AmosLewis/gpt2linalg.py

## gpt2linalg.py
from transformers import AutoTokenizer, AutoModelForCausalLM
import torch

from torch.fx.experimental.proxy_tensor import make_fx
from torch._decomp import get_decompositions
import tempfile
import torch_mlir

def prepare_sentence_tokens(hf_model: str, sentence: str):
    tokenizer = AutoTokenizer.from_pretrained(hf_model)
    return torch.tensor([tokenizer.encode(sentence)])


class HfMaskedLM(torch.nn.Module):

    def __init__(self, model_name: str):
        super().__init__()
        self.model = AutoModelForCausalLM.from_pretrained(
            model_name,  # The pretrained model name.
            # The number of output labels--2 for binary classification.
            num_labels=2,
            # Whether the model returns attentions weights.
            output_attentions=False,
            # Whether the model returns all hidden-states.
            output_hidden_states=False,
            torchscript=True,
        )
        self.model.eval()

    def forward(self, tokens):
        return self.model.forward(tokens)[0]


hf_minilm_model = "gpt2"

test_input = prepare_sentence_tokens(hf_minilm_model,
                                     "this project is very interesting")

model = HfMaskedLM(hf_minilm_model)

print(model(test_input))

fx_g = make_fx(
    model,
    decomposition_table=get_decompositions(
        [
            torch.ops.aten.embedding_dense_backward,
            torch.ops.aten.native_layer_norm_backward,
            torch.ops.aten.slice_backward,
            torch.ops.aten.select_backward,
            torch.ops.aten.norm.ScalarOpt_dim,
            torch.ops.aten.native_group_norm,
            torch.ops.aten.upsample_bilinear2d.vec,
            torch.ops.aten.split.Tensor,
            torch.ops.aten.split_with_sizes,
        ]
    ),
)(test_input)

# print(fx_g.graph)

fx_g.graph.set_codegen(torch.fx.graph.CodeGen())
fx_g.recompile()

def strip_overloads(gm):
    """
    Modifies the target of graph nodes in :attr:`gm` to strip overloads.
    Args:
        gm(fx.GraphModule): The input Fx graph module to be modified
    """
    for node in gm.graph.nodes:
        if isinstance(node.target, torch._ops.OpOverload):
            node.target = node.target.overloadpacket
    gm.recompile()

strip_overloads(fx_g)

ts_g = torch.jit.script(fx_g)

module = torch_mlir.compile(
    ts_g,
    (test_input),
    torch_mlir.OutputType.LINALG_ON_TENSORS,
    use_tracing=True,
    verbose=False,
)

# module = torch_mlir.compile(
#     ts_g,
#     (test_input),
#     torch_mlir.OutputType.TOSA,
#     use_tracing=True,
#     verbose=False,
# )
# module.dump()


from shark.shark_inference import SharkInference
mlir_model = module
func_name = "forward"

shark_module = SharkInference(
    mlir_model, func_name, device="cpu", mlir_dialect="linalg"
)
shark_module.compile()

def shark_result(x):
    x_ny = x.detach().numpy()
    inputs = (x_ny,)
    result = shark_module.forward(inputs)
    return torch.from_numpy(result)

observed_out = shark_result(test_input)
print(observed_out)
	from transformers import AutoTokenizer, AutoModelForCausalLM
	import torch

	from torch.fx.experimental.proxy_tensor import make_fx
	from torch._decomp import get_decompositions
	import tempfile
	import torch_mlir

	def prepare_sentence_tokens(hf_model: str, sentence: str):
	tokenizer = AutoTokenizer.from_pretrained(hf_model)
	return torch.tensor([tokenizer.encode(sentence)])


	class HfMaskedLM(torch.nn.Module):

	def __init__(self, model_name: str):
	super().__init__()
	self.model = AutoModelForCausalLM.from_pretrained(
	model_name, # The pretrained model name.
	# The number of output labels--2 for binary classification.
	num_labels=2,
	# Whether the model returns attentions weights.
	output_attentions=False,
	# Whether the model returns all hidden-states.
	output_hidden_states=False,
	torchscript=True,
	)
	self.model.eval()

	def forward(self, tokens):
	return self.model.forward(tokens)[0]



	hf_minilm_model = "gpt2"

	test_input = prepare_sentence_tokens(hf_minilm_model,
	"this project is very interesting")

	model = HfMaskedLM(hf_minilm_model)

	print(model(test_input))

	fx_g = make_fx(
	model,
	decomposition_table=get_decompositions(
	[
	torch.ops.aten.embedding_dense_backward,
	torch.ops.aten.native_layer_norm_backward,
	torch.ops.aten.slice_backward,
	torch.ops.aten.select_backward,
	torch.ops.aten.norm.ScalarOpt_dim,
	torch.ops.aten.native_group_norm,
	torch.ops.aten.upsample_bilinear2d.vec,
	torch.ops.aten.split.Tensor,
	torch.ops.aten.split_with_sizes,
	]
	),
	)(test_input)

	# print(fx_g.graph)

	fx_g.graph.set_codegen(torch.fx.graph.CodeGen())
	fx_g.recompile()

	def strip_overloads(gm):
	"""
	Modifies the target of graph nodes in :attr:`gm` to strip overloads.
	Args:
	gm(fx.GraphModule): The input Fx graph module to be modified
	"""
	for node in gm.graph.nodes:
	if isinstance(node.target, torch._ops.OpOverload):
	node.target = node.target.overloadpacket
	gm.recompile()

	strip_overloads(fx_g)

	ts_g = torch.jit.script(fx_g)

	module = torch_mlir.compile(
	ts_g,
	(test_input),
	torch_mlir.OutputType.LINALG_ON_TENSORS,
	use_tracing=True,
	verbose=False,
	)

	# module = torch_mlir.compile(
	# ts_g,
	# (test_input),
	# torch_mlir.OutputType.TOSA,
	# use_tracing=True,
	# verbose=False,
	# )
	# module.dump()


	from shark.shark_inference import SharkInference
	mlir_model = module
	func_name = "forward"

	shark_module = SharkInference(
	mlir_model, func_name, device="cpu", mlir_dialect="linalg"
	)
	shark_module.compile()

	def shark_result(x):
	x_ny = x.detach().numpy()
	inputs = (x_ny,)
	result = shark_module.forward(inputs)
	return torch.from_numpy(result)

	observed_out = shark_result(test_input)
	print(observed_out)