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use crate::{
binding_model::{
BindError, BindGroup, LateMinBufferBindingSizeMismatch, PushConstantUploadError,
},
command::{
bind::Binder,
compute_command::ArcComputeCommand,
end_pipeline_statistics_query,
memory_init::{fixup_discarded_surfaces, SurfacesInDiscardState},
validate_and_begin_pipeline_statistics_query, ArcPassTimestampWrites, BasePass,
BindGroupStateChange, CommandBuffer, CommandEncoderError, CommandEncoderStatus, MapPassErr,
PassErrorScope, PassTimestampWrites, QueryUseError, StateChange,
},
device::{Device, DeviceError, MissingDownlevelFlags, MissingFeatures},
global::Global,
hal_label, id,
init_tracker::{BufferInitTrackerAction, MemoryInitKind},
pipeline::ComputePipeline,
resource::{
self, Buffer, DestroyedResourceError, InvalidResourceError, Labeled,
MissingBufferUsageError, ParentDevice,
},
snatch::SnatchGuard,
track::{ResourceUsageCompatibilityError, Tracker, TrackerIndex, UsageScope},
Label,
};
use thiserror::Error;
use wgt::{BufferAddress, DynamicOffset};
use super::{bind::BinderError, memory_init::CommandBufferTextureMemoryActions};
use crate::ray_tracing::TlasAction;
use std::sync::Arc;
use std::{fmt, mem::size_of, str};
pub struct ComputePass {
/// All pass data & records is stored here.
///
/// If this is `None`, the pass is in the 'ended' state and can no longer be used.
/// Any attempt to record more commands will result in a validation error.
base: Option<BasePass<ArcComputeCommand>>,
/// Parent command buffer that this pass records commands into.
///
/// If it is none, this pass is invalid and any operation on it will return an error.
parent: Option<Arc<CommandBuffer>>,
timestamp_writes: Option<ArcPassTimestampWrites>,
// Resource binding dedupe state.
current_bind_groups: BindGroupStateChange,
current_pipeline: StateChange<id::ComputePipelineId>,
}
impl ComputePass {
/// If the parent command buffer is invalid, the returned pass will be invalid.
fn new(parent: Option<Arc<CommandBuffer>>, desc: ArcComputePassDescriptor) -> Self {
let ArcComputePassDescriptor {
label,
timestamp_writes,
} = desc;
Self {
base: Some(BasePass::new(label)),
parent,
timestamp_writes,
current_bind_groups: BindGroupStateChange::new(),
current_pipeline: StateChange::new(),
}
}
#[inline]
pub fn label(&self) -> Option<&str> {
self.base.as_ref().and_then(|base| base.label.as_deref())
}
fn base_mut<'a>(
&'a mut self,
scope: PassErrorScope,
) -> Result<&'a mut BasePass<ArcComputeCommand>, ComputePassError> {
self.base
.as_mut()
.ok_or(ComputePassErrorInner::PassEnded)
.map_pass_err(scope)
}
}
impl fmt::Debug for ComputePass {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
match self.parent {
Some(ref cmd_buf) => write!(f, "ComputePass {{ parent: {} }}", cmd_buf.error_ident()),
None => write!(f, "ComputePass {{ parent: None }}"),
}
}
}
#[derive(Clone, Debug, Default)]
pub struct ComputePassDescriptor<'a> {
pub label: Label<'a>,
/// Defines where and when timestamp values will be written for this pass.
pub timestamp_writes: Option<&'a PassTimestampWrites>,
}
struct ArcComputePassDescriptor<'a> {
pub label: &'a Label<'a>,
/// Defines where and when timestamp values will be written for this pass.
pub timestamp_writes: Option<ArcPassTimestampWrites>,
}
#[derive(Clone, Debug, Error)]
#[non_exhaustive]
pub enum DispatchError {
#[error("Compute pipeline must be set")]
MissingPipeline,
#[error(transparent)]
IncompatibleBindGroup(#[from] Box<BinderError>),
#[error(
"Each current dispatch group size dimension ({current:?}) must be less or equal to {limit}"
)]
InvalidGroupSize { current: [u32; 3], limit: u32 },
#[error(transparent)]
BindingSizeTooSmall(#[from] LateMinBufferBindingSizeMismatch),
}
/// Error encountered when performing a compute pass.
#[derive(Clone, Debug, Error)]
pub enum ComputePassErrorInner {
#[error(transparent)]
Device(#[from] DeviceError),
#[error(transparent)]
Encoder(#[from] CommandEncoderError),
#[error("Parent encoder is invalid")]
InvalidParentEncoder,
#[error("Bind group index {index} is greater than the device's requested `max_bind_group` limit {max}")]
BindGroupIndexOutOfRange { index: u32, max: u32 },
#[error(transparent)]
DestroyedResource(#[from] DestroyedResourceError),
#[error("Indirect buffer offset {0:?} is not a multiple of 4")]
UnalignedIndirectBufferOffset(BufferAddress),
#[error("Indirect buffer uses bytes {offset}..{end_offset} which overruns indirect buffer of size {buffer_size}")]
IndirectBufferOverrun {
offset: u64,
end_offset: u64,
buffer_size: u64,
},
#[error(transparent)]
ResourceUsageCompatibility(#[from] ResourceUsageCompatibilityError),
#[error(transparent)]
MissingBufferUsage(#[from] MissingBufferUsageError),
#[error("Cannot pop debug group, because number of pushed debug groups is zero")]
InvalidPopDebugGroup,
#[error(transparent)]
Dispatch(#[from] DispatchError),
#[error(transparent)]
Bind(#[from] BindError),
#[error(transparent)]
PushConstants(#[from] PushConstantUploadError),
#[error("Push constant offset must be aligned to 4 bytes")]
PushConstantOffsetAlignment,
#[error("Push constant size must be aligned to 4 bytes")]
PushConstantSizeAlignment,
#[error("Ran out of push constant space. Don't set 4gb of push constants per ComputePass.")]
PushConstantOutOfMemory,
#[error(transparent)]
QueryUse(#[from] QueryUseError),
#[error(transparent)]
MissingFeatures(#[from] MissingFeatures),
#[error(transparent)]
MissingDownlevelFlags(#[from] MissingDownlevelFlags),
#[error("The compute pass has already been ended and no further commands can be recorded")]
PassEnded,
#[error(transparent)]
InvalidResource(#[from] InvalidResourceError),
}
/// Error encountered when performing a compute pass.
#[derive(Clone, Debug, Error)]
#[error("{scope}")]
pub struct ComputePassError {
pub scope: PassErrorScope,
#[source]
pub(super) inner: ComputePassErrorInner,
}
impl<T, E> MapPassErr<T, ComputePassError> for Result<T, E>
where
E: Into<ComputePassErrorInner>,
{
fn map_pass_err(self, scope: PassErrorScope) -> Result<T, ComputePassError> {
self.map_err(|inner| ComputePassError {
scope,
inner: inner.into(),
})
}
}
struct State<'scope, 'snatch_guard, 'cmd_buf, 'raw_encoder> {
binder: Binder,
pipeline: Option<Arc<ComputePipeline>>,
scope: UsageScope<'scope>,
debug_scope_depth: u32,
snatch_guard: SnatchGuard<'snatch_guard>,
device: &'cmd_buf Arc<Device>,
raw_encoder: &'raw_encoder mut dyn hal::DynCommandEncoder,
tracker: &'cmd_buf mut Tracker,
buffer_memory_init_actions: &'cmd_buf mut Vec<BufferInitTrackerAction>,
texture_memory_actions: &'cmd_buf mut CommandBufferTextureMemoryActions,
tlas_actions: &'cmd_buf mut Vec<TlasAction>,
temp_offsets: Vec<u32>,
dynamic_offset_count: usize,
string_offset: usize,
active_query: Option<(Arc<resource::QuerySet>, u32)>,
push_constants: Vec<u32>,
intermediate_trackers: Tracker,
/// Immediate texture inits required because of prior discards. Need to
/// be inserted before texture reads.
pending_discard_init_fixups: SurfacesInDiscardState,
}
impl<'scope, 'snatch_guard, 'cmd_buf, 'raw_encoder>
State<'scope, 'snatch_guard, 'cmd_buf, 'raw_encoder>
{
fn is_ready(&self) -> Result<(), DispatchError> {
if let Some(pipeline) = self.pipeline.as_ref() {
self.binder.check_compatibility(pipeline.as_ref())?;
self.binder.check_late_buffer_bindings()?;
Ok(())
} else {
Err(DispatchError::MissingPipeline)
}
}
// `extra_buffer` is there to represent the indirect buffer that is also
// part of the usage scope.
fn flush_states(
&mut self,
indirect_buffer: Option<TrackerIndex>,
) -> Result<(), ResourceUsageCompatibilityError> {
for bind_group in self.binder.list_active() {
unsafe { self.scope.merge_bind_group(&bind_group.used)? };
// Note: stateless trackers are not merged: the lifetime reference
// is held to the bind group itself.
}
for bind_group in self.binder.list_active() {
unsafe {
self.intermediate_trackers
.set_and_remove_from_usage_scope_sparse(&mut self.scope, &bind_group.used)
}
}
// Add the state of the indirect buffer if it hasn't been hit before.
unsafe {
self.intermediate_trackers
.buffers
.set_and_remove_from_usage_scope_sparse(&mut self.scope.buffers, indirect_buffer);
}
CommandBuffer::drain_barriers(
self.raw_encoder,
&mut self.intermediate_trackers,
&self.snatch_guard,
);
Ok(())
}
}
// Running the compute pass.
impl Global {
/// Creates a compute pass.
///
/// If creation fails, an invalid pass is returned.
/// Any operation on an invalid pass will return an error.
///
/// If successful, puts the encoder into the [`CommandEncoderStatus::Locked`] state.
pub fn command_encoder_create_compute_pass(
&self,
encoder_id: id::CommandEncoderId,
desc: &ComputePassDescriptor<'_>,
) -> (ComputePass, Option<CommandEncoderError>) {
let hub = &self.hub;
let mut arc_desc = ArcComputePassDescriptor {
label: &desc.label,
timestamp_writes: None, // Handle only once we resolved the encoder.
};
let make_err = |e, arc_desc| (ComputePass::new(None, arc_desc), Some(e));
let cmd_buf = hub.command_buffers.get(encoder_id.into_command_buffer_id());
match cmd_buf
.try_get()
.map_err(|e| e.into())
.and_then(|mut cmd_buf_data| cmd_buf_data.lock_encoder())
{
Ok(_) => {}
Err(e) => return make_err(e, arc_desc),
};
arc_desc.timestamp_writes = match desc
.timestamp_writes
.map(|tw| {
Self::validate_pass_timestamp_writes(&cmd_buf.device, &hub.query_sets.read(), tw)
})
.transpose()
{
Ok(ok) => ok,
Err(e) => return make_err(e, arc_desc),
};
(ComputePass::new(Some(cmd_buf), arc_desc), None)
}
/// Note that this differs from [`Self::compute_pass_end`], it will
/// create a new pass, replay the commands and end the pass.
#[doc(hidden)]
#[cfg(any(feature = "serde", feature = "replay"))]
pub fn compute_pass_end_with_unresolved_commands(
&self,
encoder_id: id::CommandEncoderId,
base: BasePass<super::ComputeCommand>,
timestamp_writes: Option<&PassTimestampWrites>,
) -> Result<(), ComputePassError> {
let pass_scope = PassErrorScope::Pass;
#[cfg(feature = "trace")]
{
let cmd_buf = self
.hub
.command_buffers
.get(encoder_id.into_command_buffer_id());
let mut cmd_buf_data = cmd_buf.try_get().map_pass_err(pass_scope)?;
if let Some(ref mut list) = cmd_buf_data.commands {
list.push(crate::device::trace::Command::RunComputePass {
base: BasePass {
label: base.label.clone(),
commands: base.commands.clone(),
dynamic_offsets: base.dynamic_offsets.clone(),
string_data: base.string_data.clone(),
push_constant_data: base.push_constant_data.clone(),
},
timestamp_writes: timestamp_writes.cloned(),
});
}
}
let BasePass {
label,
commands,
dynamic_offsets,
string_data,
push_constant_data,
} = base;
let (mut compute_pass, encoder_error) = self.command_encoder_create_compute_pass(
encoder_id,
&ComputePassDescriptor {
label: label.as_deref().map(std::borrow::Cow::Borrowed),
timestamp_writes,
},
);
if let Some(err) = encoder_error {
return Err(ComputePassError {
scope: pass_scope,
inner: err.into(),
});
};
compute_pass.base = Some(BasePass {
label,
commands: super::ComputeCommand::resolve_compute_command_ids(&self.hub, &commands)?,
dynamic_offsets,
string_data,
push_constant_data,
});
self.compute_pass_end(&mut compute_pass)
}
pub fn compute_pass_end(&self, pass: &mut ComputePass) -> Result<(), ComputePassError> {
profiling::scope!("CommandEncoder::run_compute_pass");
let pass_scope = PassErrorScope::Pass;
let cmd_buf = pass
.parent
.as_ref()
.ok_or(ComputePassErrorInner::InvalidParentEncoder)
.map_pass_err(pass_scope)?;
let base = pass
.base
.take()
.ok_or(ComputePassErrorInner::PassEnded)
.map_pass_err(pass_scope)?;
let device = &cmd_buf.device;
device.check_is_valid().map_pass_err(pass_scope)?;
let mut cmd_buf_data = cmd_buf.try_get().map_pass_err(pass_scope)?;
cmd_buf_data.unlock_encoder().map_pass_err(pass_scope)?;
let cmd_buf_data = &mut *cmd_buf_data;
let encoder = &mut cmd_buf_data.encoder;
let status = &mut cmd_buf_data.status;
// We automatically keep extending command buffers over time, and because
// we want to insert a command buffer _before_ what we're about to record,
// we need to make sure to close the previous one.
encoder.close(&cmd_buf.device).map_pass_err(pass_scope)?;
// will be reset to true if recording is done without errors
*status = CommandEncoderStatus::Error;
let raw_encoder = encoder.open(&cmd_buf.device).map_pass_err(pass_scope)?;
let mut state = State {
binder: Binder::new(),
pipeline: None,
scope: device.new_usage_scope(),
debug_scope_depth: 0,
snatch_guard: device.snatchable_lock.read(),
device,
raw_encoder,
tracker: &mut cmd_buf_data.trackers,
buffer_memory_init_actions: &mut cmd_buf_data.buffer_memory_init_actions,
texture_memory_actions: &mut cmd_buf_data.texture_memory_actions,
tlas_actions: &mut cmd_buf_data.tlas_actions,
temp_offsets: Vec::new(),
dynamic_offset_count: 0,
string_offset: 0,
active_query: None,
push_constants: Vec::new(),
intermediate_trackers: Tracker::new(),
pending_discard_init_fixups: SurfacesInDiscardState::new(),
};
let indices = &state.device.tracker_indices;
state.tracker.buffers.set_size(indices.buffers.size());
state.tracker.textures.set_size(indices.textures.size());
let timestamp_writes: Option<hal::PassTimestampWrites<'_, dyn hal::DynQuerySet>> =
if let Some(tw) = pass.timestamp_writes.take() {
tw.query_set
.same_device_as(cmd_buf.as_ref())
.map_pass_err(pass_scope)?;
let query_set = state.tracker.query_sets.insert_single(tw.query_set);
// Unlike in render passes we can't delay resetting the query sets since
// there is no auxiliary pass.
let range = if let (Some(index_a), Some(index_b)) =
(tw.beginning_of_pass_write_index, tw.end_of_pass_write_index)
{
Some(index_a.min(index_b)..index_a.max(index_b) + 1)
} else {
tw.beginning_of_pass_write_index
.or(tw.end_of_pass_write_index)
.map(|i| i..i + 1)
};
// Range should always be Some, both values being None should lead to a validation error.
// But no point in erroring over that nuance here!
if let Some(range) = range {
unsafe {
state.raw_encoder.reset_queries(query_set.raw(), range);
}
}
Some(hal::PassTimestampWrites {
query_set: query_set.raw(),
beginning_of_pass_write_index: tw.beginning_of_pass_write_index,
end_of_pass_write_index: tw.end_of_pass_write_index,
})
} else {
None
};
let hal_desc = hal::ComputePassDescriptor {
label: hal_label(base.label.as_deref(), device.instance_flags),
timestamp_writes,
};
unsafe {
state.raw_encoder.begin_compute_pass(&hal_desc);
}
for command in base.commands {
match command {
ArcComputeCommand::SetBindGroup {
index,
num_dynamic_offsets,
bind_group,
} => {
let scope = PassErrorScope::SetBindGroup;
set_bind_group(
&mut state,
cmd_buf,
&base.dynamic_offsets,
index,
num_dynamic_offsets,
bind_group,
)
.map_pass_err(scope)?;
}
ArcComputeCommand::SetPipeline(pipeline) => {
let scope = PassErrorScope::SetPipelineCompute;
set_pipeline(&mut state, cmd_buf, pipeline).map_pass_err(scope)?;
}
ArcComputeCommand::SetPushConstant {
offset,
size_bytes,
values_offset,
} => {
let scope = PassErrorScope::SetPushConstant;
set_push_constant(
&mut state,
&base.push_constant_data,
offset,
size_bytes,
values_offset,
)
.map_pass_err(scope)?;
}
ArcComputeCommand::Dispatch(groups) => {
let scope = PassErrorScope::Dispatch { indirect: false };
dispatch(&mut state, groups).map_pass_err(scope)?;
}
ArcComputeCommand::DispatchIndirect { buffer, offset } => {
let scope = PassErrorScope::Dispatch { indirect: true };
dispatch_indirect(&mut state, cmd_buf, buffer, offset).map_pass_err(scope)?;
}
ArcComputeCommand::PushDebugGroup { color: _, len } => {
push_debug_group(&mut state, &base.string_data, len);
}
ArcComputeCommand::PopDebugGroup => {
let scope = PassErrorScope::PopDebugGroup;
pop_debug_group(&mut state).map_pass_err(scope)?;
}
ArcComputeCommand::InsertDebugMarker { color: _, len } => {
insert_debug_marker(&mut state, &base.string_data, len);
}
ArcComputeCommand::WriteTimestamp {
query_set,
query_index,
} => {
let scope = PassErrorScope::WriteTimestamp;
write_timestamp(&mut state, cmd_buf, query_set, query_index)
.map_pass_err(scope)?;
}
ArcComputeCommand::BeginPipelineStatisticsQuery {
query_set,
query_index,
} => {
let scope = PassErrorScope::BeginPipelineStatisticsQuery;
validate_and_begin_pipeline_statistics_query(
query_set,
state.raw_encoder,
&mut state.tracker.query_sets,
cmd_buf,
query_index,
None,
&mut state.active_query,
)
.map_pass_err(scope)?;
}
ArcComputeCommand::EndPipelineStatisticsQuery => {
let scope = PassErrorScope::EndPipelineStatisticsQuery;
end_pipeline_statistics_query(state.raw_encoder, &mut state.active_query)
.map_pass_err(scope)?;
}
}
}
unsafe {
state.raw_encoder.end_compute_pass();
}
// We've successfully recorded the compute pass, bring the
// command buffer out of the error state.
*status = CommandEncoderStatus::Recording;
let State {
snatch_guard,
tracker,
intermediate_trackers,
pending_discard_init_fixups,
..
} = state;
// Stop the current command buffer.
encoder.close(&cmd_buf.device).map_pass_err(pass_scope)?;
// Create a new command buffer, which we will insert _before_ the body of the compute pass.
//
// Use that buffer to insert barriers and clear discarded images.
let transit = encoder.open(&cmd_buf.device).map_pass_err(pass_scope)?;
fixup_discarded_surfaces(
pending_discard_init_fixups.into_iter(),
transit,
&mut tracker.textures,
device,
&snatch_guard,
);
CommandBuffer::insert_barriers_from_tracker(
transit,
tracker,
&intermediate_trackers,
&snatch_guard,
);
// Close the command buffer, and swap it with the previous.
encoder
.close_and_swap(&cmd_buf.device)
.map_pass_err(pass_scope)?;
Ok(())
}
}
fn set_bind_group(
state: &mut State,
cmd_buf: &CommandBuffer,
dynamic_offsets: &[DynamicOffset],
index: u32,
num_dynamic_offsets: usize,
bind_group: Option<Arc<BindGroup>>,
) -> Result<(), ComputePassErrorInner> {
let max_bind_groups = state.device.limits.max_bind_groups;
if index >= max_bind_groups {
return Err(ComputePassErrorInner::BindGroupIndexOutOfRange {
index,
max: max_bind_groups,
});
}
state.temp_offsets.clear();
state.temp_offsets.extend_from_slice(
&dynamic_offsets
[state.dynamic_offset_count..state.dynamic_offset_count + num_dynamic_offsets],
);
state.dynamic_offset_count += num_dynamic_offsets;
if bind_group.is_none() {
// TODO: Handle bind_group None.
return Ok(());
}
let bind_group = bind_group.unwrap();
let bind_group = state.tracker.bind_groups.insert_single(bind_group);
bind_group.same_device_as(cmd_buf)?;
bind_group.validate_dynamic_bindings(index, &state.temp_offsets)?;
state
.buffer_memory_init_actions
.extend(bind_group.used_buffer_ranges.iter().filter_map(|action| {
action
.buffer
.initialization_status
.read()
.check_action(action)
}));
for action in bind_group.used_texture_ranges.iter() {
state
.pending_discard_init_fixups
.extend(state.texture_memory_actions.register_init_action(action));
}
let used_resource = bind_group
.used
.acceleration_structures
.into_iter()
.map(|tlas| TlasAction {
tlas: tlas.clone(),
kind: crate::ray_tracing::TlasActionKind::Use,
});
state.tlas_actions.extend(used_resource);
let pipeline_layout = state.binder.pipeline_layout.clone();
let entries = state
.binder
.assign_group(index as usize, bind_group, &state.temp_offsets);
if !entries.is_empty() && pipeline_layout.is_some() {
let pipeline_layout = pipeline_layout.as_ref().unwrap().raw();
for (i, e) in entries.iter().enumerate() {
if let Some(group) = e.group.as_ref() {
let raw_bg = group.try_raw(&state.snatch_guard)?;
unsafe {
state.raw_encoder.set_bind_group(
pipeline_layout,
index + i as u32,
Some(raw_bg),
&e.dynamic_offsets,
);
}
}
}
}
Ok(())
}
fn set_pipeline(
state: &mut State,
cmd_buf: &CommandBuffer,
pipeline: Arc<ComputePipeline>,
) -> Result<(), ComputePassErrorInner> {
pipeline.same_device_as(cmd_buf)?;
state.pipeline = Some(pipeline.clone());
let pipeline = state.tracker.compute_pipelines.insert_single(pipeline);
unsafe {
state.raw_encoder.set_compute_pipeline(pipeline.raw());
}
// Rebind resources
if state.binder.pipeline_layout.is_none()
|| !state
.binder
.pipeline_layout
.as_ref()
.unwrap()
.is_equal(&pipeline.layout)
{
let (start_index, entries) = state
.binder
.change_pipeline_layout(&pipeline.layout, &pipeline.late_sized_buffer_groups);
if !entries.is_empty() {
for (i, e) in entries.iter().enumerate() {
if let Some(group) = e.group.as_ref() {
let raw_bg = group.try_raw(&state.snatch_guard)?;
unsafe {
state.raw_encoder.set_bind_group(
pipeline.layout.raw(),
start_index as u32 + i as u32,
Some(raw_bg),
&e.dynamic_offsets,
);
}
}
}
}
// TODO: integrate this in the code below once we simplify push constants
state.push_constants.clear();
// Note that can only be one range for each stage. See the `MoreThanOnePushConstantRangePerStage` error.
if let Some(push_constant_range) =
pipeline.layout.push_constant_ranges.iter().find_map(|pcr| {
pcr.stages
.contains(wgt::ShaderStages::COMPUTE)
.then_some(pcr.range.clone())
})
{
let len = push_constant_range.len() / wgt::PUSH_CONSTANT_ALIGNMENT as usize;
state.push_constants.extend(core::iter::repeat(0).take(len));
}
// Clear push constant ranges
let non_overlapping =
super::bind::compute_nonoverlapping_ranges(&pipeline.layout.push_constant_ranges);
for range in non_overlapping {
let offset = range.range.start;
let size_bytes = range.range.end - offset;
super::push_constant_clear(offset, size_bytes, |clear_offset, clear_data| unsafe {
state.raw_encoder.set_push_constants(
pipeline.layout.raw(),
wgt::ShaderStages::COMPUTE,
clear_offset,
clear_data,
);
});
}
}
Ok(())
}
fn set_push_constant(
state: &mut State,
push_constant_data: &[u32],
offset: u32,
size_bytes: u32,
values_offset: u32,
) -> Result<(), ComputePassErrorInner> {
let end_offset_bytes = offset + size_bytes;
let values_end_offset = (values_offset + size_bytes / wgt::PUSH_CONSTANT_ALIGNMENT) as usize;
let data_slice = &push_constant_data[(values_offset as usize)..values_end_offset];
let pipeline_layout = state
.binder
.pipeline_layout
.as_ref()
// TODO: don't error here, lazily update the push constants using `state.push_constants`
.ok_or(ComputePassErrorInner::Dispatch(
DispatchError::MissingPipeline,
))?;
pipeline_layout.validate_push_constant_ranges(
wgt::ShaderStages::COMPUTE,
offset,
end_offset_bytes,
)?;
let offset_in_elements = (offset / wgt::PUSH_CONSTANT_ALIGNMENT) as usize;
let size_in_elements = (size_bytes / wgt::PUSH_CONSTANT_ALIGNMENT) as usize;
state.push_constants[offset_in_elements..][..size_in_elements].copy_from_slice(data_slice);
unsafe {
state.raw_encoder.set_push_constants(
pipeline_layout.raw(),
wgt::ShaderStages::COMPUTE,
offset,
data_slice,
);
}
Ok(())
}
fn dispatch(state: &mut State, groups: [u32; 3]) -> Result<(), ComputePassErrorInner> {
state.is_ready()?;
state.flush_states(None)?;
let groups_size_limit = state.device.limits.max_compute_workgroups_per_dimension;
if groups[0] > groups_size_limit
|| groups[1] > groups_size_limit
|| groups[2] > groups_size_limit
{
return Err(ComputePassErrorInner::Dispatch(
DispatchError::InvalidGroupSize {
current: groups,
limit: groups_size_limit,
},
));
}
unsafe {
state.raw_encoder.dispatch(groups);
}
Ok(())
}
fn dispatch_indirect(
state: &mut State,
cmd_buf: &CommandBuffer,
buffer: Arc<Buffer>,
offset: u64,
) -> Result<(), ComputePassErrorInner> {
buffer.same_device_as(cmd_buf)?;
state.is_ready()?;
state
.device
.require_downlevel_flags(wgt::DownlevelFlags::INDIRECT_EXECUTION)?;
buffer.check_usage(wgt::BufferUsages::INDIRECT)?;
if offset % 4 != 0 {
return Err(ComputePassErrorInner::UnalignedIndirectBufferOffset(offset));
}
let end_offset = offset + size_of::<wgt::DispatchIndirectArgs>() as u64;
if end_offset > buffer.size {
return Err(ComputePassErrorInner::IndirectBufferOverrun {
offset,
end_offset,
buffer_size: buffer.size,
});
}
let stride = 3 * 4; // 3 integers, x/y/z group size
state
.buffer_memory_init_actions
.extend(buffer.initialization_status.read().create_action(
&buffer,
offset..(offset + stride),
MemoryInitKind::NeedsInitializedMemory,
));
#[cfg(feature = "indirect-validation")]
{
let params = state.device.indirect_validation.as_ref().unwrap().params(
&state.device.limits,
offset,
buffer.size,
);
unsafe {
state.raw_encoder.set_compute_pipeline(params.pipeline);
}
unsafe {
state.raw_encoder.set_push_constants(
params.pipeline_layout,
wgt::ShaderStages::COMPUTE,
0,
&[params.offset_remainder as u32 / 4],
);
}
unsafe {
state.raw_encoder.set_bind_group(
params.pipeline_layout,
0,
Some(params.dst_bind_group),
&[],
);
}
unsafe {
state.raw_encoder.set_bind_group(
params.pipeline_layout,
1,
Some(
buffer
.raw_indirect_validation_bind_group
.get(&state.snatch_guard)
.unwrap()
.as_ref(),
),
&[params.aligned_offset as u32],
);
}
let src_transition = state
.intermediate_trackers
.buffers
.set_single(&buffer, hal::BufferUses::STORAGE_READ);
let src_barrier =
src_transition.map(|transition| transition.into_hal(&buffer, &state.snatch_guard));
unsafe {
state.raw_encoder.transition_buffers(src_barrier.as_slice());
}
unsafe {
state.raw_encoder.transition_buffers(&[hal::BufferBarrier {
buffer: params.dst_buffer,
usage: hal::BufferUses::INDIRECT..hal::BufferUses::STORAGE_READ_WRITE,
}]);
}
unsafe {
state.raw_encoder.dispatch([1, 1, 1]);
}
// reset state
{
let pipeline = state.pipeline.as_ref().unwrap();
unsafe {
state.raw_encoder.set_compute_pipeline(pipeline.raw());
}
if !state.push_constants.is_empty() {
unsafe {
state.raw_encoder.set_push_constants(
pipeline.layout.raw(),
wgt::ShaderStages::COMPUTE,
0,
&state.push_constants,
);
}
}
for (i, e) in state.binder.list_valid() {
let group = e.group.as_ref().unwrap();
let raw_bg = group.try_raw(&state.snatch_guard)?;
unsafe {
state.raw_encoder.set_bind_group(
pipeline.layout.raw(),
i as u32,
Some(raw_bg),
&e.dynamic_offsets,
);
}
}
}
unsafe {
state.raw_encoder.transition_buffers(&[hal::BufferBarrier {
buffer: params.dst_buffer,
usage: hal::BufferUses::STORAGE_READ_WRITE..hal::BufferUses::INDIRECT,
}]);
}
state.flush_states(None)?;
unsafe {
state.raw_encoder.dispatch_indirect(params.dst_buffer, 0);
}
};
#[cfg(not(feature = "indirect-validation"))]
{
state
.scope
.buffers
.merge_single(&buffer, hal::BufferUses::INDIRECT)?;
use crate::resource::Trackable;
state.flush_states(Some(buffer.tracker_index()))?;
let buf_raw = buffer.try_raw(&state.snatch_guard)?;
unsafe {
state.raw_encoder.dispatch_indirect(buf_raw, offset);
}
}
Ok(())
}
fn push_debug_group(state: &mut State, string_data: &[u8], len: usize) {
state.debug_scope_depth += 1;
if !state
.device
.instance_flags
.contains(wgt::InstanceFlags::DISCARD_HAL_LABELS)
{
let label =
str::from_utf8(&string_data[state.string_offset..state.string_offset + len]).unwrap();
unsafe {
state.raw_encoder.begin_debug_marker(label);
}
}
state.string_offset += len;
}
fn pop_debug_group(state: &mut State) -> Result<(), ComputePassErrorInner> {
if state.debug_scope_depth == 0 {
return Err(ComputePassErrorInner::InvalidPopDebugGroup);
}
state.debug_scope_depth -= 1;
if !state
.device
.instance_flags
.contains(wgt::InstanceFlags::DISCARD_HAL_LABELS)
{
unsafe {
state.raw_encoder.end_debug_marker();
}
}
Ok(())
}
fn insert_debug_marker(state: &mut State, string_data: &[u8], len: usize) {
if !state
.device
.instance_flags
.contains(wgt::InstanceFlags::DISCARD_HAL_LABELS)
{
let label =
str::from_utf8(&string_data[state.string_offset..state.string_offset + len]).unwrap();
unsafe { state.raw_encoder.insert_debug_marker(label) }
}
state.string_offset += len;
}
fn write_timestamp(
state: &mut State,
cmd_buf: &CommandBuffer,
query_set: Arc<resource::QuerySet>,
query_index: u32,
) -> Result<(), ComputePassErrorInner> {
query_set.same_device_as(cmd_buf)?;
state
.device
.require_features(wgt::Features::TIMESTAMP_QUERY_INSIDE_PASSES)?;
let query_set = state.tracker.query_sets.insert_single(query_set);
query_set.validate_and_write_timestamp(state.raw_encoder, query_index, None)?;
Ok(())
}
// Recording a compute pass.
impl Global {
pub fn compute_pass_set_bind_group(
&self,
pass: &mut ComputePass,
index: u32,
bind_group_id: Option<id::BindGroupId>,
offsets: &[DynamicOffset],
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::SetBindGroup;
let base = pass
.base
.as_mut()
.ok_or(ComputePassErrorInner::PassEnded)
.map_pass_err(scope)?; // Can't use base_mut() utility here because of borrow checker.
let redundant = pass.current_bind_groups.set_and_check_redundant(
bind_group_id,
index,
&mut base.dynamic_offsets,
offsets,
);
if redundant {
return Ok(());
}
let mut bind_group = None;
if bind_group_id.is_some() {
let bind_group_id = bind_group_id.unwrap();
let hub = &self.hub;
let bg = hub
.bind_groups
.get(bind_group_id)
.get()
.map_pass_err(scope)?;
bind_group = Some(bg);
}
base.commands.push(ArcComputeCommand::SetBindGroup {
index,
num_dynamic_offsets: offsets.len(),
bind_group,
});
Ok(())
}
pub fn compute_pass_set_pipeline(
&self,
pass: &mut ComputePass,
pipeline_id: id::ComputePipelineId,
) -> Result<(), ComputePassError> {
let redundant = pass.current_pipeline.set_and_check_redundant(pipeline_id);
let scope = PassErrorScope::SetPipelineCompute;
let base = pass.base_mut(scope)?;
if redundant {
// Do redundant early-out **after** checking whether the pass is ended or not.
return Ok(());
}
let hub = &self.hub;
let pipeline = hub
.compute_pipelines
.get(pipeline_id)
.get()
.map_pass_err(scope)?;
base.commands.push(ArcComputeCommand::SetPipeline(pipeline));
Ok(())
}
pub fn compute_pass_set_push_constants(
&self,
pass: &mut ComputePass,
offset: u32,
data: &[u8],
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::SetPushConstant;
let base = pass.base_mut(scope)?;
if offset & (wgt::PUSH_CONSTANT_ALIGNMENT - 1) != 0 {
return Err(ComputePassErrorInner::PushConstantOffsetAlignment).map_pass_err(scope);
}
if data.len() as u32 & (wgt::PUSH_CONSTANT_ALIGNMENT - 1) != 0 {
return Err(ComputePassErrorInner::PushConstantSizeAlignment).map_pass_err(scope);
}
let value_offset = base
.push_constant_data
.len()
.try_into()
.map_err(|_| ComputePassErrorInner::PushConstantOutOfMemory)
.map_pass_err(scope)?;
base.push_constant_data.extend(
data.chunks_exact(wgt::PUSH_CONSTANT_ALIGNMENT as usize)
.map(|arr| u32::from_ne_bytes([arr[0], arr[1], arr[2], arr[3]])),
);
base.commands.push(ArcComputeCommand::SetPushConstant {
offset,
size_bytes: data.len() as u32,
values_offset: value_offset,
});
Ok(())
}
pub fn compute_pass_dispatch_workgroups(
&self,
pass: &mut ComputePass,
groups_x: u32,
groups_y: u32,
groups_z: u32,
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::Dispatch { indirect: false };
let base = pass.base_mut(scope)?;
base.commands
.push(ArcComputeCommand::Dispatch([groups_x, groups_y, groups_z]));
Ok(())
}
pub fn compute_pass_dispatch_workgroups_indirect(
&self,
pass: &mut ComputePass,
buffer_id: id::BufferId,
offset: BufferAddress,
) -> Result<(), ComputePassError> {
let hub = &self.hub;
let scope = PassErrorScope::Dispatch { indirect: true };
let base = pass.base_mut(scope)?;
let buffer = hub.buffers.get(buffer_id).get().map_pass_err(scope)?;
base.commands
.push(ArcComputeCommand::DispatchIndirect { buffer, offset });
Ok(())
}
pub fn compute_pass_push_debug_group(
&self,
pass: &mut ComputePass,
label: &str,
color: u32,
) -> Result<(), ComputePassError> {
let base = pass.base_mut(PassErrorScope::PushDebugGroup)?;
let bytes = label.as_bytes();
base.string_data.extend_from_slice(bytes);
base.commands.push(ArcComputeCommand::PushDebugGroup {
color,
len: bytes.len(),
});
Ok(())
}
pub fn compute_pass_pop_debug_group(
&self,
pass: &mut ComputePass,
) -> Result<(), ComputePassError> {
let base = pass.base_mut(PassErrorScope::PopDebugGroup)?;
base.commands.push(ArcComputeCommand::PopDebugGroup);
Ok(())
}
pub fn compute_pass_insert_debug_marker(
&self,
pass: &mut ComputePass,
label: &str,
color: u32,
) -> Result<(), ComputePassError> {
let base = pass.base_mut(PassErrorScope::InsertDebugMarker)?;
let bytes = label.as_bytes();
base.string_data.extend_from_slice(bytes);
base.commands.push(ArcComputeCommand::InsertDebugMarker {
color,
len: bytes.len(),
});
Ok(())
}
pub fn compute_pass_write_timestamp(
&self,
pass: &mut ComputePass,
query_set_id: id::QuerySetId,
query_index: u32,
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::WriteTimestamp;
let base = pass.base_mut(scope)?;
let hub = &self.hub;
let query_set = hub.query_sets.get(query_set_id).get().map_pass_err(scope)?;
base.commands.push(ArcComputeCommand::WriteTimestamp {
query_set,
query_index,
});
Ok(())
}
pub fn compute_pass_begin_pipeline_statistics_query(
&self,
pass: &mut ComputePass,
query_set_id: id::QuerySetId,
query_index: u32,
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::BeginPipelineStatisticsQuery;
let base = pass.base_mut(scope)?;
let hub = &self.hub;
let query_set = hub.query_sets.get(query_set_id).get().map_pass_err(scope)?;
base.commands
.push(ArcComputeCommand::BeginPipelineStatisticsQuery {
query_set,
query_index,
});
Ok(())
}
pub fn compute_pass_end_pipeline_statistics_query(
&self,
pass: &mut ComputePass,
) -> Result<(), ComputePassError> {
let scope = PassErrorScope::EndPipelineStatisticsQuery;
let base = pass.base_mut(scope)?;
base.commands
.push(ArcComputeCommand::EndPipelineStatisticsQuery);
Ok(())
}
}