QwenFunControlNet.pre_run stashes the model's diffusion_model into
self.extra_args['base_model'], but ControlBase.cleanup never clears
extra_args. The diffusion_model reference therefore lingered between
sampling runs, blocking ComfyUI's model offload/eviction logic from
freeing the UNet and -- for multigpu -- holding one such reference per
per-device control clone (defeating the max_gpus pruning added in this
PR). Override cleanup to drop the entry; super().cleanup() already
recurses into multigpu_clones so each per-device clone pops its own.
Amp-Thread-ID: https://ampcode.com/threads/T-019e4a00-fe3d-76bd-a2f2-a8c8c4040082
Co-authored-by: Amp <amp@ampcode.com>
Drop the new ignore_multigpu positional argument from prepare_state and
from the ON_PREPARE_STATE callbacks; pass the flag via model_options
instead. This restores the original 3-arg callback signature so existing
custom-node ON_PREPARE_STATE handlers keep working unchanged, while
still letting prepare_state's recursive call into multigpu_clones
short-circuit.
Amp-Thread-ID: https://ampcode.com/threads/T-019e4a00-fe3d-76bd-a2f2-a8c8c4040082
Co-authored-by: Amp <amp@ampcode.com>
Two doc-only changes addressing minor CodeRabbit findings on PR #7063:
* cli_args.py: clarify --cuda-device help text to document the required comma-separated format ('0' or '0,1'), matching how the value is consumed by CUDA_VISIBLE_DEVICES in main.py.
* nodes_multigpu.py: add a docstring NOTE on the (currently unregistered) MultiGPUOptionsNode explaining that its relative_speed input is plumbed through to model_options['multigpu_options'] but is not yet consulted by the cond scheduler, which still uses uniform round-robin via next_available_device(). Wire relative_speed into the scheduler before re-enabling the node.
Amp-Thread-ID: https://ampcode.com/threads/T-019e43b8-8258-70fd-ab3a-53e4c97f85d5
Co-authored-by: Amp <amp@ampcode.com>
The multigpu cond-batching loop called model.memory_required(input_shape) without conditioning shapes, while the single-GPU path at line 279 passes cond_shapes. Large conditioning tensors (e.g. video prompts, control inputs) were therefore under-counted, risking OOM at runtime when the chosen batch size was too large. Match the single-GPU pattern by building cond_shapes from each batched cond's conditioning dict and passing it to memory_required.
Amp-Thread-ID: https://ampcode.com/threads/T-019e43b8-8258-70fd-ab3a-53e4c97f85d5
Co-authored-by: Amp <amp@ampcode.com>
create_multigpu_deepclones cloned the existing 'multigpu' additional_models list verbatim and never pruned entries beyond limit_extra_devices. If a workflow was previously prepared for more GPUs, reducing max_gpus would leave stale clones attached and eligible for later scheduling. Replace the TODO block with a real prune that keeps only clones whose load_device is either the model's load_device or in limit_extra_devices, and re-match clones if anything was removed.
Amp-Thread-ID: https://ampcode.com/threads/T-019e43b8-8258-70fd-ab3a-53e4c97f85d5
Co-authored-by: Amp <amp@ampcode.com>
torch.device(i) defaults to CUDA, so XPU/NPU branches were producing 'cuda:N' devices that don't match get_torch_device() output ('xpu:N'/'npu:N'). This caused devices.remove(get_torch_device()) to raise ValueError when exclude_current=True on non-NVIDIA hardware. Use explicit device strings, and guard the remove() with a membership check for safety.
Amp-Thread-ID: https://ampcode.com/threads/T-019e43b8-8258-70fd-ab3a-53e4c97f85d5
Co-authored-by: Amp <amp@ampcode.com>
load_checkpoint_guess_config_clip_only() calls load_checkpoint_guess_config() with output_model=False, leaving out[0] as None. The subsequent unconditional assignment of cached_patcher_init crashed with AttributeError, breaking CLIP-only checkpoint loading entirely. Guard the assignment with a None check.
Amp-Thread-ID: https://ampcode.com/threads/T-019e43b8-8258-70fd-ab3a-53e4c97f85d5
Co-authored-by: Amp <amp@ampcode.com>
Behaviour-equivalent cleanup of _calc_cond_batch_multigpu device
scheduling. No change to batching decisions or memory checks for any
valid input.
Changes:
* Replace re-summed batched_to_run_length with a per-device load
dict (device_load), so capacity checks are O(1) and use a single
source of truth.
* Extract device selection into next_available_device(), which scans
at most len(devices) positions and raises if no device has
remaining capacity. This makes the 'skip a full device' rule live
in one place instead of two and guarantees the outer while loop
cannot spin forever on a scheduling bug.
* Drop the unused current_device assignment before the outer loop
and the index_device % len(devices) modulo dance (now handled
inside next_available_device).
* Minor cleanups: list comprehensions for total_conds, conds_to_batch,
and the devices list.
Fixes _calc_cond_batch_multigpu so that:
1. conds_per_device uses real division before math.ceil. The previous
expression math.ceil(total_conds // len(devices)) applied integer
floor division first, making ceil a no-op. For 3 conds across 2
devices this produced conds_per_device=1 instead of 2.
2. The scheduling loop skips devices that have already reached
capacity instead of appending empty batch groups. Without this
guard, the loop could repeatedly emit zero-length groups for a
full device, leaving sampling stuck at 0/N until timeout.
Reproduces with an Omnigen2 image workflow that produces three
condition entries scheduled across two CUDA devices. With the fix
the scheduler assigns conds_per_device=2 and splits the batches as
2 + 1 across the two devices, allowing sampling to complete.
Original fix authored and validated by @pollockjj in
pollockjj/ComfyUI#64.
Co-authored-by: John Pollock <pollockjj@gmail.com>
* Initial HiDream01-image support
* Cleanup nodes
* Cleaner handling of empty placeholder models
* Remove snap_to_predefined, prefer tooltip for the trained resolutions
* Add model and block wrappers
* Fix shift tooltip
* Add node to work around the patch tile issue
Experimental, runs multiple passes with the patch grid offset and blends with various different methods.
* Qwen35 vision rotary_pos_emb cast fix
* Fix embedding layout type
* Some small optimizations
* Cleanup, don't need this fallback
* Prefix KV cache, cleanup
Bit of speed, reduce redundant code
* Get rid of redundant custom sampler, refactor noise scaling
Our existing lcm sampler is mathematically same, just added the missing options to it instead and a node to control them. Refactored the noise scaling and fix it for the stochastic samplers, add a generic node to control the initial noise scale.
* Update nodes_hidream_o1.py
* Fix some cache validation cases
* Keep existing sampling params
* Remove redundant video vision path
* Replace some numpy ops with torch
* Fx RoPE index for batch size > 1
* Prefer torch preprocessing
* Rename block_type to be compatible with existing patch nodes
* Fixes and tweaks
* initial WanDancer support
* nodes_wandancer: Add list form of chunker.
Create an alternate list form of the node so the chunk gens can be
trivially looped by the comfy executor.
* Closer match to original soxr resampling
* Remove librosa node
* Cleanup
---------
Co-authored-by: Rattus <rattus128@gmail.com>
If the same weight is used multiple times within the same prefetch
window, it should only apply compute state mutations once. Mark the
weight as fully resident on the first pass accordingly.
* initial gemma4 support
* parity with reference implementation
outputs can 100% match transformers with same sdpa flags, checkpoint this and then optimize
* Cleanup, video fixes
* cleanup, enable fused rms norm by default
* update comment
* Cleanup
* Update sd.py
* Various fixes
* Add fp8 scaled embedding support
* small fixes
* Translate think tokens
* Fix image encoder attention mask type
So it works with basic attention
* Handle thinking tokens different only for Gemma4
* Code cleanup
* Update nodes_textgen.py
* Use embed scale class instead of buffer
Slight difference to HF, but technically more accurate and simpler code
* Default to fused rms_norm
* Update gemma4.py
* mm: Use Aimdo raw allocator for cast buffers
pytorch manages allocation of growing buffers on streams poorly. Pyt
has no windows support for the expandable segments allocator (which is
the right tool for this job), while also segmenting the memory by
stream such that it can be generally re-used. So kick the problem to
aimdo which can just grow a virtual region thats freed per stream.
* plan
* ops: move cpu handler up to the caller
* ops: split up prefetch from weight prep block prefetching API
Split up the casting and weight formating/lora stuff in prep for
arbitrary prefetch support.
* ops: implement block prefetching API
allow a model to construct a prefetch list and operate it for increased
async offload.
* ltxv2: Implement block prefetching
* Implement lora async offload
Implement async offload of loras.
