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KoboldAI-Client/modeling/inference_models/hf_torch.py
ebolam 5561cc1f22 Fix for GPU generation
2023-05-23 08:33:19 -04:00

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from __future__ import annotations
import gc
import os
import time
import bisect
import zipfile
import functools
import itertools
import traceback
import contextlib
from tqdm.auto import tqdm
from typing import Dict, List, Optional, Union
import torch
from torch.nn import Embedding
import transformers
from transformers import (
StoppingCriteria,
GPTNeoForCausalLM,
GPT2LMHeadModel,
AutoModelForCausalLM,
LogitsProcessorList,
)
import utils
import modeling.lazy_loader as lazy_loader
from logger import logger, Colors
from modeling import warpers
from modeling.warpers import Warper
from modeling.stoppers import Stoppers
from modeling.post_token_hooks import PostTokenHooks
from modeling.inference_models.hf import HFInferenceModel
from modeling.inference_model import (
GenerationResult,
GenerationSettings,
ModelCapabilities,
use_core_manipulations,
)
try:
import breakmodel
import accelerate.utils
except ModuleNotFoundError as e:
if not utils.koboldai_vars.use_colab_tpu:
raise e
# When set to true, messages will appear in the console if samplers are not
# changing the scores. Keep in mind some samplers don't always change the
# scores for each token.
LOG_SAMPLER_NO_EFFECT = False
class HFTorchInferenceModel(HFInferenceModel):
def __init__(self) -> None:
super().__init__()
self.hf_torch = True
self.lazy_load = True
self.low_mem = False
self.nobreakmodel = False
self.post_token_hooks = [
PostTokenHooks.stream_tokens,
]
self.stopper_hooks = [
Stoppers.core_stopper,
Stoppers.dynamic_wi_scanner,
Stoppers.singleline_stopper,
Stoppers.chat_mode_stopper,
Stoppers.stop_sequence_stopper,
]
self.capabilties = ModelCapabilities(
embedding_manipulation=True,
post_token_hooks=True,
stopper_hooks=True,
post_token_probs=True,
)
self._old_stopping_criteria = None
def _apply_warpers(
self, scores: torch.Tensor, input_ids: torch.Tensor
) -> torch.Tensor:
warpers.update_settings()
if LOG_SAMPLER_NO_EFFECT:
pre = torch.Tensor(scores)
for sid in utils.koboldai_vars.sampler_order:
warper = Warper.from_id(sid)
if not warper.value_is_valid():
continue
if warper == warpers.RepetitionPenalty:
# Rep pen needs more data than other samplers
scores = warper.torch(scores, input_ids=input_ids)
else:
scores = warper.torch(scores)
assert scores is not None, f"Scores are None; warper '{warper}' is to blame"
if LOG_SAMPLER_NO_EFFECT:
if torch.equal(pre, scores):
logger.info(warper, "had no effect on the scores.")
pre = torch.Tensor(scores)
return scores
def get_model_type(self) -> str:
if not self.model_config:
return "Read Only"
if not isinstance(self.model_config, dict):
return str(self.model_config.model_type)
model_type = self.model_config.get("model_type")
if model_type:
return model_type
if utils.koboldai_vars.mode.endswith("gpt2"):
return "gpt2"
else:
return "Unknown"
def get_auxilary_device(self):
"""Get device auxilary tensors like inputs should be stored on."""
# NOTE: TPU isn't a torch device, so TPU stuff gets sent to CPU.
if utils.koboldai_vars.hascuda and self.usegpu:
return utils.koboldai_vars.gpu_device
elif utils.koboldai_vars.hascuda and self.breakmodel:
import breakmodel
return breakmodel.primary_device
return "cpu"
def _post_load(m_self) -> None:
if not utils.koboldai_vars.model_type:
utils.koboldai_vars.model_type = m_self.get_model_type()
# Patch stopping_criteria
class PTHStopper(StoppingCriteria):
def __call__(
hf_self,
input_ids: torch.LongTensor,
scores: torch.FloatTensor,
) -> None:
m_self._post_token_gen(input_ids)
for stopper in m_self.stopper_hooks:
do_stop = stopper(m_self, input_ids)
if do_stop:
return True
return False
old_gsc = transformers.GenerationMixin._get_stopping_criteria
def _get_stopping_criteria(
hf_self,
*args,
**kwargs,
):
stopping_criteria = old_gsc(hf_self, *args, **kwargs)
stopping_criteria.insert(0, PTHStopper())
return stopping_criteria
use_core_manipulations.get_stopping_criteria = _get_stopping_criteria
# Patch logitswarpers
def new_get_logits_processor(*args, **kwargs) -> LogitsProcessorList:
processors = new_get_logits_processor.old_get_logits_processor(
*args, **kwargs
)
return processors
use_core_manipulations.get_logits_processor = new_get_logits_processor
new_get_logits_processor.old_get_logits_processor = (
transformers.GenerationMixin._get_logits_processor
)
class KoboldLogitsWarperList(LogitsProcessorList):
def __init__(self):
pass
def __call__(
lw_self,
input_ids: torch.LongTensor,
scores: torch.FloatTensor,
*args,
**kwargs,
):
scores = m_self._apply_warpers(scores=scores, input_ids=input_ids)
for processor in m_self.logits_processors:
scores = processor(m_self, scores=scores, input_ids=input_ids)
assert (
scores is not None
), f"Scores are None; processor '{processor}' is to blame"
return scores
def new_get_logits_warper(
beams: int = 1,
) -> LogitsProcessorList:
return KoboldLogitsWarperList()
def new_sample(self, *args, **kwargs):
assert kwargs.pop("logits_warper", None) is not None
kwargs["logits_warper"] = new_get_logits_warper(
beams=1,
)
if utils.koboldai_vars.newlinemode in ["s", "ns"]:
kwargs["eos_token_id"] = -1
kwargs.setdefault("pad_token_id", 2)
return new_sample.old_sample(self, *args, **kwargs)
new_sample.old_sample = transformers.GenerationMixin.sample
use_core_manipulations.sample = new_sample
return super()._post_load()
def _raw_generate(
self,
prompt_tokens: Union[List[int], torch.Tensor],
max_new: int,
gen_settings: GenerationSettings,
single_line: bool = False,
batch_count: int = 1,
seed: Optional[int] = None,
**kwargs,
) -> GenerationResult:
if not isinstance(prompt_tokens, torch.Tensor):
gen_in = torch.tensor(prompt_tokens, dtype=torch.long)[None]
else:
gen_in = prompt_tokens
device = self.get_auxilary_device()
gen_in = gen_in.to(device)
additional_bad_words_ids = [self.tokenizer.encode("\n")] if single_line else []
if seed is not None:
torch.manual_seed(seed)
with torch.no_grad():
start_time = time.time()
genout = self.model.generate(
gen_in,
do_sample=True,
max_length=min(
len(prompt_tokens) + max_new, utils.koboldai_vars.max_length
),
repetition_penalty=1.0,
bad_words_ids=self.badwordsids
+ additional_bad_words_ids,
use_cache=True,
num_return_sequences=batch_count,
)
logger.debug(
"torch_raw_generate: run generator {}s".format(time.time() - start_time)
)
return GenerationResult(
self,
out_batches=genout,
prompt=prompt_tokens,
is_whole_generation=False,
output_includes_prompt=True,
)
def _get_model(self, location: str, tf_kwargs: Dict):
tf_kwargs["revision"] = utils.koboldai_vars.revision
tf_kwargs["cache_dir"] = "cache"
# If we have model hints for legacy model, use them rather than fall back.
try:
if self.model_name == "GPT2Custom":
return GPT2LMHeadModel.from_pretrained(location, **tf_kwargs)
elif self.model_name == "NeoCustom":
return GPTNeoForCausalLM.from_pretrained(location, **tf_kwargs)
except Exception as e:
logger.warning(f"{self.model_name} is a no-go; {e} - Falling back to auto.")
# Try to determine model type from either AutoModel or falling back to legacy
try:
return AutoModelForCausalLM.from_pretrained(location, **tf_kwargs)
except Exception as e:
traceback_string = traceback.format_exc().lower()
if "out of memory" in traceback_string:
raise RuntimeError(
"One of your GPUs ran out of memory when KoboldAI tried to load your model."
)
# Model corrupted or serious loading problem. Stop here.
if "invalid load key" in traceback_string:
logger.error("Invalid load key! Aborting.")
raise
logger.warning(f"Fell back to GPT2LMHeadModel due to {e}")
logger.debug(traceback.format_exc())
try:
return GPT2LMHeadModel.from_pretrained(location, **tf_kwargs)
except Exception as e:
logger.warning(f"Fell back to GPTNeoForCausalLM due to {e}")
logger.debug(traceback.format_exc())
return GPTNeoForCausalLM.from_pretrained(location, **tf_kwargs)
def get_hidden_size(self) -> int:
return self.model.get_input_embeddings().embedding_dim
def _will_load_with_safetensors(self) -> bool:
path = self.get_local_model_path()
# TODO: This might mess up download to run
if not path:
return False
if not os.path.exists(os.path.join(path, "model.safetensors")):
return False
return True
def _move_to_devices(self) -> None:
for key, value in self.model.state_dict().items():
target_dtype = (
torch.float32 if breakmodel.primary_device == "cpu" else torch.float16
)
if value.dtype is not target_dtype:
accelerate.utils.set_module_tensor_to_device(
self.model,
tensor_name=key,
device=torch.device(value.device),
value=value,
dtype=target_dtype,
)
disk_blocks = breakmodel.disk_blocks
gpu_blocks = breakmodel.gpu_blocks
ram_blocks = len(utils.layers_module_names) - sum(gpu_blocks)
cumulative_gpu_blocks = tuple(itertools.accumulate(gpu_blocks))
device_map = {}
for name in utils.layers_module_names:
layer = int(name.rsplit(".", 1)[1])
device = (
("disk" if layer < disk_blocks else "cpu")
if layer < ram_blocks
else bisect.bisect_right(cumulative_gpu_blocks, layer - ram_blocks)
)
device_map[name] = device
for name in utils.get_missing_module_names(self.model, list(device_map.keys())):
device_map[name] = breakmodel.primary_device
breakmodel.dispatch_model_ex(
self.model,
device_map,
main_device=breakmodel.primary_device,
offload_buffers=True,
offload_dir="accelerate-disk-cache",
)
gc.collect()
return
# Function to patch transformers to use our soft prompt
def patch_embedding(self) -> None:
if getattr(Embedding, "_koboldai_patch_causallm_model", None):
Embedding._koboldai_patch_causallm_model = self.model
return
old_embedding_call = Embedding.__call__
kai_model = self
def new_embedding_call(self, input_ids, *args, **kwargs):
# Don't touch embeddings for models other than the core inference model (that's us!)
if (
Embedding._koboldai_patch_causallm_model.get_input_embeddings()
is not self
):
return old_embedding_call(self, input_ids, *args, **kwargs)
assert input_ids is not None
if utils.koboldai_vars.sp is not None:
shifted_input_ids = input_ids - kai_model.model.config.vocab_size
input_ids.clamp_(max=kai_model.model.config.vocab_size - 1)
inputs_embeds = old_embedding_call(self, input_ids, *args, **kwargs)
if utils.koboldai_vars.sp is not None:
utils.koboldai_vars.sp = utils.koboldai_vars.sp.to(
inputs_embeds.dtype
).to(inputs_embeds.device)
inputs_embeds = torch.where(
(shifted_input_ids >= 0)[..., None],
utils.koboldai_vars.sp[shifted_input_ids.clamp(min=0)],
inputs_embeds,
)
return inputs_embeds
Embedding.__call__ = new_embedding_call
Embedding._koboldai_patch_causallm_model = self.model
def _get_lazy_load_callback(self, n_layers: int, convert_to_float16: bool = True):
if not self.lazy_load:
return
disk_blocks = breakmodel.disk_blocks
gpu_blocks = breakmodel.gpu_blocks
ram_blocks = ram_blocks = n_layers - sum(gpu_blocks)
cumulative_gpu_blocks = tuple(itertools.accumulate(gpu_blocks))
def lazy_load_callback(
model_dict: Dict[str, Union[lazy_loader.LazyTensor, torch.Tensor]],
f,
is_safetensors: bool = False,
**_,
):
if lazy_load_callback.nested:
return
lazy_load_callback.nested = True
device_map: Dict[str, Union[str, int]] = {}
@functools.lru_cache(maxsize=None)
def get_original_key(key) -> Optional[str]:
key_candidates = [
original_key
for original_key in utils.module_names
if original_key.endswith(key)
]
if not key_candidates:
logger.debug(f"!!! No key candidates for {key}")
return None
return max(key_candidates, key=len)
for key, value in model_dict.items():
original_key = get_original_key(key)
if not original_key:
continue
if isinstance(value, lazy_loader.LazyTensor) and not any(
original_key.startswith(n) for n in utils.layers_module_names
):
device_map[key] = (
utils.koboldai_vars.gpu_device
if utils.koboldai_vars.hascuda and self.usegpu
else "cpu"
if not utils.koboldai_vars.hascuda
or not self.breakmodel
else breakmodel.primary_device
)
else:
layer = int(
max(
(
n
for n in utils.layers_module_names
if original_key.startswith(n)
),
key=len,
).rsplit(".", 1)[1]
)
device = (
utils.koboldai_vars.gpu_device
if utils.koboldai_vars.hascuda and self.usegpu
else "disk"
if layer < disk_blocks and layer < ram_blocks
else "cpu"
if not utils.koboldai_vars.hascuda
or not self.breakmodel
else "shared"
if layer < ram_blocks
else bisect.bisect_right(
cumulative_gpu_blocks, layer - ram_blocks
)
)
device_map[key] = device
if utils.num_shards is None or utils.current_shard == 0:
utils.offload_index = {}
if os.path.isdir("accelerate-disk-cache"):
# Delete all of the files in the disk cache folder without deleting the folder itself to allow people to create symbolic links for this folder
# (the folder doesn't contain any subfolders so os.remove will do just fine)
for filename in os.listdir("accelerate-disk-cache"):
try:
os.remove(os.path.join("accelerate-disk-cache", filename))
except OSError:
pass
os.makedirs("accelerate-disk-cache", exist_ok=True)
if utils.num_shards is not None:
num_tensors = len(
utils.get_sharded_checkpoint_num_tensors(
utils.from_pretrained_model_name,
utils.from_pretrained_index_filename,
is_safetensors=is_safetensors,
**utils.from_pretrained_kwargs,
)
)
else:
num_tensors = len(device_map)
print(flush=True)
utils.koboldai_vars.status_message = "Loading model"
utils.koboldai_vars.total_layers = num_tensors
utils.koboldai_vars.loaded_layers = 0
utils.bar = tqdm(
total=num_tensors,
desc="Loading model tensors",
file=utils.UIProgressBarFile(),
position=1
)
if not is_safetensors:
# Torch lazyload
with zipfile.ZipFile(f, "r") as z:
try:
last_storage_key = None
zipfolder = os.path.basename(os.path.normpath(f)).split(".")[0]
f = None
current_offset = 0
able_to_pin_layers = True
if utils.num_shards is not None:
utils.current_shard += 1
for key in sorted(
device_map.keys(),
key=lambda k: (
model_dict[k].key,
model_dict[k].seek_offset,
),
):
storage_key = model_dict[key].key
if (
storage_key != last_storage_key
or model_dict[key].seek_offset < current_offset
):
last_storage_key = storage_key
if isinstance(f, zipfile.ZipExtFile):
f.close()
ziproot = z.namelist()[0].split("/")[0]
f = z.open(f"{ziproot}/data/{storage_key}")
current_offset = 0
if current_offset != model_dict[key].seek_offset:
f.read(model_dict[key].seek_offset - current_offset)
current_offset = model_dict[key].seek_offset
device = device_map[key]
size = functools.reduce(
lambda x, y: x * y, model_dict[key].shape, 1
)
dtype = model_dict[key].dtype
nbytes = (
size
if dtype is torch.bool
else size
* (
(
torch.finfo
if dtype.is_floating_point
else torch.iinfo
)(dtype).bits
>> 3
)
)
# print(f"Transferring <{key}> to {f'({device.upper()})' if isinstance(device, str) else '[device ' + str(device) + ']'} ... ", end="", flush=True)
#logger.debug(f"Transferring <{key}> to {f'({device.upper()})' if isinstance(device, str) else '[device ' + str(device) + ']'} ... ")
model_dict[key] = model_dict[key].materialize(
f, map_location="cpu"
)
if model_dict[key].dtype is torch.float32:
utils.koboldai_vars.fp32_model = True
if (
convert_to_float16
and breakmodel.primary_device != "cpu"
and utils.koboldai_vars.hascuda
and (
self.breakmodel
or self.usegpu
)
and model_dict[key].dtype is torch.float32
):
model_dict[key] = model_dict[key].to(torch.float16)
if breakmodel.primary_device == "cpu" or (
not self.usegpu
and not self.breakmodel
and model_dict[key].dtype is torch.float16
):
model_dict[key] = model_dict[key].to(torch.float32)
if device == "shared":
model_dict[key] = model_dict[key].to("cpu").detach_()
if able_to_pin_layers:
try:
model_dict[key] = model_dict[key].pin_memory()
except:
able_to_pin_layers = False
elif device == "disk":
accelerate.utils.offload_weight(
model_dict[key],
get_original_key(key),
"accelerate-disk-cache",
index=utils.offload_index,
)
model_dict[key] = model_dict[key].to("meta")
else:
model_dict[key] = model_dict[key].to(device)
# print("OK", flush=True)
current_offset += nbytes
utils.bar.update(1)
utils.koboldai_vars.loaded_layers += 1
finally:
if (
utils.num_shards is None
or utils.current_shard >= utils.num_shards
):
if utils.offload_index:
for name, tensor in utils.named_buffers:
dtype = tensor.dtype
if (
convert_to_float16
and breakmodel.primary_device != "cpu"
and utils.koboldai_vars.hascuda
and (
self.breakmodel
or self.usegpu
)
):
dtype = torch.float16
if breakmodel.primary_device == "cpu" or (
not self.usegpu
and not self.breakmodel
):
dtype = torch.float32
if (
name in model_dict
and model_dict[name].dtype is not dtype
):
model_dict[name] = model_dict[name].to(dtype)
if tensor.dtype is not dtype:
tensor = tensor.to(dtype)
if name not in utils.offload_index:
accelerate.utils.offload_weight(
tensor,
name,
"accelerate-disk-cache",
index=utils.offload_index,
)
accelerate.utils.save_offload_index(
utils.offload_index, "accelerate-disk-cache"
)
utils.bar.close()
utils.bar = None
utils.koboldai_vars.status_message = ""
lazy_load_callback.nested = False
if isinstance(f, zipfile.ZipExtFile):
f.close()
else:
# Loading with safetensors
try:
able_to_pin_layers = True
if utils.num_shards is not None:
utils.current_shard += 1
for key in sorted(
device_map.keys(),
key=lambda k: model_dict[k].key,
):
storage_key = model_dict[key].key
device = device_map[key]
# print(f"Transferring <{key}> to {f'({device.upper()})' if isinstance(device, str) else '[device ' + str(device) + ']'} ... ", end="", flush=True)
model_dict[key] = model_dict[key].materialize(
f, map_location="cpu"
)
if model_dict[key].dtype is torch.float32:
utils.koboldai_vars.fp32_model = True
if (
convert_to_float16
and breakmodel.primary_device != "cpu"
and utils.koboldai_vars.hascuda
and (
self.breakmodel
or self.usegpu
)
and model_dict[key].dtype is torch.float32
):
model_dict[key] = model_dict[key].to(torch.float16)
if breakmodel.primary_device == "cpu" or (
not self.usegpu
and not self.breakmodel
and model_dict[key].dtype is torch.float16
):
model_dict[key] = model_dict[key].to(torch.float32)
if device == "shared":
model_dict[key] = model_dict[key].to("cpu").detach_()
if able_to_pin_layers:
try:
model_dict[key] = model_dict[key].pin_memory()
except:
able_to_pin_layers = False
elif device == "disk":
accelerate.utils.offload_weight(
model_dict[key],
get_original_key(key),
"accelerate-disk-cache",
index=utils.offload_index,
)
model_dict[key] = model_dict[key].to("meta")
else:
model_dict[key] = model_dict[key].to(device)
utils.bar.update(1)
utils.koboldai_vars.loaded_layers += 1
finally:
if (
utils.num_shards is None
or utils.current_shard >= utils.num_shards
):
if utils.offload_index:
for name, tensor in utils.named_buffers:
dtype = tensor.dtype
if (
convert_to_float16
and breakmodel.primary_device != "cpu"
and utils.koboldai_vars.hascuda
and (
self.breakmodel
or self.usegpu
)
):
dtype = torch.float16
if breakmodel.primary_device == "cpu" or (
not self.usegpu
and not self.breakmodel
):
dtype = torch.float32
if (
name in model_dict
and model_dict[name].dtype is not dtype
):
model_dict[name] = model_dict[name].to(dtype)
if tensor.dtype is not dtype:
tensor = tensor.to(dtype)
if name not in utils.offload_index:
accelerate.utils.offload_weight(
tensor,
name,
"accelerate-disk-cache",
index=utils.offload_index,
)
accelerate.utils.save_offload_index(
utils.offload_index, "accelerate-disk-cache"
)
utils.bar.close()
utils.bar = None
utils.koboldai_vars.status_message = ""
lazy_load_callback.nested = False
lazy_load_callback.nested = False
return lazy_load_callback
@contextlib.contextmanager
def _maybe_use_float16(self, always_use: bool = False):
if always_use or (
utils.koboldai_vars.hascuda
and self.low_mem
and (self.usegpu or self.breakmodel)
):
original_dtype = torch.get_default_dtype()
torch.set_default_dtype(torch.float16)
yield True
torch.set_default_dtype(original_dtype)
else:
yield False
def breakmodel_device_list(self, n_layers, primary=None, selected=None):
# TODO: Find a better place for this or rework this
device_count = torch.cuda.device_count()
if device_count < 2:
primary = None
logger.debug("n_layers: {}".format(n_layers))
logger.debug("gpu blocks: {}".format(breakmodel.gpu_blocks))
gpu_blocks = breakmodel.gpu_blocks + (
device_count - len(breakmodel.gpu_blocks)
) * [0]
print(f"{Colors.YELLOW} DEVICE ID | LAYERS | DEVICE NAME{Colors.END}")
for i in range(device_count):
name = torch.cuda.get_device_name(i)
if len(name) > 47:
name = "..." + name[-44:]
row_color = Colors.END
sep_color = Colors.YELLOW
print(
f"{row_color}{Colors.YELLOW + '->' + row_color if i == selected else ' '} {'(primary)' if i == primary else ' '*9} {i:3} {sep_color}|{row_color} {gpu_blocks[i]:3} {sep_color}|{row_color} {name}{Colors.END}"
)
row_color = Colors.END
sep_color = Colors.YELLOW
print(
f"{row_color}{Colors.YELLOW + '->' + row_color if -1 == selected else ' '} {' '*9} N/A {sep_color}|{row_color} {breakmodel.disk_blocks:3} {sep_color}|{row_color} (Disk cache){Colors.END}"
)
print(
f"{row_color} {' '*9} N/A {sep_color}|{row_color} {n_layers:3} {sep_color}|{row_color} (CPU){Colors.END}"
)
def breakmodel_device_config(self, config):
# TODO: Find a better place for this or rework this
global breakmodel, generator
import breakmodel
n_layers = utils.num_layers(config)
logger.debug("gpu blocks before modification: {}".format(breakmodel.gpu_blocks))
if utils.args.cpu:
breakmodel.gpu_blocks = [0] * n_layers
return
elif breakmodel.gpu_blocks == []:
logger.info("Breakmodel not specified, assuming GPU 0")
breakmodel.gpu_blocks = [n_layers]
n_layers = 0
else:
s = n_layers
for i in range(len(breakmodel.gpu_blocks)):
if breakmodel.gpu_blocks[i] <= -1:
breakmodel.gpu_blocks[i] = s
break
else:
s -= breakmodel.gpu_blocks[i]
assert sum(breakmodel.gpu_blocks) <= n_layers
n_layers -= sum(breakmodel.gpu_blocks)
if breakmodel.disk_blocks is not None:
assert breakmodel.disk_blocks <= n_layers
n_layers -= breakmodel.disk_blocks
logger.init_ok("Final device configuration:", status="Info")
self.breakmodel_device_list(n_layers, primary=breakmodel.primary_device)
with open("settings/{}.breakmodel".format(self.model_name.replace("/", "_")), "w") as file:
file.write("{}\n{}".format(",".join(map(str, breakmodel.gpu_blocks)), breakmodel.disk_blocks))
# If all layers are on the same device, use the old GPU generation mode
while len(breakmodel.gpu_blocks) and breakmodel.gpu_blocks[-1] == 0:
breakmodel.gpu_blocks.pop()
self.breakmodel = True
if len(breakmodel.gpu_blocks) and breakmodel.gpu_blocks[-1] in (
-1,
utils.num_layers(config),
):
logger.debug("All layers on same GPU. Breakmodel disabled")
self.breakmodel = False
self.usegpu = True
utils.koboldai_vars.gpu_device = len(breakmodel.gpu_blocks) - 1
return
if not breakmodel.gpu_blocks:
logger.warning("Nothing assigned to a GPU, reverting to CPU only mode")
import breakmodel
breakmodel.primary_device = "cpu"
self.breakmodel = False
self.usegpu = False
return
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