media in their life; rather, we must work towards copyright reform and free licensing to protect them from copyright overreach.
Privacy concerns are also traditional in software freedom discourse. True, secure communications software can never be proprietary, given the possibility of backdoors and impossibility of transparent audits. Unfortunately, the converse fails: there are freely licensed programs that inherently compromise user privacy. Consider third-party clients to centralized unencrypted chat systems. Although two users of such a client privately messaging one another are using only free software, if their messages are being data mined, there is still harm. The need for context is once more underscored.
Sustainability is an emergent concern, tying to software freedom via the electronic waste crisis. In the mobile space, where deprecating smartphones after a few short years is the norm and lithium batteries are hanging around in landfills indefinitely, we see the paradox of a freely licensed operating system with an abysmal social track record. A curious implication is the need for free device drivers. Where proprietary drivers force devices into obsolescence shortly after the vendor abandons them in favour of a new product, free drivers enable long-term maintenance. As before, licensing is not enough; the code must also be upstreamed and mainlined. Simply throwing source code over a wall is insufficient to resolve electronic waste, but it is a prerequisite. At risk is the right of a device owner to continue use of a device they have already purchased, even after the manufacturer no longer wishes to support it. Desired by climate activists and the dollar conscious alike, we cannot allow software to override this right.
Beyond copyright, privacy, and sustainability concerns, no software can be truly “free” if the technology itself shackles us, dumbing us down and driving us to outrage for clicks. Thanks to television culture spilling onto the Internet, the typical citizen has less to fear from government wiretaps than from themselves. For every encrypted message broken by an intelligence agency, thousands of messages are willingly broadcast to the public, seeking instant gratification. Why should a corporation or a government bother snooping into our private lives, if we present them on a silver platter? Indeed, popular open source implementations of corrupt technology do not constitute success, an issue epitomized by free software responses to social media. No, even without proprietary software, centralization, or cruel psychological manipulation, the proliferation of social media still endangers society.
Overall, focusing on concrete software freedom issues provides room for nuance, rather than the traditional binary view. End-users may make more informed decisions, with awareness of technologies’ trade-offs beyond the license. Software developers gain a framework to understand how their software fits into the bigger picture, as a free license is necessary but not sufficient for guaranteeing software freedom today. Activists can divide-and-conquer.
Many outside of our immediate sphere understand and care about these issues; long-term success requires these allies. Claims of moral superiority by licenses are unfounded and foolish; there is no success backstabbing our friends. Instead, a nuanced approach broadens our reach. While abstract moral philosophies may be intellectually valid, they are inaccessible to all but academics and the most dedicated supporters. Abstractions are perpetually on the political fringe, but these concrete issues are already understood by the general public. Furthermore, we cannot limit ourselves to technical audiences; understanding network topology cannot be a prerequisite to private conversations. Overemphasizing the role of source code and under-emphasizing the power dynamics at play is a doomed strategy; for decades we have tried and failed. In a post-Snowden world, there is too much at stake for more failures. Reforming the specific issues paves the way to software freedom. After all, social change is harder than writing code, but with incremental social reform, licenses become the easy part.
The nuanced analysis even helps individual software freedom activists. Purist attempts to refuse non-free technology categorically are laudable, but outside a closed community, going against the grain leads to activist burnout. During the day, employers and schools invariably mandate proprietary software, sometimes used to facilitate surveillance. At night, popular hobbies and social connections today are mediated by questionable software, from the DRM in a video game to the surveillance of a chat with a group of friends. Cutting ties with friends and abandoning self-care as a prerequisite to fighting powerful organizations seems noble, but is futile. Even without politics, there remain technical challenges to using only free software. Layering in other concerns, or perhaps foregoing a mobile smartphone, only amplifies the risk of software freedom burnout.
As an application, this approach to software freedom brings to light disparate issues with the modern web raising alarm in the free software community. The traditional issue is proprietary JavaScript, a licensing question, yet considering only JavaScript licensing prompts both imprecise and inaccurate conclusions about web “applications”. Deeper issues include rampant advertising and tracking; the Internet is the largest surveillance network in human history, largely for commercial aims. To some degree, these issues are mitigated by script, advertisement, and tracker blockers; these may be pre-installed in a web browser for harm reduction in pursuit of a gentler web. However, the web’s fatal flaw is yet more fundamental. By design, when a user navigates to a URL, their browser executes whatever code is piped on the wire. Effectively, the web implies an automatic auto-update, regardless of the license of the code. Even if the code is benign, it is still every year more expensive to run, forcing a hardware upgrade cycle deprecating old hardware which would work if only the web weren’t bloated by corporate interests. A subtler point is the “attention economy” tied into the web. While it’s hard to become addicted to reading in a text-only browser, binge-watching DRM-encumbered television is a different story. Half-hearted advances like “Reading Mode” are limited by the ironic distribution of documents over an app store. On the web, disparate issues of DRM, forced auto-update, privacy, sustainability, and psychological dark patterns converge to a single worst case scenario for software freedom. The licenses were only the beginning.
Nevertheless, there is cause for optimism. Framed appropriately, the fight for software freedom is winnable. To fight for software freedom, fight for privacy. Fight for copyright reform. Fight for sustainability. Resist psychological dark patterns. At the heart of each is a software freedom battle – keep fighting and we can win.
Declaration of Digital Autonomy
Local-first software: You own your data, in spite of the cloud
Mike, the zink dev, mentioned that swiftshader seemed slow at some stuff and I realised I've never expended much effort in checking swiftshader vs llvmpipe in benchmarks.
The thing is CPU rendering is pretty much going to top out on memory bandwidth pretty quickly but I decided to do some rough napkin benchmarks using the vulkan samples from Sascha Willems.
I'd also thought that due to having a few devs and the fact that it was used instead of mesa by google for lots of things that llvmpipe would be slower since it hasn't really gotten dedicated development resources.
I picked a random smattering of Vulkan samples and ran them on my Ryzen
workstation without doing anything else, in their default window size.
The first number is lavapipe fps the second swiftshader.
I guess the swift is just good marketing name, now I'm not sure why llvmpipe/lavapipe isn't more of a development target for those devs, imagine how much better it could be if it has fulltime dedicate devs on it.
It’s no secret that CPU renderers are slower than GPU renderers. But at the same time, CPU renderers are crucial for things like CI and also not hanging your current session by testing on a live GPU when you’re deep into Critical Rewrites.
So I’ve spent some time today doing some rewrites in the *pipe section of mesa, and let’s just say that the pipe was good with zink before, but it’s much, much better now.
Here’s where I started on piglit’s drawoverhead test under Lavapipe:
#, Test name , Thousands draws/s, Difference vs the 1st
1, DrawElements ( 1 VBO| 0 UBO| 0 ) w/ no state change, 1517, 100.0%
2, DrawElements ( 4 VBO| 0 UBO| 0 ) w/ no state change, 1519, 100.2%
3, DrawElements (16 VBO| 0 UBO| 0 ) w/ no state change, 1112, 73.3%
4, DrawElements ( 1 VBO| 0 UBO| 16 Tex) w/ no state change, 524, 34.5%
5, DrawElements ( 1 VBO| 8 UBO| 8 Tex) w/ no state change, 583, 38.4%
Nothing too incredible. Modern CPUs with a discrete GPU should be pulling upwards of 15,000k draws/s, and hitting 10% of that is sort of okay.jpg.
But what if I implemented my Mesa multidraw extensions in Lavapipe?
The gist of this extension is that when no other draw parameters have changed except for the starting vertex/index and the number of vertices/indices, an array of those values can just be dumped into the Vulkan driver to optimize out a lot of draw dispatch/validation code, mirroring Marek Olšák’s multidraw work in Gallium.
The results, just from doing basic support in Lavapipe without adding any handling in LLVMpipe underneath, speak for themselves:
#, Test name , Thousands draws/s, Difference vs the 1st
1, DrawElements ( 1 VBO| 0 UBO| 0 ) w/ no state change, 2945, 100.0%
2, DrawElements ( 4 VBO| 0 UBO| 0 ) w/ no state change, 2626, 89.2%
3, DrawElements (16 VBO| 0 UBO| 0 ) w/ no state change, 1702, 57.8%
4, DrawElements ( 1 VBO| 0 UBO| 16 Tex) w/ no state change, 2881, 97.8%
5, DrawElements ( 1 VBO| 8 UBO| 8 Tex) w/ no state change, 2888, 98.1%
Yup, that’s a 100% perf increase.
But then I thought to myself: What if LLVMpipe could also handle me dumping all this info in?
Indeed, by spending way too much time rewriting and refactoring deep Mesa internals, I have gone beyond:
#, Test name , Thousands draws/s, Difference vs the 1st
1, DrawElements ( 1 VBO| 0 UBO| 0 ) w/ no state change, 5273, 100.0%
2, DrawElements ( 4 VBO| 0 UBO| 0 ) w/ no state change, 4804, 91.1%
3, DrawElements (16 VBO| 0 UBO| 0 ) w/ no state change, 2941, 55.8%
4, DrawElements ( 1 VBO| 0 UBO| 16 Tex) w/ no state change, 5052, 95.8%
5, DrawElements ( 1 VBO| 8 UBO| 8 Tex) w/ no state change, 5057, 95.9%
A 3.5x performance boost in drawoverhead seemed pretty good, and it also cut my GLES3 CTS runtime by about 20%, so I think I’m done here for now.
After my recent Swiftshader misadventure, wherein I discovered that it’s missing (at least) transform feedback and conditional render extension support, meaning that it can’t be used to create a legitimate GL 3.0+ context, esoteric rendering expert Dave Airlie took benchmarking matters into his own hands today to battle it out against the other name-brand Vulkan CPU renderer.
The results were shocking.
Iago wrote recently a blog post about performance improvements on the v3d compiler, and introduced our plans to improve the pipeline caching (specifically the compiled shaders) (full blog here). We merged some improvements recently, so let’s talk about that work.
While analysing the perfomance of RBDOOM-3-BFG, we noticed that some significant CPU time was spent every frame for linking shaders.
After some investigation, we found that the game was calling ClearAttachment twice every frame. The implementation of those ClearAttachments was relying on a full job with a graphics pipeline. On v3dv by default any pipeline is created with a pipeline cache (provided by the user, or a default pipeline). On v3dv (and in general any Vulkan driver) the main cached data are the compiled shaders, so the main objective of the pipeline cache is avoiding full shader re-compilation on compatible pipelines that are used really often. Why was that time spent on linking shaders?
The issue was that for each pipeline lookup on the pipeline cache we were doing two cache lookups. The first one against a cache with the shaders in NIR, that is the main intermediate representation for shaders in Mesa (more info about intermediate representation here). And then we used those shaders to fill up the key for a second cache lookup, that if succesful, will return the compiled shader on Broadcom (QPU) assembly format.
The reason of this two-step lookup is that to compile a shader we call the common (for both OpenGL and Vulkan) Broadcom compiler, and we use some data structures that contain info that will affect the compilation (like if blending is enabled). When we implemented the pipeline cache support, for simplicity, we used the same data structures as part of the cache key. But as such keys were filled with info coming from the NIR shaders, those needed to be linked together on the case of the graphics pipelines.
When we analyzed how to improve it, we realized that in order to identify the compiled shader, we don’t really need the NIR shaders, as the info derived from them are implicit to the SPIR-V shaders provided to create the pipeline. Those NIR shaders are only really needed to compile the shader. The improvement here was using a different data structure as part of the cache key, and replace the two-cache-lookup with a one-cache-lookup. We needed to do some additional changes, as there were parts of the code that assumed that the NIR shaders would be available, but now if possible we are skipping getting them.
Let’s start showing the improvement with a synthetic test. We took one CTS test using a complex shader, and forced the pipeline to be re-recreated 1000 times. So we get the following times:
That’s a clear improvement. So how about real applications? As mentioned we started this work after analyze RBDOOM-3-BFG use of ClearAttachment. That game got an improvement of ~1fps. But when we tested other games we didn’t get any improvement on that case. This is because using a full job for ClearAttachment isn’t the preferred option (it is in fact the slowest path), and because the other games are GPU limited.
But we got improvements on other cases. As mentioned the advantage of creating the pipeline with a hot cache is that we avoid the shader recompilation, so it is far faster. And there are some apps that create pipelines at runtime. We found that this happens with the Unreal Engine 4 demos, specifically the Shooter Game. So, for example, we start the demo like this:
and then we decide to shot for the first time:
in order to render the shooting effect, new pipelines are created, and several shaders are compiled. Due all that extra work we experiment a noticiable FPS hiccup. We can visualize it with this graph:
On that graph we can see how we go from ~25fps to ~2fps. That is the shooting moment.
For this cases, the ideal would be to start the game with a pipeline cache loaded with the outcome of previous executions of the game. So adding a hack to simulate that situation, and focusing on the relevant stat in this case, that is the minimum FPS, we get the following:
As mentioned, the ideal would be that the applications used a pipeline cache when creating the pipelines, and that they stored the content on disk, and loaded it on following executions. Among other things, because the application would have more control about what to store and load at each moment (like for example: store/load the pipeline cache for a given level of a game).
The reality is that not all the applications do that. As mentioned, the numbers of the previous situation was simulating that ideal situation, but the application was not doing that. In order to mitigate that, we added support for on-disk-cache. Mesa provides a framework to store and load shaders on disk, so basically for any pipeline cacke lookup, now we have an extra fallback. In this case, for the UE4 Shooter demo, for a hot on-disk-cache we get a minimum of ~7fps, that as expected, is better that the situation before our work, but worse that the ideal case of the application handling the store/load of the pipeline cache on disk.
So some conclusions from this work, that applies to any Vulkan driver, not only v3dv in particular:
The blogging is happening once again, and it feels good.
I did a brief recap a couple posts ago, but I’ve gotten some sleep since then, and now it’s time for the real deal. Here’s what you missed while you were asleep and not following the Mesa RSS feed like all the coolest people I know:
Good times.
Last year, I have been working on Turnip driver development as my daily job at Igalia. One of those tasks was implementing the support for VK_KHR_depth_stencil_resolve extension.
This extension adds support for automatically resolving multisampled depth/stencil attachments in a subpass in a similar manner as for color attachments.
This extension, however, does not add support for resolving msaa depth/stencil images with vkCmdResolveImage() command.
As you can imagine, this extension is easy to use by any application. Unless you are using a driver that supports Vulkan 1.2 or higher (VK_KHR_depth_stencil_resolve was promoted to core in Vulkan 1.2), you should check first if it is supported. Once done that, ask the driver which features are supported by extending VkPhysicalDeviceProperties2 with VkPhysicalDeviceDepthStencilResolveProperties structure when calling vkGetPhysicalDeviceProperties2().
struct VkPhysicalDeviceDepthStencilResolveProperties {
VkStructureType sType;
void* pNext;
VkResolveModeFlags supportedDepthResolveModes;
VkResolveModeFlags supportedStencilResolveModes;
VkBool32 independentResolveNone;
VkBool32 independentResolve;
}
This structure will be filled by the driver to indicate the different depth/stencil resolve modes supported by the driver (more info about their meaning and possible values in the spec).
Next step: just fill a VkSubpassDescriptionDepthStencilResolve struct with the resolve mode wanted and the depth/stencil attachment used for resolve. Then, extend the VkSubpassDescription2 struct with it. And that’s all.
struct VkSubpassDescriptionDepthStencilResolve {
VkStructureType sType;
const void* pNext;
VkResolveModeFlagBits depthResolveMode;
VkResolveModeFlagBits stencilResolveMode;
const VkAttachmentReference2* pDepthStencilResolveAttachment;
}
Implementing this extension on Turnip was more or less direct, although there were some issues to fix.
For all depth/stencil formats, it was added its support in the both resolve paths used by the driver, one for sysmem (system memory) and other for gmem (tile buffer), including flushing the depth cache when needed. However, for VK_FORMAT_D32_SFLOAT_S8_UINT format, which has the stencil part in a separate plane, it was needed to add specific code to extend the 2D path used in the driver for sysmem resolves.
However the main issue when was testing the extension implementation on Adreno 630 GPU. It turns out that VK-GL-CTS tests exercising this extension for MSAA VK_FORMAT_D24_UNORM_S8_UINT formats were failing always, except when disabling UBWC via TU_DEBUG=noubwc environment variable. UBWC (Universal Bandwidth Compression) is a HW feature designed to improve throughput to system memory by minimizing the bandwidth of data (which also gives some power savings). The problem was that the UBWC support for MSAA VK_FORMAT_D24_UNORM_S8_UINT format is known to be failing on Adreno 630 and Adreno 618 (see merge request for freedreno driver). I just needed to disable it Turnip to fix these failures.
I also found other VK_KHR_depth_stencil_resolve CTS tests failing: the ones testing the format compatibility for VK_FORMAT_D32_SFLOAT_S8_UINT and VK_FORMAT_D24_UNORM_S8_UINT formats. For VK_FORMAT_D32_SFLOAT_S8_UINT failures, it was needed to take into account the particularity that it has a separate plane for the stencil part when resolving it to VK_FORMAT_S8_UINT. In the VK_FORMAT_D24_UNORM_S8_UINT failures, the problem was that we were setting wrongly the resolve mode used by the HW: it was wrongly doing a sample average, when we wanted to use the value of sample 0. This merge request fixed both issues.
And that’s all, this was a extension that allowed me to dive into the different resolve paths used by Turnip and learn one or two things about the HW ;-) Thanks a lot to Jonathan Marek for his reviews and suggestions to improve the implementation of this extension.
Happy hacking!
Lately, I have been looking at improving performance of the V3DV Vulkan driver for the Raspberry Pi 4. So far we had been toying a lot with some Vulkan ports of the Quake trilogy but we wanted to have a look at more modern games as well, and for that we started to look at some Unreal Engine 4 samples, particularly the Shooter demo.
Unreal Engine 4 Shooter Demo In our initial tests with “High” settings, even at 480p we were running the sample at 8-15 fps, with 720p being mostly in the 5-10 fps range. Not great, obviously, but a good opportunity to guide and focus our performance efforts.
One aspect of the UE4 sample that was immediately obvious compared to the Quake games is that the shading is a lot more expensive in general, and more specifically, it involves more texture lookups and UBO loads, which require expensive accesses to memory from the shader cores, so this was the first area we targeted. The good thing about this is that because our Vulkan and OpenGL drivers share the compiler stack, any optimizations we do here benefit both drivers.
What follows is a brief discussion of some of the optimizations we did recently to our backend compiler and the results we have observed from this work.
So the first thing we tackled was better managing the latency of texture lookups. Interestingly, the NIR scheduler was setting this up so that we would try to put instructions that consumed the result of a texture lookup as far away as possible from the instruction that triggered the lookup, but then the backend compiler was not fully taking advantage of this and would still end up waiting on lookup results sooner than it should.
Fixing this helped performance by 1%-3%, although it could go a bit above that in some cases. It has a caveat though: doing this extends the liveness of our lookup sequences, and that makes spilling more difficult (we can’t emit spills/unspills in the middle of an outstanding memory lookup), so when register pressure is high enough that we need to inject register spills to compile the shader, we would typically be a lot more constrained and end up producing significantly worse code, or even worse, failing to register allocate for the shader completely. To avoid this, we recompile the shader without the optimization if we detect that we need to do any spilling. One can use V3D_DEBUG=perf to detect if this is happening for any shaders, looking for messages like this:
Falling back to strategy 'disable TMU pipelining' for MESA_SHADER_FRAGMENT.
While the above optimization was useful, I was expecting that it would make a larger impact for this particular demo so I kept looking for ways to do our memory lookups more efficient. One thing that is relevant to this analysis is that we were using the same hardware unit for both texture and UBO lookups, but for the latter, we could really use a different strategy by handling our UBOs as uniform streams. This has some caveats, but making a long story short, the fact that many UBO loads use uniform addresses, that we usually read a bunch of consecutive scalars from a UBO load (such as a full vec4) and that applications usually emit UBO loads for nearby addresses together, we can emit fairly optimal code for many of these, leading to more efficient memory access in general.
Eventually, this turned out to be a big win, yielding 20%-30% improvements for the Shooter demo even with the initial basic implementation, which we would then tune and optimize further.
Again related to memory accesses, I have also been improving how we schedule instructions involved with setting up memory lookups. Our scheduler was more restrictive here than it needed, and the extra flexibility can help reduce instruction counts, which will affect these more modern games most, as they are more likely to emit a larger number of texture/image operations in their shaders.
Another thing we did was to improve instruction packing. The V3D GPU is able to emit multiple instructions in the same cycle so long as the instructions meet some requirements. Turns out our assembly scheduler was being too restrictive with this and we could do better. Going by shader-db results, this led to ~5% less instructions on our programs and added another modest 1%-2% performance improvement for the Shooter demo.
Another issue we noticed is that a lot of the shaders were passing a lot of varyings from the vertex to fragment shaders, and our setup for fragment shader inputs was not optimal. The issue here was that there is a specific instruction involved in this process that writes two registers, one of then with an instruction of delay, and our dependency tracking was not able to handle this properly, effectively assuming that both registers are written in the same instruction which then had an impact in how we scheduled instructions. Fixing this required to handle this case specially in our scheduler so we could be more effective at scheduling these instructions in a way that would enable optimal pipelining of the instructions involved with varying setups for fragment shaders.
Another aspect we improved was related to our uniform handling. Generally, there many instances in which we need to emit duplicate uniforms. There are reasons for that related to how the GPU works, but in some cases, for example with consecutive UBO loads, we would emit the uniform with the base address of the UBO multiple times very close to each other. We can obviously do better by trying to track previous uses of a uniform/constant value and reusing them in nearby instructions. Of course, this comes at the expense of increasing register pressure (for reasons beyond the scope of this post our shaders typically require a lot of uniforms), so there is a balancing game to play here too. Reducing the size of our uniform streams this way also plays an important role in lowering some of the CPU overhead of the driver, since these streams need to be rebuilt often when certain pipeline states change.
Finally, an optimization that was more targeted at reducing register pressure rather than improving performance: we noticed that we would sometimes put some instructions far away from their consumers with no obvious benefit to it. This was bad enough some times that it would even cause us to be unable to compile some shaders. Mesa has a handy NIR pass for this called nir_opt_sink, which also proved to be helpful for this. This allowed us to get a few more shaders from shader-db to compile and reduce spilling for a bunch of shaders. For the Shooter demo, this changed a large compute shader involved with histogram post-processing, which had 48 spills and 50 fills to only have 8 spills and 15 fills. While the impact in performance of this is probably very small since the game only runs this pass once per frame, it made a notable difference in loading time, since compiling a shader with this much spilling is very slow at present. I have a mental note to improve this some day, I know Intel managed to fix this for their compiler, but for the time being, this alone managed to make the loading time much more reasonable.
First, here are some shader-db stats, which describe how these optimizations change various statistics for a large collections of real world shaders:
total instructions in shared programs: 14992758 -> 13731927 (-8.41%) instructions in affected programs: 14003658 -> 12742827 (-9.00%) helped: 80448 HURT: 4297 total threads in shared programs: 407932 -> 412242 (1.06%) threads in affected programs: 4514 -> 8824 (95.48%) helped: 2189 HURT: 34 total uniforms in shared programs: 4069524 -> 3790401 (-6.86%) uniforms in affected programs: 2267834 -> 1988711 (-12.31%) helped: 40588 HURT: 1186 total max-temps in shared programs: 2388462 -> 2322009 (-2.78%) max-temps in affected programs: 897803 -> 831350 (-7.40%) helped: 30598 HURT: 2464 total spills in shared programs: 6241 -> 5940 (-4.82%) spills in affected programs: 3963 -> 3662 (-7.60%) helped: 75 HURT: 24 total fills in shared programs: 14587 -> 13372 (-8.33%) fills in affected programs: 11192 -> 9977 (-10.86%) helped: 90 HURT: 14 total sfu-stalls in shared programs: 28106 -> 31489 (12.04%) sfu-stalls in affected programs: 16039 -> 19422 (21.09%) helped: 4382 HURT: 6429 total inst-and-stalls in shared programs: 15020864 -> 13763416 (-8.37%) inst-and-stalls in affected programs: 14028723 -> 12771275 (-8.96%) helped: 80396 HURT: 4305
Less is better for all stats, except threads. We can see significant improvements across the board: we generally produce shaders with less instructions that have less maximum register pressure, we reduce spills and uniform counts and can run with more threads. We only are worse at stalls, but that is generally because we now produce more compact code with less instructions, so more stalls are expected.
Another good thing in these stats is the large number of helped shaders compared to hurt shaders, meaning that it is very likely that these optimizations will help most applications to some extent.
But enough of boring compiler statistics, most people won’t care about that and what they want to know is how this impacts performance on actual games and applications, which is what the following graphs shows (these were obtained by replaying specific traces with gfx-reconstruct). Keep in mind that while I am using a collection of Vulkan samples/games here it is expected that these optimizations apply to OpenGL too.
Before vs After 
Framerate improvement after optimization (in %) As it can be observed from the graph above, this optimization work made a significant impact in the observed framerate in all the cases. It is not surprising that the UE4 demo is the one that sees the most improvement, considering this the one we used to guide most of the optimization work.
In this post I have been focusing exclusively on compiler optimizations, but we have also been improving other parts of the Vulkan driver. While I won’t go into details to avoid making this post too long, we have also been improving aspects of the driver involved with buffer to image copies, depth buffer clears, dirty descriptor state management, usage of the TFU unit for transfer operations and more.
Finally, there is one other aspect of this UE4 demo that is pretty obvious as soon as you start a game: it can compile a lot of shaders in the middle of the gameplay loop which can lead to significant stutter. While there is not much we can do about this on the driver side, but adding support for a shader cache on disk should eliminate the problem on sessions after the first, so this is something that we may work on in the future.
We will certainly continue to look at improving the driver performance in the future so stay tuned for further updates on our progress or maybe join us at #videocore on Freenode.
I got a weird bug report the other day. Apparently Unigine Superposition, the final boss of Unigine benchmarks, was broken in zink(-wip). And it was a regression, which meant that at some point it had worked, but because testing is hard, it then stopped working for a while.
I had no idea what the problem was other than a vague impression it might be queue-related given the perf output in the bug report. The first step here was to figure out what I was dealing with. Off I went to the two horsemen of all queue-related bugs: zink_flush() and zink_fence_finish().
Here’s the latter of the two:
static bool
zink_fence_finish(struct zink_screen *screen, struct pipe_context *pctx, struct zink_tc_fence *mfence,
uint64_t timeout_ns)
{
pctx = threaded_context_unwrap_sync(pctx);
struct zink_context *ctx = zink_context(pctx);
if (screen->device_lost)
return true;
if (pctx && mfence->deferred_ctx == pctx && mfence->deferred_id == ctx->curr_batch) {
zink_context(pctx)->batch.has_work = true;
/* this must be the current batch */
pctx->flush(pctx, NULL, !timeout_ns ? PIPE_FLUSH_ASYNC : 0);
if (!timeout_ns)
return false;
}
/* need to ensure the tc mfence has been flushed before we wait */
bool tc_finish = tc_fence_finish(ctx, mfence, &timeout_ns);
struct zink_fence *fence = mfence->fence;
if (!tc_finish || (fence && !fence->submitted))
return fence ? p_atomic_read(&fence->completed) : false;
/* this was an invalid flush, just return completed */
if (!mfence->fence)
return true;
/* if the zink fence has a different batch id then it must have completed and been recycled already */
if (mfence->fence->batch_id != mfence->batch_id)
return true;
return zink_vkfence_wait(screen, fence, timeout_ns);
}
In short, the control flow goes:
mfence->fence) no longer belongs to the gallium sync object (mfence)So this is all fine and good, and it’s been working terrifically for many months. But I put a printf at the top, and it turns out this was being spammed nonstop during load with the app constantly checking the same sync object to see if it was finished.
It wasn’t finished.
Specifically, the return fence ? p_atomic_read(&fence->completed) : false; case was being hit, which led me to dig deeper into what was going on.
Another printf in zink_flush() (function contents omitted to spare the eyes of anyone under the legal drinking age) revealed that the sync object reaching zink_fence_finish was, in fact, the second one created by the app, which was then being waited upon twenty-something flushes later.
So in this case, mfence->deferred_id was something like 2 and the current batch id in ctx->curr_batch was around 20. The last-completed batch id was also around 20.
A slight modification here resolved the issue:
if (pctx && mfence->deferred_ctx == pctx) {
if (mfence->deferred_id == ctx->curr_batch) {
zink_context(pctx)->batch.has_work = true;
/* this must be the current batch */
pctx->flush(pctx, NULL, !timeout_ns ? PIPE_FLUSH_ASYNC : 0);
if (!timeout_ns)
return false;
}
/* this batch is known to have finished */
if (mfence->deferred_id <= screen->last_finished)
return true;
}
This way, cases where an app is randomly waiting on something that has finished so far in the past that there’s no longer any trace of it can just become a no-op success, and everything is happy.
Probably.
Testing is ongoing, but it seems like everything is happy now.
As we are heading towards April and the release of Fedora Workstation 34 I wanted to post an update on what we are working on for this release and what we are looking at going forward. 2020 was a year where we focused a lot on polishing what we had and getting things past the finish line and Fedora Workstation 34 is going to be the culmination of that effort in many ways.
Wayland:
The big ticket item we have wanted to close off on was Wayland, because while Wayland has been production ready for most of us for a while, there was still some cases it didn’t cover as well as X.org. The biggest of this was of course the lack of accelerated XWayland support with the binary NVidia driver. Fixing that issue of course wasn’t something we could do ourselves, but we have been working diligently with our friends at NVidia to help ensure everything was in place for them to enable that support in their driver, so I have been very happy to see the public reports confirming that NVidia will have accelerated 3D in the summer release of their driver. The other Wayland area we have put a lot of effort into has been the work undertaken by Jonas Ådahl to get headless display support working with Wayland. This is a critical feature for people who for instance want a desktop instance on their servers or in the cloud, who want a desktop they access through things like VNC or RDP to use for sysadmin related tasks. Jonas spent a lot of time laying the groundwork for this over the course of last year and we are now in the final stages of merging the patches to enable this feature in GNOME and Wayland in preparation for Fedora Workstation 34. Once those two items are out we consider our Wayland rampup/rollout to be complete, so while there of course will continue to be bugfixes and new features implemented, that will be part of a natural evolution of Wayland and not part of a ‘close gaps with X11’ effort like now.
PipeWire
Another big ticket item we are hoping to release fully in Fedora Workstation 34 is PipeWire. PipeWire as most of you know is the engine we use to deal with handling video streams in a secure and shareable away in Fedora Workstation, so when you interact with your web camera(s) or do screen casting or make screenshots it is all routed and handled by PipeWire. But in Fedora Workstation 34 we are aiming to also switch to using PipeWire for audio, to replace both PulseAudio and Jack. For those of you who had read any previous blog post from me you will know what an important step forward this will be as we would finally be making the pro-audio community first class citizens in Fedora Workstation and Linux in general. When we decided to try to switch to PipeWire in Fedora Workstation 34 I have to admit I was a little skeptical about if we would be able to get all things ready in time as there are so many things that needs to be tested and fixed when you switch out such a critical component. Up to that point we had a lot of people interested in PipeWire, but only limited community involvement, but I feel the announcement of bringing in PipeWire for Fedora Workstation 34 galvanized the community around the project and we now have a very active community around PipeWire in #pipewire on the freenode IRC network. Not only is Wim Taymans getting a ton of help with testing and verification, but we also see a stead stream of patches coming in, with for instance improved Bluetooth audio support being contributed, in fact I believe that PipeWire will be able to usher in better bluetooth audio support in Fedora than we ever had before, with great support for high quality Bluetooth audio codecs like LDAC.
I am especially happy to see so many of the key members of the pro-audio Linux community taking part in this effort and is of course also happy to see many pro-audio folks testing Fedora Workstation for the first time due to this effort. The community is working closely with Wim to test and verify as many important ProAudio applications as possible and work to update Fedora packaging as needed to ensure they can transition from Jack to PipeWire without dependency conflicts or issues. One last item to mention here is that you might have seen that Red Hat is getting into the automotive space, I can’t share a lot of details about that effort, but one thing I can say is that PipeWire will be a core part of it and thus we will soon be looking to hire more engineers to work on PipeWire, so if that is of interest to you be sure to track my twitter feed or blog as I will announce our job openings there as they become available. For the community at large this should be great too as it means that we can get a lot of synergy between automotive and the desktop around audio and video handling.
It is still somewhat of an open question if we end up actually switching to PipeWire in Fedora Workstation 34, but things are looking good at this point in time and worst case scenario it will be in place for Fedora Workstation 35.
Toolbox
Toolbox is another effort that is in a great spot now. Toolbox is our tool for making working with pet containers a breeze for developers. The initial version was prototyped quickly by writing it as a shell script, but we spent time last year getting it rewritten in Go in order to make it possible to keep expanding the project and allow us to implement all the things we envision for it. With that done feature work is now in focus again and Ondřej Michal has done some great work making it possible to set up RHEL containers in Toolbox. This means that you can run Fedora on your laptop and get the latest and greatest features that way, but you can do your development in a RHEL pet container, so you get an environment identical to what you applications will see once they are deployed into the cloud or onto company hardware. This gives you the best of both worlds in my opinion, the fast moving Fedora Workstation that brings the most out of our laptop and desktop hardware, but still easy access to the RHEL platform for development and testing. You can even test this today on Fedora Workstation 33, just open a terminal and type ‘toolbox create --distro rhel --release 8.3‘. The resulting toolbox will then be based on RHEL and not Fedora and thus perfect for doing RHEL targeted development. You will need to use the subscription-manager tool to register it (be sure to register on developer.redhat.com for your free RHEL developer subscription. Over time we hope to integrate this into GNOME Online accounts like we do for the RHEL virtual machines you can set up with GNOME Boxes, so that once you set up your RHEL account you can create RHEL virtual machines and RHEL containers easily on Fedora Workstation.
Toolbox pet container with RHEL UBI
Flatpak
Owen Taylor has been doing some incredible work behind the scenes for the last year trying to ensure the infrastructure we have in RHEL and Fedora provides a great integrated Flatpak experience. As we move forward we expect Flatpaks to be the primary packaging format that Fedora users consume their applications in, but to make that a reality we needed to ensure the experience is good both for Fedora maintainers and for the end users. So one of the big ticket items Owen been working on is getting incremental updates working in Fedora. If you have used applications from Flathub you probably noticed that their updates are small and nimble despite being packaged as Flatpak containers, while the Fedora flatpaks causes big updates each time. The reason for this is that the Fedora flatpaks are shipping as OCI (Open Container Initiative) images, while the Flatpaks on Flathub are shipping as OStree repositories (if you don’t know OStree, think of it as git for binaries). So shipping the Flatpaks as OCI images has advantages in the form of being the same format we at Red Hat use for our kubernetes/docker/openshift containers and thus it allows us to reuse a lot of the work that Red Hat as put into ensuring we can provide and keep such containers up to date and secure, but the downside until now has been that these containers where shipped in a way which cause each update, no matter how small the change, to be a full re-download of the whole image. Well Owen Taylor and Alex Larsson worked together to resolve this and came up with a method to allow incremental updates of such containers and thus bring the update sizes in line with what you see on Flathub for Flatpaks. This should be deployed in time for Fedora Workstation 34 and we also hope to eventually deploy it for kubernetes/docker containers too. Finally to make even more applications available we are doing work to enable people to get access to Flathub.org out of the box in Fedora when you enable 3rd party repositories in initial setup, so that your our of the box application selection will be even bigger.
Flathub webpage
GNOME 40
Another major change in Fedora Workstation 34 is GNOME40 which contains a revamp of the GNOME 3 user interface. This was a collaborative effort between a lot of GNOME 3 stakeholders with Allan Day representing Red Hat. This was also an effort by the GNOME design community to up their game and thus as part of the development process the GNOME Foundation paid a professional company to do user testing on the proposed changes and some of the alternatives. This means that the changes where verified to actually be experienced as an improvement for the experienced GNOME user participants and that it felt intuitive for new users of GNOME. One advantage we have in Fedora is that since we don’t do major tweaking of the GNOME user interface which means once Fedora Workstation 34 ships you are set to enjoy the new GNOME experience from day one. For long time GNOME users I hope and expect that the updates will be a welcome refresh and at the same time that the changes provide a more easy onramp for new GNOME and Fedora Workstation users. Some of the early versions did lead some long term fans of how multimonitor support in GNOME3 worked to be a bit concerned, but be assured that multi monitor is a critical usecase in our opinion and something we have been looking at and will be looking at keep improving. In fact Allan Day wrote a great blog post about GNOME40 multimonitor support recently to explain what we are doing and how we see it evolving going forward.
Input
Another area where we keep putting in a lot of effort is input. Thanks to Peter Hutterer and Benjamin Tissoires we keep making sure Fedora Workstation and the world of Linux keeps having access to the newest and best in input. The latest effort they are working on has been to enable haptic touchpads. Haptics touchpads should be familiar among people who tried Apple hardware, but they are expected to appear in force on laptops in general this year, so we have been putting in the effort to ensure that we can support this new type of device as they come out. So if you see laptops you want with haptic touchpads then Fedora Workstation should be ready for it, but of course until these devices are commonplace and we had a chance to test and verify I can make no guarantees.
Another major effort that we undertook in relation to input was move the GNOME input to a separate thread. Carlos Garnacho worked on this patch to make that happen. This should provide a smoother experience with Fedora Workstation 34 as it means the mouse should not stall due to the main thread running Wayland being busy. This was done as part of the overall performance work we been continuously doing over the last years to ensure to address performance issues and make Fedora and GNOME have the best performance and performance related behaviour possible.
Lenovo Laptops
So one of the major announcements of last year was Lenovo Laptops with Fedora Linux pre-installed. There are currently two models available with Linux, the X1 Carbon and the Lenovo P1. Between them they cover the two most commons requests we see, a ultralight weight laptop with the X1 and a more powerful ‘portable workstation’ model with the P1. We are working on a couple of more models and also to get them sold globally, which was key goal of the effort. Be aware that both models are on sale as I am writing this (hopefully still true when you read this), so it is a good time to grab a great laptop with a great OS.
Lenovo P1
Vision
So one thing I wanted to do to is tie the work we do in Fedora Workstation together by articulating what we are trying to achieve. Fedora has for the longest time been the place where Linux as an operating system is evolving and being developed. There are very few major innovations that has come to Linux that hasn’t been developed and incubated in Fedora by Fedora contributors, including of course Red Hat. This include things like the Linux Vendor Firmware Service, Wayland, Flatpak, SilverBlue, PipeWire, SystemD, flicker free boot, HiDPI support, gaming mouse support and so much more. We have always done this work in close cooperation with the upstreams we are collaborating with, which is why the patch delta in any given Fedora release is small. We work hard to get improvements into the upstream kernel and into GNOME and so on right away, to avoid needing to ship downstream patches in Fedora. That of course saves us from having to maintain temporary forks, but more importantly it is the right way to collaborate with an open source community.
So looking back to when we launched Fedora Workstation we realized that being at the front like that had come at the cost of not being stable and user friendly. So the big question we tried to ask ourselves when launching Fedora Workstation and the question that still drives a lot of our decision making and focus is : how can we preserve being the heart and center of Linux OS development, but at the same time provide end users with a stable and well functioning system? To achieve that we have done lot of changes over the last years, ranging from some policy changes in terms of how and when we brought changes into Fedora, but maybe even more importantly we focused on a lot on figuring out ways to reduce the challenges caused by a rapidly evolving OS, like the introduction of Flatpaks to allow applications to be developed and released without strong ties to the host system libraries and with the concepts we are maturing in Silverblue around image based operating systems or how we are looking at pet container development with Toolbox. All of these things combined remove a lot of the fragility we seen in Linux up to this point and instead let us treat the rapidly evolving linux landscape as a strength.
So where we are today is that I think we are very close to realizing the vision of being able to let Fedora be the place where exiting new stuff happens, yet at the same time provide the robustness and polish that end users need to be able to use it as their daily driver, it has been my daily driver for many years now and by the rapid growth of users we seen in Fedora over the last 5 years I think that is true for a lot of other people too. The goal is to allow the wider community around Linux, especially the developers, sysadmins and creators relying on Linux to do their work, to come to Fedora and interact and collaborate with the developers working on the OS itself to the benefit of all. You all are probably better judges than me to if we are succeeding with that, but I do take the increased chatter and adoption of Fedora by a lot of people doing Linux related podcasts, news sites and so on as a sign that we are succeeding. And PipeWire for me is a perfect example of how this can look, where we want to bring in the pro-audio creators to Fedora Workstation and let them interact and work closely with Wim Taymans and the PipeWire development team to make the experience even better for themselves and their fellow creators and at the same time give them a great stable platform to create their music on.
Over the last year and then so, we at Collabora have been working with Microsoft on their D3D12 mapping layer, which I announced in my previous blog post. In July, Louis-Francis Ratté-Boulianne wrote an update on the status on the Collabora blog, but a lot has happened since then, so it’s time for another update.
There’s two major things that has happened since then; we have passed the OpenGL 3.3 conformance tests, and we have upstreamed the code in Mesa 3D.
It might not be a big surprise, but one of the motivation for this work was to be able to run applications like Photoshop on Windows devices without full OpenGL support.
I’m happy to report that Microsoft has released their compatibility pack that uses our work to provide OpenGL (and OpenCL) support, Photoshop can now run on Windows on ARM CPUs! This is pretty exciting to see high-profile applications like that benefit from our work!
First of all, I would like to point out that having passed the OpenGL CTS isn’t necessarily the same as being formally conformant. There’s some details about how to formally becoming conformant on layered implementations that are complicated, and I’ll leave the question about formal conformance up to Microsoft and Khronos.
Instead, I want to talk a bit about passing the OpenGL CTS.
A problem we face with layered implementations is that we are subject to a few more sources of issues, some of which are entirely out of our control. A normal OpenGL, non-layered, implementation have two primary sources of issues:
Issues with the OpenGL driver itself that leads to tests failing is always required to be fixed before results are submitted. Issues with the hardware generally requires software workarounds, but this is not always feasible, so Khronos have a system where a vendor can file a waiver for a hardware issue, and if approved they can mark test-failures as waived, and the appropriate failures will be ignored.
So far so good.
But for our layered implementations, our world looks a bit different. We don’t really see the hardware, but instead we see D3D12 and the D3D12 driver. This means our sources of issues are:
For the OpenGL driver, the story is the same as for a non-layered implementation, but from there on things start changing.
Problems in the D3D12 run-time must also be fixed before submitting results. We work together with Microsoft to get these issues fixed as appropriate. Such fixes can take a while to trickle all the way into a Windows build and to end-users, but they will eventually show up.
But for the D3D12 vendor-driver and below, things gets complicated. First of all, it’s not always possible for us to tell vendor-driver issues and hardware issues apart. And worse, as these are developed by third party companies, we have little insight there. We can’t affect their priorities, so it’s hard to know when or even if an issue gets resolved.
It’s also not really a good idea to work around such issues, because if they turn out to be fixable software problems, we don’t know when they will be fixed, so we can’t really tell when to disable the work-around. We also don’t know exactly what combination of hardware and software these issues apply to.
But there’s one case where we have full insight, and that’s when the D3D12 vendor-driver is WARP, a high-performance software rasterizer. Because that component is developed by Microsoft, and we have channels to report issues and even make sure they get resolved!
When developing something new, there’s always going to be bugs. But usually also when using something existing in a new way. We encountered a lot of bugs on our way, and here’s a quick overview over some of them. This is in no way exhaustive, and most of our own bugs are not that interesting. So this is mostly about problems unique to layered implementations.
It turned out early on that the DXIL validator in D3D12 had a requirement when parsing the LLVM bitcode that required that the amounts were always 32-bit values. While this seems fine by itself, LLVM itself requires that all operands to binops have the same bit-size. This obviously meant that only 32-bit shifts could pass the validator.
Microsoft quickly removed this requirement once we figured out what was going on.
In D3D12, one requirement for block-compressed textures is that the base-level is aligned to ther block-size. This requirement does not apply to mip-levels, and OpenGL has no such requirement. This isn’t technically speaking a bug, but a documented limitation in DirectX.
It turns out that this limitation was an artificial historical left-over, and after a bunch of testing (and fixing of WARP), we got this limitation lifted. Great :)
Something that has been much more frustrating is bugs in the vendor-drivers. The problem here is that even though we have channels to file bugs, we don’t have any influence or even insight into their prioritization and release schedule.
I think it suffice to say that there’s been several reported bugs to all vendors we’ve actively been running the OpenGL CTS on top of. We believe fixes are underway for at least some of this, but we can’t make any promises here.
Right now, the only configurations we’re cleanly passing the OpenGL 3.3 CTS on are WARP (which became conformant on November 24th, 2020), and NVIDIA (which became conformant on February 26th, 2021).
Having these multiple independent implementations of DirectX drivers passing in conjunction with the Mesa/D3D12 layer shows that we are able to implement GLon12 in a vendor-neutral way, which allowed us to bring the layer to conformance. Many thanks to Khronos for their assistance through this process.
We’ve also submitted results on top of an Intel GPU, but that submission has been halted due to failures, and will as far as I know be updated as soon as Intel publish updated drivers.
The conformance tests have been run against our downstream fork, which is no longer actively maintained, because:
The D3D12 driver was upstreamed in Mesa in Merge-Request 7477, and the OpenCL compiler followed in Merge-Request 7565. There’s been a lot more merge-requests since then, and even more is expected in the future.
The process of upstreaming the driver into Mesa3D went relatively smoothly, but there were quite a lot of regressions that happened quickly after we upstreamed the code, so to avoid this from becoming a big problem we’ve added the D3D12 driver to Mesa’s set of GitLab CI tests. We now build and test the D3D12 driver on top of WARP on CI, as well as running some basic sanity-tests for the OpenCL compiler.
All in all, this seems to work very well right now, and we’re looking forward to the future. Next step, WSL support!
I’m no longer working full-time on this project, instead I’m trying to take some of the lessons learned and apply them to Zink. I’m sure there’s even more room for code-reuse than what we currently have, but it will probably take some time to figure out.
It was created by Konstantin Ryabitsev and has become a very frequently used tool for me.
It supports a lot of different ways for interacting with the Linux Kernel mailing lists.
Of these the b4 am subcommand is what I primarily use. This subcommand downloads all of
the patches belonging to a patch series and drops them into a .mbox file. But! It doesn't
apply them to the repository we're currently in, and herein lies the itch that I would like
to scratch.
The inspiration for this post is the script that @stellarhopper authored and @widawsky pointed out to me.
After first publishing this post, people on the twittersphere suggested some alternative approaches, and it would seem that there …
One of the best decisions I did in my life was when I joined Igalia in 2012. Inside Igalia, I have been working in different open-source projects, most of the time related to graphics technologies, interacting with different communities, giving talks, organizing conferences and, more importantly, contributing to free software as my daily job.
Now I’m thrilled to announce that we are hiring for our Graphics team!
Right now we have two open positions:
We are looking for candidates that would like to contribute to open-source OpenGL/Vulkan graphics drivers (Mesa), or other areas of the open-source graphics stack such as X11 or Wayland, among others. If you have experience with them, or you are very motivated to become an expert there, just send us your CV!
We are looking for candidates that either have experience with kernel development or they can ramp-up quickly to contribute to linux kernel drivers. Although no specific subsystem is mentioned in the job position, I encourage you to apply if you have DRM experience and/or ARM[64]/MIPS related knowledge.
Graphics technologies are not your cup of tea? We have positions in other areas like browsers, compilers, multimedia… Just check out our job offers on our website!
What we offer is to work in an open-source consultancy in which you can participate equally in the management and decision-making process of the company via our democratic, consensus-based assembly structure. As all of our positions are remote-friendly, we welcome submissions from any part of the world.
Are you still a student? We have launched the 2021 edition of our Coding Experience program. Check it out!
It is extremely rare that a hobby software project of mine gets completed, but now it has happened. Behold! Fourbyfour!
Have you ever had to implement a mathematical algorithm, say, matrix inversion? You want it to be fast and measuring the speed is fairly simple, right. But what about correctness? Or precision? Behavior around inputs that are on the edge? You can hand-pick a few example inputs, put those into your test suite, and verify the result is what you expect. If you do not pick only trivial inputs, this is usually enough to guarantee your algorithm does not have fundamental mistakes. But what about those almost invalid inputs, can you trust your algorithm to not go haywire on them? How close to invalid can your inputs be before things break down? Does your algorithm know when it stops working and tell you?
Inverting a square matrix requires that the inverse matrix exists to begin with. Matrices that do not mathematically have an inverse matrix are called singular. Can your matrix inversion algorithm tell you when you are trying to invert a matrix that cannot be inverted, or does it just give you a bad result pretending it is ok?
Working with computers often means working with floating-point numbers. With floating-point, the usual mathematics is not enough, it can actually break down. You calculate something and the result a computer gives you is total nonsense, like 1+2=2 in spirit. In the case of matrix inversion, it's not enough that the input matrix is not singular mathematically, it needs to be "nice enough" numerically as well. How do you test your matrix inversion algorithm with this in mind?
These questions I tried to answer with Fourbyfour. The README has the links to the sub-pages discussing how I solved this, so I will not repeat it here. However, as the TL;DR, if there is one thing you should remember, it is this:
Do not use the matrix determinant to test if a matrix is invertible!
Yes, the determinant is zero for a singular matrix. No, close to zero determinant does not tell you how close to singular the matrix is. There are better ways.
However, the conclusion I came to is that if you want a clear answer for a specific input matrix, is it invertible, the only way to know for sure is to actually invert it, multiply the input matrix with the inverse you computed, and measure how far off from the identity matrix it is. Of course, you also need to set a threshold, how close to identity matrix is close enough for your application, because with numerical algorithms, you will almost never get the exact answer. Also, pick an appropriate matrix norm for the matrix difference.
The reason for this conclusion is what one of the tools I wrote tells me about a matrix that would be typical for a display server with two full-HD monitors. The matrix is simply the pixel offset of the second monitor on the desktop. The analysis of the matrix is the example I used to demonstrate fourbyfour-analyse. If you read through it, you should be shocked. The mathematics, as far as I can understand, seems to tell us that if you use 32-bit floating-point, inverting this matrix gives us a result that leads to no correct digits at all. Obviously this is nonsense, the inverse is trivial and algorithms should give the exact correct result. However, the math does not lie (unless I did). If I did my research right, then what fourbyfour-analyse tells us is true, with an important detail: it is the upper error bound. It guarantees that we cannot get errors larger than that (heh, zero correct digits is pretty hard to make much worse). But I also read that there is no better error bound possible for a generic matrix inversion algorithm. (If you take the obvious-to-human constraints into account that those elements must be one and those must be zero, the analysis would likely be very different.) Therefore the only thing left to do is to actually go on with the matrix inversion and then verify the result.
Here is a list of the cool things the Fourbyfour project does or has:
I you want to learn about numerical methods for matrices, I recommend the book Gene H. Golub, Charles F. van Loan, Matrix Computations. The Johns Hopkins University Press. I used the third edition, 1996, when implementing the Weston matrix inversion years ago.
In a now pretty well established tradition on my part, I am posting on things I no longer work on!
I gave a talk on modifiers at XDC 2017 and Linux Plumbers 2017 audio only. It was always my goal to have a blog post accompany the work. Relatively shortly after the talks, I ended up leaving graphics and so it dropped on the priority list.
I'm splitting this up into two posts. This post will go over the problem, and solutions. The next post will go over the implementation details.
Each 3d computational unit in an Intel GPU is called an Execution Unit (EU). Aside from what you might expect them to do, like execute shaders, they may be used for copy operations (itself a shader), or compute operations (also, shaders). All of these things require memory bandwidth in order to complete their task in a timely manner.
Modifiers were the chosen solution in order to allow end to end renderbuffer [de]compression to work, which is itself designed to reduce memory bandwidth needs in the GPU and display pipeline. End to end renderbuffer compression simply means that through all parts of the GPU and display pipeline, assets are read and written to in a compression scheme that is capable of reducing bandwidth (more on this later).
Modifiers are relatively simple concept. They are modifications that are applied to a buffer's layout. Typically a buffer has a few properties, width, height, and pixel format to name a few. Modifiers can be thought of as ancillary information that is passed along with the pixel data. It will impact how the data is processed or displayed. One such example might be to support tiling, which is a mechanism to change how pixels are stored (not sequentially) in order for operations to make better use of locality for caching and other similar reasons. Modifiers were primarily designed to help negotiate modified buffers between the GPU rendering engine and the display engine (usually by way of the compositor). In addition, other uses can crop up such as the video decode/encode engines.
My understanding is that even now, 3 years later, full modifier support isn't readily available across all corners of the graphics ecosystem. Many hardware features are being entirely unrealized. Upstreaming sweeping graphics features like this one can be very time consuming and I seriously would advise hardware designers to take that into consideration (or better yet, ask your local driver maintainer) before they spend the gates. If you can make changes that don't require software, just do it. If you need software involvement, the longer you wait, the worse it will be.
They weren't new even when I made the presentation 3.5 years ago.
commit e3eb3250d84ef97b766312345774367b6a310db8
Author: Rob Clark <robdclark@gmail.com>
Date: 6 years ago
drm: add support for tiled/compressed/etc modifier in addfb2
I managed to land some stuff:
commit db1689aa61bd1efb5ce9b896e7aa860a85b7f1b6
Author: Ben Widawsky <ben@bwidawsk.net>
Date: 3 years, 7 months ago
drm: Create a format/modifier blob
Back of the envelope requirement for a midrange Skylake GPU from the time can be calculated relatively easily. 4 years ago, at the frequencies we run our GPUs and their ISA, we can expect roughly 1GB⁄s for each of the 24 EUs.
A 4k display:
3840px × 2160rows × 4Bpp × 60HZ = 1.85GB⁄s
24GB⁄s + 1.85GB⁄s = 25.85GB⁄s
This by itself will oversaturate single channel DDR4 bandwidth (which was what was around at the time) at the fastest possible clock. As it turns out, it gets even worse with compositing. Most laptops sporting a SKL of this range wouldn't have a 4k display, but you get the idea.
The picture (click for larger SVG) is a typical "flow" for a composited desktop using direct rendering with X or a Wayland compositor using EGL. In this case, drawing a Rubik's cube looking thing into a black window.
Admiring the problemUsing this simple Rubik's cube example I'll explain each of the steps so that we can understand where our bandwidth is going and how we might mitigate that. This is just the overview, so feel free to move on to the next section. Since the example will be trivial, and the window is small (and only a singleton) it won't saturate the bandwidth, but it will demonstrate where the bandwidth is being consumed, and open up a discussion on how savings can be achieved.
For the example, no processing happens other than texturing. In a simple world, the processing of the shader instructions doesn't increase the memory bandwidth cost. As such, we'll omit that from the details.
The main steps on how you get this Rubik's cube displayed are
More details below...
Getting the texture from the application, usually from disk, into main memory, is what I'm referring to as texture upload. In terms of memory bandwidth, you are using write bandwidth to write into the memory.
Assets are transfered from persistent storage to memoryTextures may either be generated by the 3d application, which would be trivial for this example, or they may be authored using a set of offline tools and baked into the application. For any consequential use, the latter is predominantly used. Certain surface types are often dynamically generated though, for example, the shadow mapping technique will generate depth maps. Those dynamically generated surfaces actually will benefit even more (more later).
This is pseudo code (but close to real) to upload the texture in OpenGL:
const unsigned height = 128;
const unsigned width = 64;
const void *data = ... // rubik's cube
GLuint tex;
glGenTextures(1, &tex);
glBindTexture(GL_TEXTURE_2D, texture);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, width, height, 0, GL_RGB, GL_UNSIGNED_BYTE, data);
glGenerateMipmap(GL_TEXTURE_2D);
I'm going to punt on explaining mipmaps, which are themselves a mechanism to conserve memory bandwidth. If you have no understanding, I'd recommend reading up on mipmaps. This wikipedia article looks decent to me.
Once the texture is bound, the graphics runtime can execute shaders which can
reference those textures. When the shader requests a color value (also known as
sampling) from the texture, it's possiblelikely that the calculated
coordinate within the texture will be in between pixels. The hardware will have
to return a single color value for the sample point and the way it interpolates
is chosen by the graphics runtime. This is referred to as a filter
 |
|---|
| Texture Fetch/Filtering |
Here's the GLSL to fetch the texture:
#version 330 uniform sampler2D tex; in vec2 texCoord; out vec4 fragColor; void main() { vec4 temp = texelFetch(tex, ivec2(texCoord)); fragColor = temp; }
The above actually does something that's perhaps not immediately obvious. fragColor = temp;. This actually instructs the fragment shader to write out that value to a surface which is bound for output (usually a framebuffer). In other words, there are two steps here, read and filter a value from the texture, write it back out.
The part of the overall diagram that represents this step:
In the old days of X, and even still when not using the composite extension, the graphics applications could be given a window to write the pixels directly into the resulting output. The X window manager would mediate resize and move events, letting the client update as needed. This has a lot of downsides which I'll say are out of scope here. There is one upside that is in scope though, there's no extra copy needed to create the screen composition. It just is what it is, tearing and all.
If you don't know if you're currently using a compositor, you almost certainly are using one. Wayland only composites, and the number of X window managers that don't composite is very few. So what exactly is compositing? Simply put it's a window manager that marshals frame updates from clients and is responsible for drawing them on the final output. Often the compositor may add its own effects such as the infamous wobbly windows. Those effects themselves may use up bandwidth!
 |
|---|
| Simplified compositor block diagram |
Applications will write their output into what's referred to as an offscreen buffer. 👋👋 The compositor will read the output and copy it into what will become the next frame. What this means from a bandwidth consumption perspective is that the compositor will need to use both read and write bandwidth just to build the final frame. 👋👋
It's the mundane part of this whole thing. Pixels are fetched from memory and pushed out onto whatever display protocol.
 |
|---|
| Display Engine |
Perhaps the interesting thing about the display engine is it has fairly isochronous timing requirements and can't tolerate latency very well. As such, it will likely have a dedicated port into memory that bypasses arbitration with other agents in the system that are generating memory traffic.
Out of scope here but I'll briefly mention, this also gets a bit into tiling. Display wants to read things row by row, whereas rendering works a bit different. In short this is the difference between X-tiling (good for display), and Y-tiling (good for rendering). Until Skylake, the display engine couldn't even understand Y-tiled buffers.
Running through our 64x64 example...
| Operation | Color Depth | Description | Bandwidth | R/W |
|---|---|---|---|---|
| Texture Upload | 1Bpc (RGBX8) | File to DRAM | 16KB (64 × 64 × 4) | W |
| Texel Fetch (nearest) | 1Bpc | DRAM to Sampler | 16KB (64 × 64 × 4) | R |
| FB Write | 1Bpc | GPU to DRAM | 16KB (64 × 64 × 4) | W |
| Compositing | 1Bpc | DRAM to DRAM | 32KB (64 × 64 × 4 × 2) | R+W |
| Scanout | 1Bpc | DRAM to PHY | 16KB (64 × 64 × 4) | R |
Total = (16 + 16 + 16 + 32 + 16) × 60Hz = 5.625MB⁄s
But actually, Display Engine will always scanout the whole thing, so really with a 4k display:
Total = (16 + 16 + 16 + 32 + 32400) × 60Hz = 1.9GB⁄s
Don't forget about those various filter modes though!
| Filter Mode | Multiplier (texel fetch) | Total Bandwidth |
|---|---|---|
| Bilinear | 4x | 11.25MB⁄s |
| Trilinear | 8x | 18.75MB⁄s |
| Aniso 4x | 32x | 63.75MB⁄s |
| Aniso 16x | 128x | 243.75MB⁄s |
Without actually doing math, I think cache is probably the biggest win you can get. One spot where caching could help is that framebuffer write step followed composition step could avoid the trip to main memory. Another is the texture upload and fetch. Assuming you don't blow out your cache, you can avoid the main memory trip.
While caching can buy you some relief, ultimately you have to flush your caches to get the display engine to be able to read your buffer. At least as of 2017, I was unaware of an architecture that had a shared cache between display and 3d.
Also, cache sizes are limited...
Instead of doing anything, why not just wait until memory gets higher bandwidth?
Here's a quick breakdown of the progression at the high end of the specs. For the DDR memory types, I took a swag at number of populated channels. For a fair comparison, the expectation with DDR is you'll have at least dual channel nowadays.
Looking at the graph it seems like the memory vendors aren't hitting Moore's Law any time soon, and if they are, they're fooling me. A similar chart should be made for execution unit counts, but I'm too lazy. A Tigerlake GT2 has 96 Eus. If you go back to our back of the envelope calculation we had a mid range GPU at 24 EUs, so that has quadrupled. In other words, the system architects will use all the bandwidth they can get.
Improving memory technologies is vitally important, it just isn't enough.
TOTAL SAVINGS = 0%
One obvious place we want to try to reduce bandwidth is composition. It was after all the biggest individual consumer of available memory bandwidth.
With composition as we described earlier, there was presumed to be a single plane. Software would arrange the various windows onto the plane, which if you recall from the section on composition added quite a bit to the bandwidth consumption, then the display engine could display from that plane.
Hardware composition is the notion that each of those windows could have a separate display plane, directly write into that, and all the compositor would have to do is make sure those display planes occupied the right part of the overall screen. It's conceptually similar to the direct scanout we described earlier in the section on composition.
| Operation | Color Depth | Description | Bandwidth | R/W |
|---|---|---|---|---|
TOTAL SAVINGS = 1.875MB⁄s (33% savings)
33% savings is really really good, and certainly if you have hardware with this capability, the driver should enable it, but there are some problems that come along with this that make it not so appealing.
So far in order to solve the, not enough bandwidth, problem, we've tried to add more bandwidth, and reduce usage with hardware composition. The next place to go is to try to tackle texture consumption from texturing.
If you recall, we split the texturing up into two stages. Texture upload, and texture fetch. This third proposed solution attempts to reduce bandwidth by storing a compressed texture in memory. Texture upload will compress it while uploading, and texture sampling can understand the compression scheme and avoid doing all the lookups. Compressing the texture usually comes with some unperceivable degradation. In terms of the sampling, it's a bit handwavy to say you reduce by the compression factor, but let's say for simplicity sake, that's what it does.
Some common formats at the time of the original materials were
| Format | Compression Ratio |
|---|---|
| DXT1 | 8:1 |
| ETC2 | 4:1 |
| ASTC | Variable, 6:1 |
Using DXT1 as an example of the savings:
| Operation | Color Depth | Bandwidth | R/W |
|---|---|---|---|
| Texture Upload | DXT1 | 2KB (64 × 64 × 4 / 8) | W |
| Texel Fetch (nearest) | DXT1 | 2KB (64 × 64 × 4 / 8) | R |
| FB Write | 1Bpc | 16KB (64 × 64 × 4) | W |
| Compositing | 1Bpc | 32KB (64 × 64 × 4 × 2) | R+W |
| Scanout | 1Bpc | 16KB (64 × 64 × 4) | R |
Here's an example with the simple DXT1 format:
Texture compression solves a couple of the limitations that hardware composition left. Namely it can work for full screen applications, and if your hardware supports it, there isn't a limit to how many applications can make use of it. Furthermore, it scales a bit better because an application might use many many textures but only have 1 visible window.
There are of course some downsides.
For comparison, here is the same cube scaled down with an 8:1 ratio. As you can see DXT1 does a really good job.
We can't ignore the degradation though as certain rendering may get very distorted as a result.
*TOTAL SAVINGS (DXT1) = 1.64MB⁄s (30% savings)
*total savings here is kind of a theoretical max
So what if I told you there was a way to reduce your memory bandwidth consumption without having to modify your application, without being subject to hardware limits on planes, and without having to wait for new memory technologies to arrive?
End to end loss compression attempts to provide both "end to end" and "lossless" compression transparently to software. Explanation coming up.
As mentioned in the previous section on texture compression, one of the pitfalls is that you'd have to decompress the texture in order for it to be used outside of your 3d engine. Typically this would mean for the display engine to scanout out from, but you could also envision a case where perhaps you'd like to share these surfaces with the hardware video encoder. The nice thing about this "end to end" attribute is every stage we mentioned in previous sections that required bandwidth can get the savings just by running on hardware and drivers that enable this.
Now because this is all transparent to the application running, a lossless compression scheme has to be used so that there aren't any unexpected results. While lossless might sound great on the surface (why would you want to lose quality?) it reduces the potential savings because lossless compression algorithms are always more inefficient, but it's still a pretty big win.
I want to provide an example of how this can be possible. Going back to our original image of the full picture, everything looks sort of the same. The only difference is there is a little display engine decompression step, and all of the sampler and framebuffer write steps now have a little purple box accompanying them
One sort of surprising aspect of this compression is it reduces bandwidth, not overall memory usage (that's also true of the Intel implementation). In order to store the compression information, hardware carves off a little bit of extra memory which is referenced for each operation on a texture (yes, that might use bandwidth too if it's not cached).
Here's a made-up implementation which tracks state in a similar way to Skylake era hardware, but the rest is entirely made up by me. It shows that even a naive implementation can get up to a lossless 2:1 compression ratio. Remember though, this comes at the cost of adding gates to the design and so you'd probably want something better performing than this.
2:1 compressionEverything is tracked as cacheline pairs. In this example we have state called "CCS". For every pair of cachelines in the image, 2b are in this state to track the current compression. When the pair of cachelines uses 12 or fewer colors (which is surprisingly often in real life), we're able to compress the data into a single cacheline (state becomes '01'). When the data is compressed, we can reassemble the image losslessly from a single cacheline, this is 2:1 compression because 1 cacheline gets us back 2 cachelines worth of pixel data.
Walking through the example we've been using of the Rubik's cube.
The memory consumed is minimal which also means that any bandwidth usage overhead is minimal. In the example we have a 64x128 image. In total that's 512 cachelines. At 2 bits per 2 cachelines the CCS size for the example would be not even be a full cacheline: 512 / 2 / 2 = 128b = 16B
* Unless you really want to understand how hardware might actually work, ignore the 00 encoding for clear color.
* There's a caveat here that we assume texture upload and fetch use the sampler. At the time of the original presentation, this was not usually the case and so until the FB write occurred, you didn't actually get compression.
Theoretical best savings would compress everything:
| Operation | Color Depth | Description | Bandwidth | R/W |
|---|---|---|---|---|
| Texture Upload | 1Bpc compressed | File to DRAM | 8KB (64 × 64 × 4) / 2 | W |
| Texel Fetch (nearest) | 1Bpc compressed | DRAM to Sampler | 8KB (64 × 64 × 4) / 2 | R |
| FB Write | 1Bpc compressed | GPU to DRAM | 8KB (64 × 64 × 4) / 2 | W |
| Compositing | 1Bpc compressed | DRAM to DRAM | 16KB (64 × 64 × 4 × 2) / 2 | R+W |
| Scanout | 1Bpc compressed | DRAM to PHY | 8KB (64 × 64 × 4) / 2 | R |
TOTAL SAVINGS = 2.8125MB⁄s (50% savings)
And if you use HW compositing in addition to this...
TOTAL SAVINGS = 3.75MB⁄s (66% savings)
Hopefully it's somewhat clear how 3d applications are consuming memory bandwidth, and how quickly the consumption grows when adding more applications, textures, screen size, and refresh rate.
End to end lossless compression isn't always going to be a huge win, but in many cases it can really chip away at the problem enough to be measurable. The challenge as it turns out is actually getting it hooked up in the driver and rest of the graphics software stack. As I said earlier, just because a feature seems good doesn't necessarily mean it would be worth the software effort to implement it. End to end loss compression is one feature that you cannot just turn on by setting a bit, and the fact that it's still not enabled anywhere, to me, is an indication that effort and gates may have been better spent elsewhere.
However, next section will be all about how we got it hooked up through the graphics stack.
If you've made it this far, you probably could use a drink. I know I can.
Linaro has been working together with Qualcomm to enable camera support on their platformssince 2017. The Open Source CAMSS driver was written to support the ISP IP-block with the same name that is present on Qualcomm SoCs coming from the smartphone space.
The first development board targeted by this work was the DragonBoard 410C, which was followed in 2018 by DragonBoard 820C support. Recently support for the Snapdragon 660 SoC was added to the driver, which will be part of the v5.11 Linux Kernel release. These SoCs all contain the CAMSS (Camera SubSystem) version of the ISP architecture.
Currently, support for the ISP found in the Snapdragon 845 SoC and the DragonBoard 845C is in the process of being upstreamed to the mailinglists. Having …
After a lot of effort over short stints in the last several months, I have completed my blog migration to Lektor in the hopes that when I migrate again in the future, it won't be as painful.
Despite my efforts, many old posts might not be perfect. This is a job for the wayback machine
In case you're curious I did this primarily for one reason (and lots of smaller ones). I wanted my data back. Wordpress is an open source blogging platform with huge adoption. It has a very large plugin ecosystem and is very actively updated and maintained. While security issues have come up here and there, at some point automatic updates became an option and that helped a bit. In 2010 it was the obvious choice.
If you've gained anything from my blog posts, you should thank Wordpress. Wordpress' ease of setup and relative ease of use is a big reason I was able to author things as well as I did.
I wanted my data back. It was a self hosted instance and I had all my information stored in a SQL database. Obviously I never lost my data, but...
Plugins.
I used plugins for my tables (multiple plugins). I used plugins for code highlighting. Plugins for LaTeX. Plugins for table of contents, social media integration, post tagging, image captioning and formatting, spelling. You get the idea. The result of all this was I ended up with a blog post that was entirely useless in its text only form. Plugins storing the data in non-standard places so it can be processed and look fancy.
The WYSIWYG editor interface was a huge plus for me. I spent all day in front of a terminal breaking graphics and display (meaning I really was in front of an 80x24 terminal at times). I didn't want to have to deal with fanciful layout engines or styles. Those plugins ended up destroying the WYSIWYG editor experience and I ended up doing everything in quasi markdown anyway.
Plugins themselves introduced security issues when they weren't intentionally malicious anyway.
These static site generators seemed really appealing as a solution to this problem. Everything in markdown. Assets stored together in the filesystem. Jekyll is obviously hugely popular. Hugo, Pelican, Gatsby, and Sphinx are all generators I considered. The number of static site generators is staggering. I wish I could remember what made me choose Lektor, but I can't - python based was my only requirement.
Python because I wanted a platform that did most of what I wanted but was extendible by me if absolutely necessary.
Migrating was definitely a lot of work. I was tempted several times to abort the effort and just rely on wayback machine. Ultimately I decided that migrating the post would be a good way to learn how well the platform would meet my needs (that being an annual blog post or so)
There are definitely some features I miss that I may or may not get to.
I followed this. I did have to make some minor changes specific to my needs and posts did still require some touchups, in large part due to plugins and my obsessive use of SVG.
Now that I'm back, I hope to post more often. Next up will be a recap of some of the pathfinding projects I worked on after FreeBSD enabling
Last year I wrote about how to create a user-specific XKB layout, followed by a post explaining that this won't work in X. But there's a pandemic going on, which is presumably the only reason people haven't all switched to Wayland yet. So it was time to figure out a workaround for those still running X.
This Merge Request (scheduled for xkeyboard-config 2.33) adds a "custom" layout to the evdev.xml and base.xml files. These XML files are parsed by the various GUI tools to display the selection of available layouts. An entry in there will thus show up in the GUI tool.
Our rulesets, i.e. the files that convert a layout/variant configuration into the components to actually load already have wildcard matching [1]. So the custom layout will resolve to the symbols/custom file in your XKB data dir - usually /usr/share/X11/xkb/symbols/custom.
This file is not provided by xkeyboard-config. It can be created by the user though and whatever configuration is in there will be the "custom" keyboard layout. Because xkeyboard-config does not supply this file, it will not get overwritten on update.
From XKB's POV it is just another layout and it thus uses the same syntax. For example, to override the +/* key on the German keyboard layout with a key that produces a/b/c/d on the various Shift/Alt combinations, use this:
This example includes the "basic" section from the symbols/de file (i.e. the default German layout), then overrides the 12th alphanumeric key from left in the 4th row from bottom (D) with the given symbols. I'll leave it up to the reader to come up with a less useful example.
default
xkb_symbols "basic" {
include "de(basic)"
key <AD12> { [ a, b, c, d ] };
};
There are a few drawbacks:
So overall, it's a hack[2]. But it's a hack that fixes real user issues and given we're talking about X, I doubt anyone notices another hack anyway.
[1] If you don't care about GUIs, setxkbmap -layout custom -variant foobar has been possible for years.
[2] Sticking with the UNIX principle, it's a hack that fixes the issue at hand, is badly integrated, and weird to configure.
I recently joined Igalia and as a way to familiarize myself with Adreno GPUs it was decided to get Freedreno up to OpenGL 3.3.
Just recently, Freedreno exposed only OpenGL 3.0. The big jump in version required only two small extensions and a few fixes to get rid of most crashes in Piglit since almost all features were already supported.
I decided to start with dual-source-blending. Fittingly, it was the cause of the first issue I investigated in Mesa two and a half years ago =)
Turnip already had it implemented so it was a good first task. Most of the time was spent getting myself familiarized with Freedreno and squashing the hangs that happened due to the lack of experience with this driver. And shortly I have a working MR
freedreno/a6xx: add support for dual-source blending (!7708)
However, Freedreno didn’t have Piglit tests running on CI and I missed the failure of arb_blend_func_extended-fbo-extended-blend-pattern_gles2 test. I did test the _gles3 version though. Thus the issue with gles2 was not found immediately.
What’s different in the gles2 test? It uses gl_SecondaryFragColorEXT for the second color of dual-source blending. gl_FragColor and gl_SecondaryFragColorEXT are different from the other ways to specify color in that they broadcast the color to all enabled draw buffers. In Mesa they both translated to slot FRAG_RESULT_COLOR, which in Freedreno didn’t expect the second source for blending. The solution was simple, if a shader has a dual-source blending - remap FRAG_RESULT_COLOR to FRAG_RESULT_DATA0 + dual_src_index.
freedreno/ir3: remap FRAG_RESULT_COLOR to _DATA* for dual-src blending (!8245)
While looking at how other drivers handle FRAG_RESULT_COLOR I saw that Zink also has a similar issue but in a NIR lowering path, so I fixed it too since it was simple enough.
nir/lower_fragcolor: handle dual source blending (!8247)
While implementing ARB_blend_func_extended I saw in Turnip that RB_FS_OUTPUT_CNTL0 also could enable stencil export:
tu_cs_emit_pkt4(cs, REG_A6XX_RB_FS_OUTPUT_CNTL0, 2);
tu_cs_emit(cs, COND(fs->writes_pos, A6XX_RB_FS_OUTPUT_CNTL0_FRAG_WRITES_Z) |
COND(fs->writes_smask, A6XX_RB_FS_OUTPUT_CNTL0_FRAG_WRITES_SAMPMASK) |
COND(fs->writes_stencilref, A6XX_RB_FS_OUTPUT_CNTL0_FRAG_WRITES_STENCILREF) |
COND(dual_src_blend, A6XX_RB_FS_OUTPUT_CNTL0_DUAL_COLOR_IN_ENABLE));
Meanwhile, in Freedreno there was just a cryptic 0xfc000000:
OUT_PKT4(ring, REG_A6XX_SP_FS_OUTPUT_CNTL0, 1);
OUT_RING(ring, A6XX_SP_FS_OUTPUT_CNTL0_DEPTH_REGID(posz_regid) |
A6XX_SP_FS_OUTPUT_CNTL0_SAMPMASK_REGID(smask_regid) |
COND(fs_has_dual_src_color,
A6XX_SP_FS_OUTPUT_CNTL0_DUAL_COLOR_IN_ENABLE) |
0xfc000000);
Which I was quickly told to be a shifted register r63.x, which has a value of 0xfc and is used to signify an unused value.
Again, Turnip already supported stencil export and compiler had it wired up; it’s hard to have a simpler extension to implement.
freedreno/a6xx: add support for ARB_shader_stencil_export (!7810)
After enabling ARB_blend_func_extended and ARB_shader_stencil_export Freedreno had everything for a jump to GL 3.3. It was a time to run tests.
First observation was that the test passes with FD_MESA_DEBUG=nogmem, next I compared traces with and without nogmem and saw the difference in a texture layout (I should have just printed the layouts with FD_MESA_DEBUG=layout). It didn’t give me an answer, so I checked whether I could bisect the failure. To my delight it was bisectable
freedreno: reduce extra height alignment in a6xx layout (e4974852)
The change is only one line of code and without the context first thing which comes to mind is that maybe the alignment is wrong:
if (level == mip_levels - 1)
- nblocksy = align(nblocksy, 32);
+ height = align(nblocksy, 4);
uint32_t nblocksx =
But it’s even more trivial, nblocksy was erroneously changed to height, and height just wasn’t used afterwards which hid the issue. Thus it was fixed in
freedreno/a6xx: Fix typo in height alignment calculation in a6xx layout (!7792)
It was quickly found that clearing a framebuffer in Freedreno didn’t take into account that framebuffer could have several layers, so only the first one was cleared.
Initially, I thought that we would need a number_of_layers draw calls to clear all layers, but looking at a generic blitter in gallium suggested a better answer - instanced draw where each instance draw a fullscreen quad into a distinct layer. Which could be accomplished just by:
gl_Layer = gl_InstanceID;
in the vertex shader. However, this required the support of GL_AMD_vertex_shader_layer which Freedreno didn’t have…
Fortunately, Turnip again had it implemented. As with stencil export it was just a matter of finding a register of VARYING_SLOT_LAYER and plugging it into respective control structure.
freedreno/a6xx: add support for gl_Layer in vertex shader
Simple enough? Yes! However, it failed the only tests available for the extension:
amd_vertex_shader_layer-layered-2d-texture-render // Fails
amd_vertex_shader_layer-layered-depth-texture-render // Crashes
The crash when clearing a depth texture is a known one, but why 2d-texture-render fails? Let’s look at the output:
amd_vertex_shader_layer-layered-2d-texture-render
First layer and its mipmaps are cleared, but on other layers most mipmaps are not! Mipmaps are nowhere near gl_Layer, so it seams that the implementation is indeed correct, however the single test we expected to pass - fails. Which is bad because we don’t have other tests to test gl_Layer.
A good starting point is always to check whether one of FD_MESA_DEBUG options helps. In this case noubwc changed the result of the test to:
amd_vertex_shader_layer-layered-2d-texture-render with noubwc
Not by a lot but still a lead. Something wrong with image layouts…
I searched for similar tests for Vulkan and found them in vktDrawShaderLayerTests.cpp, the tests passed on Turnip which told me that most likely the issue is not in the common code of layout calculations. After some hacking of the tests I made one close enough to amd_vertex_shader_layer-layered-2d-texture-render. However, directly comparing traces between GL and Vulkan isn’t productive. So I decided to see what changes with different mip levels in Freedreno and Turnip separately.
So I did make 4 tests:
With that comparing “GL level 1”” with “GL level 2” and “VK level 1”” with “VK level 2” yielded just a few differences. For GL the only difference which could had been relevant was:
Level 1:
RB_MRT[0].ARRAY_PITCH: 8192
Level 2:
RB_MRT[0].ARRAY_PITCH: 4096
However in VK this value didn’t change, there was no difference in traces barring window/scissor/blit sizes!
RB_MRT[0].ARRAY_PITCH: 45056
In VK it was just a constant 45056 regardless of mip level. Hardcoding the value in Freedreno fixed the test. After that it was a matter of comparing how the field is calculated for Turnip and Freedreno resulting in:
freedreno/a6xx: fix array pitch for layer-first layouts
With the above changes the layered clear was simple enough:
freedreno/a6xx: support layered framebuffers in blitter_clear
Before, Freedreno supported only 16 vec4 varyings or 64 components between shader stages. GL3.2 on the other hand mandates the minimum of 128 components. After a couple of trivial fixes - I thought it would be easy, but Marek Olšák pointed out that I didn’t cover all cases with my tests. And of course one of them, the passing of varyings between VS and TCS, hanged the GPU.
I ran a few tests only changing the varyings count and observed that GPU hanged starting from 17 vec4. By comparing the traces I didn’t find anything suspicious in shaders, so I decided to check a few states that depended on varyings count. After poking a few of them I found that setting SP_HS_UNKNOWN_A831 above 64 resulted in a guaranteed hang.
In Turnip SP_HS_UNKNOWN_A831 had a special case for A650 which made me a bit suspicious. However, using A650’s formula for A630 didn’t change anything. It was time to see what blob driver does, so I wrote a script to iterate from 1 to 32 vec4, push test on device, run it, copy trace back, extract A831 value and append to a csv. Here is the result:
| vec4 count | A831 (Hex) | A831 (Dec) | PC_HS_INPUT_SIZE |
|---|---|---|---|
| 1 | 0x10 | 16 | 0xc |
| 2 | 0x14 | 20 | 0xf |
| 3 | 0x18 | 24 | 0x12 |
| 4 | 0x1c | 28 | 0x15 |
| 5 | 0x20 | 32 | 0x18 |
| 6 | 0x24 | 36 | 0x1b |
| 7 | 0x28 | 40 | 0x1e |
| 8 | 0x2c | 44 | 0x21 |
| 9 | 0x30 | 48 | 0x24 |
| 10 | 0x34 | 52 | 0x27 |
| 11 | 0x38 | 56 | 0x2a |
| 12 | 0x3c | 60 | 0x2d |
| 13 | 0x3f | 63 | 0x30 |
| 14 | 0x40 | 64 | 0x33 |
| 15 | 0x3d | 61 | 0x36 |
| 16 | 0x3d | 61 | 0x39 |
| 17 | 0x40 | 64 | 0x3c |
| 18 | 0x3f | 63 | 0x3f |
| 19 | 0x3e | 62 | 0x42 |
| 20 | 0x3d | 61 | 0x45 |
| 21 | 0x3f | 63 | 0x48 |
| 22 | 0x3d | 61 | 0x4b |
| 23 | 0x40 | 64 | 0x4e |
| 24 | 0x3d | 61 | 0x51 |
| 25 | 0x3f | 63 | 0x54 |
| 26 | 0x3c | 60 | 0x57 |
| 27 | 0x3e | 62 | 0x5a |
| 28 | 0x40 | 64 | 0x5d |
| 29 | 0x3c | 60 | 0x60 |
| 30 | 0x3e | 62 | 0x63 |
| 31 | 0x40 | 64 | 0x66 |
So A831 is indeed capped at 64 and after the first time A831 reaches 64, the relation ceases to be linear. Ugh…
Without having any good ideas I posted the results on Gitlab asking Jonathan Marek, who added a special case for A650 some time ago, for help. The previous A650 formula was:
prims_per_wave = wavesize // tcs_vertices_out
total_size = output_size * patch_control_points * prims_per_wave
unknown_a831 = DIV_ROUND_UP(total_size, wavesize)
After looking at the table above Jonathan Marek suggested the following formula:
prims_per_wave = wavesize // tcs_vertices_out
while True:
total_size = output_size * patch_control_points * prims_per_wave
unknown_a831 = DIV_ROUND_UP(total_size, wavesize)
if unknown_a831 <= 0x40:
break
prims_per_wave -= 1
And it worked! What does the new formula mean is that there is A831 * wavesize available space per wave for varyings; the more varyings we use in a shader the less threads the wave will have. For TCS we use wave size of 64 so the total size available would be
64 (wave size) * 64 (max A831) * 4 = 16k
freedreno/a6xx: bump varyings limit (!7917)
There still was a considerable amount of Piglit failures but they were either already known or not so important to prevent the the version increase. Which was done in
freedreno: Enable GLSL 3.30, updating us to GL 3.3 contexts (!8270)
This article is part of a series on how to setup a bare-metal CI system for Linux driver development. Check out part 1 where we expose the context/high-level principles of the whole CI system, and make the machine fully controllable remotely (power on, OS to boot, keyboard/screen emulation using a serial console).
In this article, we will start demystifying the boot process, and discuss about different ways to generate and boot an OS image along with a kernel for your machine. Finally, we will introduce boot2container, a project that makes running containers on bare metal a breeze!
This work is sponsored by the Valve Corporation.
To boot your test environment, you will need to generate the following items:
The initramfs is optional because the drivers and their firmwares can be built in the kernel directly.
Let's not generate these items just yet, but instead let's look at the different ways one could generate them, depending on their experience.
If you are used to dealing with embedded devices, you are already familiar with projects such as Yocto or Buildroot. They are well-suited to generate a tiny rootfs which can be be useful for netbooted systems such as the one we set up in part 1 of this series. They usually allow you to describe everything you want on your rootfs, then will configure, compile, and install all the wanted programs in the rootfs.
If you are wondering which one to use, I suggest you check out the presentation from Alexandre Belloni / Thomas Pettazoni which will give you an overview of both projects, and help you decide on what you need.
Pros:
Cons:
If you are used to installing Linux distributions, your first instinct might be to install your distribution of choice in a chroot or a Virtual Machine, install the packages you want, and package the folder/virtual disk into a tarball.
Some tools such as debos, or virt-builder make this process relatively painless, although they will not be compiling an initramfs, nor a kernel for you.
Fortunately, building the kernel is relatively simple, and there are plenty of tutorials on the topic (see ArchLinux's wiki). Just make sure to compile modules and firmware in the kernel, to avoid the complication of using an initramfs. Don't forget to also compress your kernel if you decide to netboot it!
Pros:
Cons:
Containers are an evolution of the old chroot trick, but instead made secure thanks the addition of multiple namespaces to Linux. Containers and their runtimes have been addressing pretty much all the cons of the "Linux distribution way", and became a standard way to share applications.
On top of generating a rootfs, containers also allow setting environment variables, control the command line of the program, and have a standardized transport mechanism which simplifies sharing images.
Finally, container images are constituted of cacheable layers, which can be used to share base images between containers, and also speed up the generation of the container image by only re-computing the layer that changed and all the layers applied on top of it.
The biggest draw-back of containers is that they usually are meant to be run on pre-configured hosts. This means that if you want to run the container directly, you will need to make sure to include an initscript or install systemd in your container, and set it as the entrypoint of the container. It is however possible to perform these tasks before running the container, as we'll explain in the following sections.
Pros:
Cons:
Now we know how we could generate a rootfs, so the next step is to be able to deploy and boot it!
There are multiple ways to deploy an operating system:
The former solution is great at preventing the bricking of a device that depends on an Operating System to be flashed again, as it enables checking the deployment on the device itself before rebooting.
The latter solution enables diskless test machines, which is an effective way to reduce state (the enemy #1 of reproducible results). It also enables a faster deployment/boot time as the CI system would not have to boot the machine, flash it, then reboot. Instead, the machine simply starts up, requests an IP address through BOOTP/DHCP, downloads the kernel/initramfs, and executes the kernel. This was the solution we opted for in part 1 of this blog series.
Whatever solution you end up picking, you will now be presented with your next challenge: making sure the rootfs remains the same across reboots.
If you have chosen the Flash and reboot deployment method, you may be
prepared to re-flash the entire Operating System image every time you boot.
This would make sure that the state of a previous boot won't leak into
following boots.
This method can however become a big burden on your network when scaled to tens of machines, so you may be tempted to use a Network File System such as NFS to spread the load over a longer period of time. Unfortunately, using NFS brings its own set of challenges (how deep is this rabbit hole?):
So, instead of trying to spread the load, we could try to reduce the size of the rootfs by only sending the content that changed. For example, the rootfs could be split into the following layers:
Layers can be downloaded by the test machine, through a short-lived-state network protocol such as HTTP, as individual SquashFS images. Additionally, SquashFS provides compression which further reduces the storage/network bandwidth needs.
The layers can then be directly combined by first mounting the layers to
separate folders in read-only mode (only mode supported by SquashFS), then
merging them using
OverlayFS.
OverlayFS will store all the writes done to this file system into the workdir
directory. If this work directory is backed up by a ramdisk
(tmpfs) or a never-reused temporary
directory, then this would guarantee that no information from previous boots
would impact the new boots!
If you are familiar with containers, you may have recognized this approach as what is used by containers: layers + overlay2 storage driver. The only difference is that container runtimes depend on tarballs rather than SquashFS images, probably because this is a Linux-only filesystem.
If you are anything like me, you should now be pretty tempted to simply use containers for the rootfs generation, transport, and boot! That would be a wise move, given that thousands of engineers have been working on them over the last decade or so, and whatever solution you may come up with will inevitably have even more quirks than these industry standards.
I would thus recommend using containers to generate your rootfs, as there are plenty of tools that will generate them for you, with varying degree of complexity. Check out buildah, if Docker, or Podman are not too high/level for your needs!
Let's now brace for the next challenge, deploying a container runtime!
In the previous challenge, we realized that a great way to deploy a rootfs efficiently was to simply use a container runtime to do everything for us, rather than re-inventing the wheel.
This would enable us to create an initramfs which would be downloaded along with the kernel through the usual netboot process, and would be responsible for initializing the machine, connecting to the network, mounting the layer cache partition, setting the time, downloading a container, then executing it. The last two steps would be performed by the container runtime of our choice.
Generating an initramfs is way easier than one can expect. Projects like dracut are meant to simplify their creation, but my favourite has been u-root, coming from the LinuxBoot project. I generated my first initramfs in less than 5 minutes, so I was incredibly hopeful to achieve the outlined goals in no time!
Unfortunately, the first setback came quickly:
container runtimes (Docker, or
Podman) are huge (~150 to 300 MB), if we are to believe
Alpine Linux's size of their respective packages and dependencies! While this
may not be a problem for the Flash and reboot method, it is definitely a
significant issue for the Netboot method which would need to download it for
every boot.
After spending a significant amount of time studying container runtimes, I identified the following functions:
Thus started my quest to find lightweight solutions that could do all of these steps... and wonder just how deep is this rabbit hole??
The usual executor found in the likes of Podman and Docker is runc. It is written in Golang, which compiles everything statically and leads to giant binaries. In this case, runc clocks at ~12MB. Fortunately, a knight in shining armour came to the rescue, re-implemented runc in C, and named it crun. The final binary size is ~400 KB, and it is fully compatible with runc. That's good-enough for me!
To download and unpack the rootfs from the container image, I found genuinetools/img which supports that out of the box! Its size was however much bigger than expected, at ~28.5MB. Fortunately, compiling it ourselves, stripping the symbols, then compressing it using UPX led to a much more manageable ~9MB!
What was left was to generate the container manifest according to the runtime
spec. I
started by hardcoding it to verify that I could indeed run the container. I was
relieved to see it would work on my development machine, even thought it
fails on my initramfs. After spending a couple of hours diffing
straces, poking a couple
of files sysfs/config files, and realizing that pivot_root does not work in an
initramfs
, I finally managed to run the container with crun run --no-pivot!
I was over the moon, as the only thing left was to generate the container manifest by patching genuinetools/img to generate it according to the container image manifest (like docker or podman does). This is where I started losing grip: lured by the prospect of a simple initramfs solving all my problems, being so close to the goal, I started free-falling down what felt like the deepest rabbit hole of my engineering career... Fortunately, after a couple of weeks, I emerged, covered in mud but victorious! Queue the gory battle log :)
When trying to access the container image's manifest in img, I realized that it was re-creating the layers and manifest, and thus was losing the information such as entrypoint, environment variables, and other important parameters. After scouring through its source code and its 500 kLOC of dependencies, I came to the conclusion that it would be easier to start a project from scratch that would use Red Hat's image and storage libraries to download and store the container on the cache partition. I then needed to unpack the layers, generate the container manifest, and start runc. After a couple of days, ~250 lines of code, and tons of staring at straces to get it working, it finally did! Out was img, and the new runtime's size was under 10 MB \o/!
The last missing piece in the puzzle was performance-related: use OverlayFS to merge the layers, rather than unpacking them ourselves.
This is when I decided to have another look at Podman, saw that they have
their own internal library for all the major functions, and decided to compile
podman to try it out. The binary size was ~50 MB, but after removing some
features, setting the -w -s LDFLAGS, and compressing it using upx --best, I
got the final size to be ~14 MB! Of course, Podman is more than just one binary,
so trying to run a container with it failed. However, after a bit of
experimentation and stracing, I realized that running the container with
--privileged --network=host would work using crun... provided we force-added
the --no-pivot parameter to crun. My happiness was however short-lived,
replaced by a MAJOR FACEPALM MOMENT:
After a couple of minutes of constant facepalming, I realized I was also relieved, as Podman is a battle-tested container runtime, and I would not need to maintain a single line of Go! Also, I now knew how deep the rabbit was, and we just needed to package everything nicely in an initramfs and we would be good. Success, at last!
If you have managed to read through the article up to this point, congratulations! For the others who just gave up and jumped straight to this section, I forgive you for teleporting yourself to the bottom of the rabbit hole directly! In both cases, you are likely wondering where is this breeze you were promised in the introduction?
Boot2container enters the chat.
Boot2container is a lightweight (sub-20 MB) and fast initramfs I developed that will allow you to ignore the subtleties of operating a container runtime and focus on what matters, your test environment!
Here is an example of how to run boot2container, using SYSLINUX:
LABEL root
MENU LABEL Run docker's hello world container, with caching disabled
LINUX /vmlinuz-linux
APPEND b2c.container=docker://hello-world b2c.cache_device=none b2c.ntp_peer=auto
INITRD /initramfs.linux_amd64.cpio.xz
The hello-world container image will be run in privileged mode, without the host network, which is what you want when running the container for bare metal testing!
Make sure to check out the list of features and options before either generating the initramfs yourself or downloading it from the releases page. Try it out with your kernel, or the example one bundled in in the release!
With this project mostly done, we pretty much conclude the work needed to set up the test machines, and the next articles in this series will be focusing on the infrastructure needed to support a fleet of test machines, and expose it to Gitlab/Github/...
That's all for now, thanks for reading that far!
If you don’t know what is traces based rendering regression testing, read the appendix before continuing.
The Mesa community has witnessed an explosion of the Continuous Integration interest in the last two years.
In addition to checking the proper building of the project, integrating the testing of its functional correctness has become a priority. The user space graphics drivers exhibit a wide variety of types of tests and test suites. One kind of those tests are the traces based rendering regression testing.
The public effort to add this kind of tests into Mesa’s CI started with this mail from Alexandros Frantzis.
At some point, we had support for replaying OpenGL, Vulkan and D3D11 traces using apitrace, RenderDoc and GFXReconstruct with the in-tree tool tracie. However, it was a very custom solution made to the needs of Mesa so I proposed to move this codebase and integrate it into the piglit test suite. It was a natural step forward.
This is how replayer was born into piglit.
The first step to test a trace is, actually, obtaining a trace. I won’t go into the details about how to create one from scratch. The process is well documented on each of the tools listed above. However, the Mesa community has been collecting publicly distributable traces for a while and placing them in traces-db whose CI is copying them to Freedesktop.org’s MinIO instance.
To make things simple, once we have built and installed piglit, if we would like to test an apitrace created OpenGL trace, we can download from there with:
$ replayer.py download \
--download-url https://minio-packet.freedesktop.org/mesa-tracie-public/ \
--db-path ./traces-db \
--force-download \
glxgears/glxgears-2.traceThe parameters are self explanatory. The downloaded trace will now exist at ./traces-db/glxgears/glxgears-2.trace.
The next step will be to dump an image from the trace. Since it is a .trace file we will need to have apitrace installed in the system. If we do not specify the call(s) from which to dump the image(s), we will just get the last frame of the trace:
$ replayer.py dump ./traces-db/glxgears/glxgears-2.traceThe dumped PNG image will be at ./results/glxgears-2.trace-0000001413.png. Notice, the number suffix is the snapshot id from the trace.
Dumping from a trace may result in a range of different possible images. One example is when the trace makes use of uninitialized values, leading to undefined behaviors.
However, since the original aim was performing pre-merge rendering regression testing in Mesa’s CI, the idea is that replaying any of the provided traces would be quick and the dumped image will be consistent. In other words, if we would dump several times the same frame of a trace with the same GFX stack, the image will always be the same.
With this precondition, we can test whether 2 different images are the same just by doing a hash of its content. replayer can obtain the hash for the generated dumped image:
$ replayer.py checksum ./results/glxgears-2.trace-0000001413.png
f8eba0fec6e3e0af9cb09844bc73bdc8Now, if we would build a different commit of Mesa, we could check the generated image at this new point against the previously generated reference image. If everything goes well, we will see something like:
$ replayer.py compare trace \
--download-url https://minio-packet.freedesktop.org/mesa-tracie-public/ \
--device-name gl-vmware-llvmpipe \
--db-path ./traces-db \
--keep-image \
glxgears/glxgears-2.trace f8eba0fec6e3e0af9cb09844bc73bdc8
[dump_trace_images] Info: Dumping trace ./traces-db/glxgears/glxgears-2.trace...
[dump_trace_images] Running: apitrace dump --calls=frame ./traces-db/glxgears/glxgears-2.trace
// process.name = "/usr/bin/glxgears"
1384 glXSwapBuffers(dpy = 0x56060e921f80, drawable = 31457282)
1413 glXSwapBuffers(dpy = 0x56060e921f80, drawable = 31457282)
error: drawable failed to resize: expected 1515x843, got 300x300
[dump_trace_images] Running: eglretrace --headless --snapshot=1413 --snapshot-prefix=./results/trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace- ./blog-traces-db/glxgears/glxgears-2.trace
Wrote ./results/trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace-0000001413.png
OK
[check_image]
actual: f8eba0fec6e3e0af9cb09844bc73bdc8
expected: f8eba0fec6e3e0af9cb09844bc73bdc8
[check_image] Images match for:
glxgears/glxgears-2.trace
PIGLIT: {"images": [{"image_desc": "glxgears/glxgears-2.trace", "image_ref": "f8eba0fec6e3e0af9cb09844bc73bdc8.png", "image_render": "./results/trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace-0000001413-f8eba0fec6e3e0af9cb09844bc73bdc8.png"}], "result": "pass"}replayer‘s compare subcommand is the one spitting a piglit formatted test expectations output.
We can make the whole process way simpler by passing the replayer a YAML tests list file. For example:
$ cat testing-traces.yml
traces-db:
download-url: https://minio-packet.freedesktop.org/mesa-tracie-public/
traces:
- path: gputest/triangle.trace
expectations:
- device: gl-vmware-llvmpipe
checksum: c8848dec77ee0c55292417f54c0a1a49
- path: glxgears/glxgears-2.trace
expectations:
- device: gl-vmware-llvmpipe
checksum: f53ac20e17da91c0359c31f2fa3f401e
$ replayer.py compare yaml \
--device-name gl-vmware-llvmpipe \
--yaml-file testing-traces.yml
[check_image] Downloading file gputest/triangle.trace took 5s.
[dump_trace_images] Info: Dumping trace ./replayer-db/gputest/triangle.trace...
[dump_trace_images] Running: apitrace dump --calls=frame ./replayer-db/gputest/triangle.trace
// process.name = "/home/anholt/GpuTest_Linux_x64_0.7.0/GpuTest"
397 glXSwapBuffers(dpy = 0x7f0ad0005a90, drawable = 56623106)
510 glXSwapBuffers(dpy = 0x7f0ad0005a90, drawable = 56623106)
/home/anholt/GpuTest_Linux_x64_0.7.0/GpuTest
[dump_trace_images] Running: eglretrace --headless --snapshot=510 --snapshot-prefix=./results/trace/gl-vmware-llvmpipe/gputest/triangle.trace- ./replayer-db/gputest/triangle.trace
Wrote ./results/trace/gl-vmware-llvmpipe/gputest/triangle.trace-0000000510.png
OK
[check_image]
actual: c8848dec77ee0c55292417f54c0a1a49
expected: c8848dec77ee0c55292417f54c0a1a49
[check_image] Images match for:
gputest/triangle.trace
[check_image] Downloading file glxgears/glxgears-2.trace took 5s.
[dump_trace_images] Info: Dumping trace ./replayer-db/glxgears/glxgears-2.trace...
[dump_trace_images] Running: apitrace dump --calls=frame ./replayer-db/glxgears/glxgears-2.trace
// process.name = "/usr/bin/glxgears"
1384 glXSwapBuffers(dpy = 0x56060e921f80, drawable = 31457282)
1413 glXSwapBuffers(dpy = 0x56060e921f80, drawable = 31457282)
/usr/bin/glxgears
error: drawable failed to resize: expected 1515x843, got 300x300
[dump_trace_images] Running: eglretrace --headless --snapshot=1413 --snapshot-prefix=./results/trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace- ./replayer-db/glxgears/glxgears-2.trace
Wrote ./results/trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace-0000001413.png
OK
[check_image]
actual: f8eba0fec6e3e0af9cb09844bc73bdc8
expected: f8eba0fec6e3e0af9cb09844bc73bdc8
[check_image] Images match for:
glxgears/glxgears-2.tracereplayer features also the query subcommand, which is just a helper to read the YAML files with the tests configuration.
Testing the other kind of supported 3D traces doesn’t change much from what’s shown here. Just make sure to have the needed tools installed: RenderDoc, GFXReconstruct, the VK_LAYER_LUNARG_screenshot layer, Wine and DXVK. A good reference for building, installing and configuring these tools are Mesa’s GL and VK test containers building scripts.
replayer also accepts several configurations to tweak how to behave and where to find the actual tracing tools needed for replaying the different types of traces. Make sure to check the replay section in piglit’s configuration example file.
replayer‘s README.md file is also a good read for further information.
replayer is a test runner in a similar fashion to shader_runner or glslparsertest. We are now missing how does it integrate so we can do piglit runs which will produce piglit formatted results.
This is done through the replay test profile.
This profile needs a couple configuration values. Easiest is just to set the PIGLIT_REPLAY_DESCRIPTION_FILE and PIGLIT_REPLAY_DEVICE_NAME env variables. They are self explanatory, but make sure to check the documentation for this and other configuration options for this profile.
The following example features a similar run to the one done above invoking directly replayer but with piglit integration, providing formatted results:
$ PIGLIT_REPLAY_DESCRIPTION_FILE=testing-traces.yml PIGLIT_REPLAY_DEVICE_NAME=gl-vmware-llvmpipe piglit run replay -n replay-example replay-results
[2/2] pass: 2
Thank you for running Piglit!
Results have been written to replay-resultsWe can create some summary based on the results:
# piglit summary console replay-results/
trace/gl-vmware-llvmpipe/glxgears/glxgears-2.trace: pass
trace/gl-vmware-llvmpipe/gputest/triangle.trace: pass
summary:
name: replay-example
---- --------------
pass: 2
fail: 0
crash: 0
skip: 0
timeout: 0
warn: 0
incomplete: 0
dmesg-warn: 0
dmesg-fail: 0
changes: 0
fixes: 0
regressions: 0
total: 2
time: 00:00:00Creating an HTML summary may be also interesting, specially when finding failures!
Thanks a lot to the whole Mesa community for helping with the creation of this tool. Alexandros Frantzis, Rohan Garg and Tomeu Vizoso did a lot of the initial development for the in-tree tracie tool while Dylan Baker was very patient while reviewing my patches for the piglit integration.
Finally, thanks to Igalia for allowing me to work in this.
In 3D computer graphics we say “traces”, for short, to name the files generated by 3D APIs capturing tools which store not only the calls to the specific 3D API but also the internal state of the 3D program during the capturing process: shaders, textures, buffers, etc.
Being able to “record” the execution of a 3D program is very useful. Usually, it will allow us to replay the execution without the need of the original program from which we generated the trace, it will also allow in-depth analysis for debugging and performance optimization, it’s a very good solution for sharing with other developers, and, in some cases, will allow us to check how the replay will happen with different GPUs.
In this post, however, I focus in a specific usage: rendering regression testing.
When doing a regression test what we would do is compare a specific metric obtained by replaying the trace with a specific version of the GFX software stack against the same metric obtained from a different version of the GFX stack. If the value of the metric changes we have found a regression (or an improvement!).
To make things simpler, we would like to check changes happening just in one of the many elements of the software stack. The most relevant component is the user space driver. In particular, I care about the Mesa drivers and the GNU/Linux stack.
Mainly, there are two kinds of regression testing we can do with a trace: performance or rendering regression testing. When doing a performance one, the checked metric(s) usually are in terms of speed or memory usage. In the case of the rendering ones what we would do is comparing the rendered output at one (or many) point during the trace replay. This output, a bitmap image, is the metric that we will compare in between two different points of the Mesa driver. If the images differ, we may have found a regression; artifacts, improper colors, etc, or an enhancement, if the reference image is the one featuring any of these problems.
