forked from jiuyuan/InfiniTensor
[feature] support kvcache with static graph
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6a1bfd6c45
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@ -0,0 +1,146 @@
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import os
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from pyinfinitensor.onnx import OnnxStub, backend
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import numpy as np
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import onnx
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import torch
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from transformers import LlamaModel, LlamaForCausalLM
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from tqdm import tqdm
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import onnx_graphsurgeon as gs
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from onnxsim import simplify
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import argparse
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parser = argparse.ArgumentParser(description='')
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parser.add_argument('--batchsize', dest='batchsize', type=int, default=1)
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parser.add_argument('--layer', dest='n_layers', type=int, default=2)
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parser.add_argument('--iter', dest='n_iter', type=int, default=1)
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parser.add_argument('--n_max_length', dest='n_max_length', type=int, default=1024)
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parser.add_argument('--pretrained_llama_path', dest='pretrained_llama_path', type=str,
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default="/data0/shared/data/public/opensource_models/meta-llama/Llama-2-7b-hf/")
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parser.add_argument('--onnx_model_path', dest='onnx_model_path', type=str,
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default="/data1/shared/llama")
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args = parser.parse_args()
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ONNX_MODEL_PATH = "{}/llama_bs{}_layer{}.onnx".format(args.onnx_model_path, args.batchsize, args.n_layers)
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ONNX_WEIGHT_PATH = "./llama_bs{}_layer{}.pb".format(args.batchsize, args.n_layers)
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def export_onnx(model: LlamaModel, ONNX_MODEL_PATH):
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param = torch.zeros(
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(args.batchsize, 1024), dtype=torch.long)
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logits = model(param, past_key_values=None)
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param_kvcache = torch.zeros((args.batchsize, 1), dtype=torch.long)
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torch.onnx.export(model, (param_kvcache, {"past_key_values": logits.past_key_values,
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"position_ids": param_kvcache}), ONNX_MODEL_PATH, verbose=False,
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do_constant_folding=True,)
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onnx_model = onnx.load(ONNX_MODEL_PATH)
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print("simplifing onnx model")
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onnx_model, check = simplify(onnx_model, skipped_optimizers=[
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'eliminate_duplicate_initializer'])
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assert check
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onnx.save(onnx_model, ONNX_MODEL_PATH, save_as_external_data=True, location=ONNX_WEIGHT_PATH)
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print("simlifing finished.")
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@gs.Graph.register()
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def replace_with_attention(self, inputs, outputs, inputs_added, outputs_removed):
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for inp in inputs:
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inp.outputs.clear()
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for out in outputs:
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out.inputs.clear()
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for inp in inputs_added:
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inputs.append(inp)
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for out in outputs_removed:
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out.inputs.clear()
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return self.layer(op="AttentionKVCache", inputs=inputs, outputs=outputs)
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def replace_onnx_with_attention_op():
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graph = gs.import_onnx(
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onnx.load(ONNX_MODEL_PATH))
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tmap = graph.tensors()
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for i in range(args.n_layers):
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inputs = [
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tmap["onnx::Concat_" + str((i+1)*2)],
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tmap["onnx::Concat_" + str((i+1)*2+1)],
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tmap["/model/layers." + str(i) + "/self_attn/Add_output_0"],
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tmap["/model/layers." + str(i) + "/self_attn/Add_1_output_0"],
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tmap["/model/layers." + str(i) + "/self_attn/Transpose_2_output_0"]]
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outputs = [
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tmap["/model/layers." + str(i) + "/self_attn/MatMul_1_output_0"],
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tmap[graph.outputs[1+i*2].name],
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tmap[graph.outputs[2+i*2].name]]
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inputs_added = [graph.inputs[1]]
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outputs_removed = []
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graph.replace_with_attention(
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inputs, outputs, inputs_added, outputs_removed)
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graph.cleanup(True).toposort()
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onnx.save(gs.export_onnx(graph), ONNX_MODEL_PATH, save_as_external_data=True)
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if __name__ == "__main__":
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kvcache_torch = None
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torch_model = LlamaForCausalLM.from_pretrained(
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args.pretrained_llama_path, num_hidden_layers=int(args.n_layers)).eval()
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n_heads = torch_model.config.num_attention_heads
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n_dims = torch_model.config.hidden_size // n_heads
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if not os.path.exists(ONNX_MODEL_PATH):
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print("exporting onnx graph")
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export_onnx(torch_model, ONNX_MODEL_PATH)
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replace_onnx_with_attention_op()
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else:
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print("will use exsiting onnx graph")
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onnx_model = onnx.load(ONNX_MODEL_PATH)
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stub = OnnxStub(onnx_model, backend.cuda_runtime())
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count_wrong = 0
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for i in tqdm(range(0, args.n_max_length)):
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query = np.random.randint(
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torch_model.config.vocab_size, size=(args.batchsize, 1), dtype=np.int32)
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position_id = i*np.ones((args.batchsize, 1), dtype=np.int32)
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####################################
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# pytorch
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####################################
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outputs_torch = torch_model(
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torch.tensor(query), past_key_values=kvcache_torch)
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logit_torch = outputs_torch['logits']
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kvcache_torch = outputs_torch['past_key_values']
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####################################
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# infinitensor
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####################################
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# copyin input
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(list(stub.inputs.items()))[0][1].copyin_int64(
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query.reshape(-1).tolist())
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(list(stub.inputs.items()))[1][1].copyin_int64(
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position_id.reshape(-1).tolist())
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stub.run()
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####################################
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# validation
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####################################
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# copyout output
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logits_it = np.array((list(stub.outputs.items()))
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[0][1].copyout_float())
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try:
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np.testing.assert_allclose(
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logit_torch[:, -1, :].detach().cpu().numpy().flatten(), logits_it, rtol=1e-3, atol=1e-3)
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except Exception as e:
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try:
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np.testing.assert_allclose(
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np.argmax(logit_torch[:, -1, :].detach().cpu().numpy().flatten()), np.argmax(logits_it), rtol=1e-3, atol=1e-3)
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except:
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count_wrong = count_wrong + 1
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result = "{}/{} failed.".format(count_wrong, args.n_max_length)
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print(result)
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del stub
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@ -74,9 +74,10 @@ class GraphHandlerObj {
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Tensor squeeze(Tensor input, Tensor output, Shape axes);
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Tensor unsqueeze(Tensor input, Tensor output, Shape axes);
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Tensor concat(TensorVec inputs, Tensor output, int dim);
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Tensor attentionKVCache(Tensor input_k_cache, Tensor input_v_cache,
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TensorVec attentionKVCache(Tensor input_k_cache, Tensor input_v_cache,
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Tensor input_q, Tensor input_k, Tensor input_v,
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Tensor position_id, Tensor output_matmul);
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Tensor position_id, Tensor output_matmul,
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Tensor output_k_cache, Tensor output_v_cache);
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TensorVec split(Tensor input, std::optional<TensorVec> outputs, int axis,
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std::variant<int, vector<int>> numOrRatio);
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Tensor gather(Tensor data, Tensor indices, Tensor output, int axis);
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@ -10,6 +10,7 @@ namespace infini {
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void attention_kvcache_kernel(float *input_k_cache, float *input_v_cache,
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float *input_q, float *input_k, float *input_v,
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int *position_id, float *output_matmul,
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const AttentionKVCacheMetadata &compMeta);
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const AttentionKVCacheMetadata &compMeta,
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float *output_O_temp, float *output_sum_temp);
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} // namespace infini
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@ -22,18 +22,21 @@ class AttentionKVCacheObj : public OperatorObj {
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* @param input_v The value input tensor.
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* @param position_id The positon id of the query,
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* @param output_matmul The query output tensor.
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* @param output_k_cache The output k_cache tensor.
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* @param output_v_cache The output v_cache tensor.
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*/
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AttentionKVCacheObj(GraphObj *graph, Tensor input_k_cache,
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Tensor input_v_cache, Tensor input_q, Tensor input_k,
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Tensor input_v, Tensor position_id,
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Tensor output_matmul);
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Tensor output_matmul, Tensor output_k_cache,
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Tensor output_v_cache);
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OP_CLONE(AttentionKVCacheObj);
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optional<vector<Shape>> inferShape(const TensorVec &inputs) override;
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std::string toString() const override;
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int numInputs() const override { return 6; }
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int numOutputs() const override { return 1; }
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int numOutputs() const override { return 3; }
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int getDim() const { return dim; }
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private:
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@ -660,7 +660,7 @@ class OnnxStub:
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next((attr.i for attr in node.attribute if attr.name == "axis")),
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)
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elif node.op_type == "AttentionKVCache":
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tensors[node.output[0]] = self.handler.attentionKVCache(
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tensors[node.output[0]], tensors[node.output[1]], tensors[node.output[2]] = self.handler.attentionKVCache(
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tensors[node.input[0]],
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tensors[node.input[1]],
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tensors[node.input[2]],
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@ -668,6 +668,8 @@ class OnnxStub:
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tensors[node.input[4]],
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tensors[node.input[5]],
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tensors.get(node.output[0]),
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tensors.get(node.output[1]),
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tensors.get(node.output[2]),
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)
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elif node.op_type == "Split":
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split = (
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@ -324,24 +324,25 @@ Tensor GraphHandlerObj::concat(TensorVec inputs, Tensor output, int dim) {
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}
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}
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Tensor GraphHandlerObj::attentionKVCache(Tensor input_k_cache,
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Tensor input_v_cache, Tensor input_q,
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Tensor input_k, Tensor input_v,
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Tensor position_id,
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Tensor output_matmul) {
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if (output_matmul) {
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TensorVec GraphHandlerObj::attentionKVCache(
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Tensor input_k_cache, Tensor input_v_cache, Tensor input_q, Tensor input_k,
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Tensor input_v, Tensor position_id, Tensor output_matmul,
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Tensor output_k_cache, Tensor output_v_cache) {
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if (output_matmul && output_k_cache && output_v_cache) {
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g->addOpWithOutputs<AttentionKVCacheObj>(
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std::move(input_k_cache), std::move(input_v_cache),
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std::move(input_q), std::move(input_k), std::move(input_v),
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std::move(position_id), output_matmul);
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return {output_matmul};
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std::move(position_id), output_matmul, output_k_cache,
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output_v_cache);
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return {output_matmul, output_k_cache, output_v_cache};
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} else {
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return g
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->addOp<AttentionKVCacheObj>(
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std::move(input_k_cache), std::move(input_v_cache),
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std::move(input_q), std::move(input_k), std::move(input_v),
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std::move(position_id), output_matmul)
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->getOutput();
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std::move(position_id), output_matmul, output_k_cache,
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output_v_cache)
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->getOutputs();
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}
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}
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@ -67,8 +67,10 @@ bool OperatorObj::checkValid(GraphObj *graph) {
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if (graph) { // if graph != nullptr, outputs should be created
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auto dataTypes = inferDataType();
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for (size_t i = 0; i < outputs.size(); i++) {
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IT_ASSERT(!outputs[i], "Find empty output while operator creation");
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if (!outputs[i])
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outputs[i] = graph->addTensor(shapes[i], dataTypes[i]);
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else if (shapes[i] != outputs[i]->getDims())
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return false;
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}
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} else { // if outputs have been created, check their shapes
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for (size_t i = 0; i < shapes.size(); ++i) {
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@ -21,7 +21,8 @@ class AttentionKVCacheCompute {
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public:
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void do_compute(Tensor input_k_cache, Tensor input_v_cache, Tensor input_q,
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Tensor input_k, Tensor input_v, Tensor position_id,
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Tensor output_matmul) const {
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Tensor output_matmul, Tensor output_temp_O,
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Tensor output_temp_sum) const {
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AttentionKVCacheMetadata metadata;
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initAttentionKVCacheMetadata(metadata, input_v_cache);
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@ -32,7 +33,9 @@ class AttentionKVCacheCompute {
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input_v->getRawDataPtr<float *>(),
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position_id->getRawDataPtr<int *>(),
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output_matmul->getRawDataPtr<float *>(),
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metadata);
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metadata,
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output_temp_O->getRawDataPtr<float *>(),
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output_temp_sum->getRawDataPtr<float *>());
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}
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};
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@ -41,10 +44,10 @@ class AttentionKVCacheCuda : private AttentionKVCacheCompute,
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void compute(const Operator &_op,
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const RuntimeObj *_context) const override {
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IT_ASSERT(_op->getDType() == DataType::Float32);
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do_compute(_op->getInputs()[0], _op->getInputs()[1],
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_op->getInputs()[2], _op->getInputs()[3],
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_op->getInputs()[4], _op->getInputs()[5],
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_op->getOutputs()[0]);
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do_compute(
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_op->getInputs()[0], _op->getInputs()[1], _op->getInputs()[2],
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_op->getInputs()[3], _op->getInputs()[4], _op->getInputs()[5],
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_op->getOutputs()[0], _op->getOutputs()[1], _op->getOutputs()[2]);
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}
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};
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@ -2,127 +2,168 @@
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#include "cuda/cuda_attention_kvcache.h"
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#define WARP_SIZE 32
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#define BLOCKSIZE WARP_SIZE
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#define SEQ_UNIT 64
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#define SEQ_UNIT 32
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__global__ void _attention_kvcache_kernel(float* input_k_cache,
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// ASSUME SEQ_LEN OF Q IS 1
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__global__ void _attention_kvcache_kernel_128_1(float* input_k_cache,
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float* input_v_cache,
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float* input_q,
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float* input_k,
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float* input_v,
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int* position_id,
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float* output_matmul,
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AttentionKVCacheMetadata compMeta) {
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AttentionKVCacheMetadata compMeta,
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float* output_O_temp,
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float* output_sum_temp) {
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int seq_length = position_id[0] + 1;
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int stride = (seq_length + SEQ_UNIT - 1) / SEQ_UNIT;
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if(blockIdx.y >= stride)
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return;
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int lane_id = threadIdx.x % WARP_SIZE;
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int group_id = threadIdx.x / WARP_SIZE;
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int parallel_idx = blockIdx.x * (blockDim.x / WARP_SIZE) + group_id;
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int idx_seq = blockIdx.y * SEQ_UNIT;
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if(parallel_idx >= compMeta.dimSize[0] * compMeta.dimSize[1])
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return;
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float ptr_V[SEQ_UNIT*2];
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float ptr_K[SEQ_UNIT*2];
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float ptr_Q[2];
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float ptr_P[SEQ_UNIT];
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float ptr_V[SEQ_UNIT*4]; // V
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float ptr_K[SEQ_UNIT*4]; // K
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float ptr_Q[4]; // Q
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float ptr_P[SEQ_UNIT] = {0};
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float ptr_O[2];
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float ptr_max[1];
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float ptr_sum[1];
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float ptr_O[4] = {0};
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float ptr_sum[1] = {0};
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float ptr_max_last[1];
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float ptr_sum_last[1];
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float ptr_O_last[2];
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(float2 &)ptr_Q[0] = (float2 &)input_q[(lane_id * 2) + (parallel_idx * 64)];
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int SEQ_LENGTH = position_id[0] + 1;
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int common_idx = (lane_id * 2) + (parallel_idx * compMeta.stride[1]);
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for (int idx_seq = 0; idx_seq < SEQ_LENGTH; idx_seq += SEQ_UNIT){
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ptr_max_last[0] = ptr_max[0];
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ptr_sum_last[0] = ptr_sum[0];
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(float2 &)ptr_O_last[0] = (float2 &)ptr_O[0];
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// readin Q
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(float4 &)ptr_Q[0] = (float4 &)input_q[(lane_id * 4) + (parallel_idx * 128)];
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int common_idx = (lane_id * 4) + (parallel_idx * compMeta.stride[1]);
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// Q*K
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#pragma unroll
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for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < SEQ_LENGTH; idx_SEQ_UNIT ++) {
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if(idx_SEQ_UNIT + idx_seq < SEQ_LENGTH - 1){
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(float2 &)ptr_K[idx_SEQ_UNIT * 2]
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= (float2 &) input_k_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])];
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for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < seq_length; idx_SEQ_UNIT ++) {
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if(idx_SEQ_UNIT + idx_seq < seq_length - 1){
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(float4 &)ptr_K[idx_SEQ_UNIT * 4]
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= (float4 &) input_k_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])];
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}
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else{
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(float2 &)ptr_K[idx_SEQ_UNIT * 2]
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= (float2 &) input_k[((lane_id * 2) + parallel_idx * compMeta.stride[2])];
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(float2 &)input_k_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])] =
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(float2 &)ptr_K[idx_SEQ_UNIT * 2];
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(float4 &)ptr_K[idx_SEQ_UNIT * 4]
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= (float4 &) input_k[((lane_id * 4) + parallel_idx * compMeta.stride[2])];
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(float4 &)input_k_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])] =
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(float4 &)ptr_K[idx_SEQ_UNIT * 4];
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}
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ptr_K[idx_SEQ_UNIT * 2] = ptr_Q[0] * ptr_K[idx_SEQ_UNIT * 2];
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ptr_K[idx_SEQ_UNIT * 2 + 1] = ptr_Q[1] * ptr_K[idx_SEQ_UNIT * 2 + 1];
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#pragma unroll
|
||||
for (int i = 0; i < 4; i ++){
|
||||
ptr_K[idx_SEQ_UNIT * 4 + i] = ptr_Q[i] * ptr_K[idx_SEQ_UNIT * 4 + i];
|
||||
#pragma unroll
|
||||
for (int offset = 16; offset > 0; offset /= 2) {
|
||||
ptr_K[idx_SEQ_UNIT * 2] += __shfl_down_sync(0xffffffff, ptr_K[idx_SEQ_UNIT * 2], offset);
|
||||
ptr_K[idx_SEQ_UNIT * 4 + i] += __shfl_down_sync(0xffffffff, ptr_K[idx_SEQ_UNIT * 4 + i], offset);
|
||||
}
|
||||
ptr_P[idx_SEQ_UNIT] = ptr_K[idx_SEQ_UNIT * 2];
|
||||
#pragma unroll
|
||||
for (int offset = 16; offset > 0; offset /= 2){
|
||||
ptr_K[((idx_SEQ_UNIT * 2) + 1)] += __shfl_down_sync(0xffffffff, ptr_K[((idx_SEQ_UNIT * 2) + 1)], offset);
|
||||
ptr_P[idx_SEQ_UNIT] += ptr_K[idx_SEQ_UNIT * 4 + i];
|
||||
}
|
||||
ptr_P[idx_SEQ_UNIT] += ptr_K[((idx_SEQ_UNIT * 2) + 1)];
|
||||
}
|
||||
|
||||
// div sqrt(d)
|
||||
#pragma unroll
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < SEQ_LENGTH; idx_SEQ_UNIT ++) {
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < seq_length; idx_SEQ_UNIT ++) {
|
||||
ptr_P[idx_SEQ_UNIT] = __shfl_sync(0xffffffff, ptr_P[idx_SEQ_UNIT], 0);
|
||||
ptr_P[idx_SEQ_UNIT] /= 8;
|
||||
ptr_max[0] = (idx_SEQ_UNIT == 0) ? ptr_P[0] : max(ptr_max[0], ptr_P[idx_SEQ_UNIT]);
|
||||
ptr_P[idx_SEQ_UNIT] /= sqrt(128.0);
|
||||
}
|
||||
ptr_max[0] = (idx_seq == 0) ? ptr_max[0] : max(ptr_max[0], ptr_max_last[0]);
|
||||
|
||||
ptr_sum[0] = 0;
|
||||
// softmax
|
||||
#pragma unroll
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < SEQ_LENGTH; idx_SEQ_UNIT ++) {
|
||||
ptr_P[idx_SEQ_UNIT] = expf(ptr_P[idx_SEQ_UNIT] - ptr_max[0]);
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < seq_length; idx_SEQ_UNIT ++) {
|
||||
ptr_P[idx_SEQ_UNIT] = expf(ptr_P[idx_SEQ_UNIT]);
|
||||
ptr_sum[0] += ptr_P[idx_SEQ_UNIT];
|
||||
}
|
||||
ptr_sum[0] = (idx_seq == 0) ? ptr_sum[0] : expf(ptr_max_last[0] - ptr_max[0]) * ptr_sum_last[0] + ptr_sum[0];
|
||||
|
||||
ptr_O[0] = 0;
|
||||
ptr_O[1] = 0;
|
||||
// * V
|
||||
#pragma unroll
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < SEQ_LENGTH; idx_SEQ_UNIT ++) {
|
||||
if(idx_SEQ_UNIT + idx_seq < SEQ_LENGTH - 1){
|
||||
(float2 &)ptr_V[idx_SEQ_UNIT * 2]
|
||||
= (float2 &) input_v_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])];
|
||||
for (int idx_SEQ_UNIT = 0; idx_SEQ_UNIT < SEQ_UNIT && idx_SEQ_UNIT + idx_seq < seq_length; idx_SEQ_UNIT ++) {
|
||||
if(idx_SEQ_UNIT + idx_seq < seq_length - 1){
|
||||
(float4 &)ptr_V[idx_SEQ_UNIT * 4]
|
||||
= (float4 &) input_v_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])];
|
||||
}
|
||||
else{
|
||||
(float2 &)ptr_V[idx_SEQ_UNIT * 2]
|
||||
= (float2 &) input_v[((lane_id * 2) + parallel_idx * compMeta.stride[2])];
|
||||
(float2 &)input_v_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])] =
|
||||
(float2 &)ptr_V[idx_SEQ_UNIT * 2];
|
||||
(float4 &)ptr_V[idx_SEQ_UNIT * 4]
|
||||
= (float4 &) input_v[((lane_id * 4) + parallel_idx * compMeta.stride[2])];
|
||||
(float4 &)input_v_cache[common_idx + ((idx_SEQ_UNIT + idx_seq) * compMeta.stride[2])]
|
||||
= (float4 &)ptr_V[idx_SEQ_UNIT * 4];
|
||||
}
|
||||
|
||||
ptr_P[idx_SEQ_UNIT] /= ptr_sum[0];
|
||||
#pragma unroll
|
||||
for (int i = 0; i < 4; i ++)
|
||||
ptr_O[i] = fmaf(ptr_P[idx_SEQ_UNIT], ptr_V[(idx_SEQ_UNIT * 4 + i)], ptr_O[i]);
|
||||
}
|
||||
|
||||
ptr_O[0] = fmaf(ptr_P[idx_SEQ_UNIT], ptr_V[(idx_SEQ_UNIT * 2)], ptr_O[0]);
|
||||
ptr_O[1] = fmaf(ptr_P[idx_SEQ_UNIT], ptr_V[(idx_SEQ_UNIT * 2) + 1], ptr_O[1]);
|
||||
#pragma unroll
|
||||
for (int i = 0; i < 4; i ++)
|
||||
ptr_O[i] /= ptr_sum[0];
|
||||
|
||||
(float4 &)output_O_temp[(lane_id * 4) + (blockIdx.y * compMeta.dimSize[3]) + (parallel_idx * compMeta.dimSize[3] * stride)] = (float4 &)ptr_O[0];
|
||||
if(threadIdx.x == 0){
|
||||
output_sum_temp[blockIdx.y + parallel_idx * stride] = ptr_sum[0];
|
||||
}
|
||||
ptr_O[0] = (idx_seq == 0) ? ptr_O[0] : ptr_O[0] + ptr_O_last[0] * expf(ptr_max_last[0] - ptr_max[0]) * ptr_sum_last[0] / ptr_sum[0];
|
||||
ptr_O[1] = (idx_seq == 0) ? ptr_O[1] : ptr_O[1] + ptr_O_last[1] * expf(ptr_max_last[0] - ptr_max[0]) * ptr_sum_last[0] / ptr_sum[0];
|
||||
}
|
||||
(float2 &)output_matmul[(lane_id * 2) + (parallel_idx * compMeta.dimSize[3])] = (float2 &)ptr_O[0];
|
||||
|
||||
}
|
||||
|
||||
__global__ void _attention_kvcache_kernel_128_2(int* position_id,
|
||||
float* output_matmul,
|
||||
AttentionKVCacheMetadata compMeta,
|
||||
float* output_O_temp,
|
||||
float* output_sum_temp) {
|
||||
int lane_id = threadIdx.x % WARP_SIZE;
|
||||
int group_id = threadIdx.x / WARP_SIZE;
|
||||
int parallel_idx = blockIdx.x * (blockDim.x / WARP_SIZE) + group_id;
|
||||
|
||||
float ptr_O[4] = {0};
|
||||
float ptr_O_sum[4] = {0};
|
||||
float ptr_sum = 0;
|
||||
float ptr_sum_temp;
|
||||
int size = (position_id[0] + SEQ_UNIT) / SEQ_UNIT;
|
||||
|
||||
#pragma unroll
|
||||
for(int i = 0; i < size; i ++){
|
||||
(float4 &)ptr_O[0]
|
||||
= (float4 &)output_O_temp[(lane_id * 4) + (i * compMeta.dimSize[3]) + parallel_idx * compMeta.dimSize[3] * size];
|
||||
ptr_sum_temp = output_sum_temp[i + parallel_idx * size];
|
||||
|
||||
#pragma unroll
|
||||
for(int k = 0; k < 4; k ++)
|
||||
ptr_O_sum[k] += ptr_O[k] * ptr_sum_temp;
|
||||
ptr_sum += ptr_sum_temp;
|
||||
}
|
||||
|
||||
#pragma unroll
|
||||
for(int k = 0; k < 4; k ++)
|
||||
ptr_O_sum[k] = ptr_O_sum[k] / ptr_sum;
|
||||
|
||||
(float4 &)output_matmul[(lane_id * 4) + (parallel_idx * compMeta.dimSize[3])] = (float4 &)ptr_O_sum[0];
|
||||
|
||||
}
|
||||
|
||||
|
||||
namespace infini {
|
||||
void attention_kvcache_kernel(float *input_k_cache, float *input_v_cache, float *input_q, float *input_k,
|
||||
void attention_kvcache_kernel(float *input_k_cache, float *input_v_cache,
|
||||
float *input_q, float *input_k,
|
||||
float *input_v, int *position_id, float *output_matmul,
|
||||
const AttentionKVCacheMetadata &compMeta) {
|
||||
IT_ASSERT(compMeta.dimSize[3] == 64);
|
||||
dim3 gridDim(compMeta.dimSize[0]*compMeta.dimSize[1]/(BLOCKSIZE/WARP_SIZE), 1);
|
||||
const AttentionKVCacheMetadata &compMeta,
|
||||
float *output_O_temp, float *output_sum_temp) {
|
||||
IT_ASSERT(compMeta.dimSize[3] == 128);
|
||||
|
||||
int gridsize_y = (compMeta.dimSize[2] - 1 + SEQ_UNIT) / SEQ_UNIT;
|
||||
dim3 gridDim(compMeta.dimSize[0]*compMeta.dimSize[1]/(BLOCKSIZE/WARP_SIZE), gridsize_y);
|
||||
dim3 blockDim(BLOCKSIZE, 1);
|
||||
|
||||
_attention_kvcache_kernel<<<gridDim, blockDim>>>(
|
||||
input_k_cache, input_v_cache, input_q, input_k, input_v, position_id, output_matmul, compMeta);
|
||||
assert(compMeta.dimSize[3] == 128);
|
||||
_attention_kvcache_kernel_128_1<<<gridDim, blockDim>>>(
|
||||
input_k_cache, input_v_cache, input_q, input_k, input_v, position_id,
|
||||
compMeta, output_O_temp, output_sum_temp);
|
||||
_attention_kvcache_kernel_128_2<<<compMeta.dimSize[0]*compMeta.dimSize[1]/(BLOCKSIZE/WARP_SIZE), WARP_SIZE>>>(
|
||||
position_id, output_matmul, compMeta, output_O_temp, output_sum_temp);
|
||||
|
||||
}
|
||||
|
||||
} // namespace infini
|
||||
|
|
|
@ -2,15 +2,14 @@
|
|||
#include "utils/operator_utils.h"
|
||||
|
||||
namespace infini {
|
||||
AttentionKVCacheObj::AttentionKVCacheObj(GraphObj *graph, Tensor input_k_cache,
|
||||
Tensor input_v_cache, Tensor input_q,
|
||||
Tensor input_k, Tensor input_v,
|
||||
Tensor position_id,
|
||||
Tensor output_matmul)
|
||||
AttentionKVCacheObj::AttentionKVCacheObj(
|
||||
GraphObj *graph, Tensor input_k_cache, Tensor input_v_cache, Tensor input_q,
|
||||
Tensor input_k, Tensor input_v, Tensor position_id, Tensor output_matmul,
|
||||
Tensor output_k_cache, Tensor output_v_cache)
|
||||
: OperatorObj(OpType::AttentionKVCache,
|
||||
TensorVec{input_k_cache, input_v_cache, input_q, input_k,
|
||||
input_v, position_id},
|
||||
{output_matmul}) {
|
||||
TensorVec{output_matmul, output_k_cache, output_v_cache}) {
|
||||
int rank = inputs[0]->getRank();
|
||||
IT_ASSERT(rank == 4);
|
||||
dim = 2;
|
||||
|
@ -23,7 +22,7 @@ AttentionKVCacheObj::inferShape(const TensorVec &inputs) {
|
|||
Shape dims = inputs[0]->getDims();
|
||||
ShapeElem n = dims.at(dim);
|
||||
dims[dim] = n + 1;
|
||||
return {{inputs[2]->getDims()}};
|
||||
return {{inputs[2]->getDims(), dims, dims}};
|
||||
}
|
||||
|
||||
std::string AttentionKVCacheObj::toString() const {
|
||||
|
|
|
@ -14,16 +14,16 @@ TEST(AttentionKVCache, Cuda) {
|
|||
|
||||
auto cudaRuntime = make_ref<CudaRuntimeObj>();
|
||||
Graph gCuda = make_ref<GraphObj>(cudaRuntime);
|
||||
auto input_k_cache_d = gCuda->addTensor({1, 1, 1, 64}, DataType::Float32);
|
||||
auto input_v_cache_d = gCuda->addTensor({1, 1, 1, 64}, DataType::Float32);
|
||||
auto input_q_d = gCuda->addTensor({1, 1, 1, 64}, DataType::Float32);
|
||||
auto input_k_d = gCuda->addTensor({1, 1, 1, 64}, DataType::Float32);
|
||||
auto input_v_d = gCuda->addTensor({1, 1, 1, 64}, DataType::Float32);
|
||||
auto input_k_cache_d = gCuda->addTensor({1, 1, 1, 128}, DataType::Float32);
|
||||
auto input_v_cache_d = gCuda->addTensor({1, 1, 1, 128}, DataType::Float32);
|
||||
auto input_q_d = gCuda->addTensor({1, 1, 1, 128}, DataType::Float32);
|
||||
auto input_k_d = gCuda->addTensor({1, 1, 1, 128}, DataType::Float32);
|
||||
auto input_v_d = gCuda->addTensor({1, 1, 1, 128}, DataType::Float32);
|
||||
auto position_id_d = gCuda->addTensor({1, 1}, DataType::UInt32);
|
||||
|
||||
auto op = gCuda->addOp<AttentionKVCacheObj>(
|
||||
input_k_cache_d, input_v_cache_d, input_q_d, input_k_d, input_v_d,
|
||||
position_id_d, nullptr);
|
||||
position_id_d, nullptr, nullptr, nullptr);
|
||||
gCuda->dataMalloc();
|
||||
|
||||
input_q_d->setData(OneGenerator());
|
||||
|
@ -32,11 +32,14 @@ TEST(AttentionKVCache, Cuda) {
|
|||
position_id_d->setData(IncrementalGenerator());
|
||||
cudaRuntime->run(gCuda);
|
||||
|
||||
auto oCpu = gCpu->cloneTensor(op->getOutput());
|
||||
auto oCpu = gCpu->cloneTensor(op->getOutputs()[0]);
|
||||
EXPECT_TRUE(oCpu->equalData(vector<float>{
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1}));
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
|
||||
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1}));
|
||||
}
|
||||
|
||||
} // namespace infini
|
||||
|
|
Loading…
Reference in New Issue