Teen-Different/Code_Opt_Triton · Datasets at Hugging Face

entry_point stringlengths 1 65	original_triton_python_code stringlengths 208 619k	optimised_triton_code stringlengths 1.15k 275k	repo_name stringlengths 7 115	module_name stringlengths 1 65	synthetic bool 1 class	uuid int64 0 18.5k	licenses listlengths 1 6	sha stringlengths 40 40	repo_link stringlengths 72 180
FocalLoss	import torch from torch import nn class FocalLoss(nn.Module): def __init__(self, gamma=0, eps=1e-07): super(FocalLoss, self).__init__() self.gamma = gamma self.eps = eps self.ce = torch.nn.CrossEntropyLoss(reduction='none') def forward(self, input, target): logp = self.ce(input, target) p = torch.exp(-logp) loss = (1 - p) ** self.gamma * logp return loss.mean() def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__log_softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_per_fused__log_softmax_exp_mean_mul_neg_pow_rsub_sum_1(in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex % 16 r1 = rindex // 16 tmp0 = tl.load(in_ptr0 + (r0 + 64 * r1), None) tmp2 = tl.load(in_ptr0 + (16 + r0 + 64 * r1), None) tmp5 = tl.load(in_ptr0 + (32 + r0 + 64 * r1), None) tmp8 = tl.load(in_ptr0 + (48 + r0 + 64 * r1), None) tmp13 = tl.load(in_ptr1 + (r0 + 64 * r1), None) tmp16 = tl.load(in_ptr1 + (16 + r0 + 64 * r1), None) tmp20 = tl.load(in_ptr1 + (32 + r0 + 64 * r1), None) tmp24 = tl.load(in_ptr1 + (48 + r0 + 64 * r1), None) tmp1 = tl_math.exp(tmp0) tmp3 = tl_math.exp(tmp2) tmp4 = tmp1 + tmp3 tmp6 = tl_math.exp(tmp5) tmp7 = tmp4 + tmp6 tmp9 = tl_math.exp(tmp8) tmp10 = tmp7 + tmp9 tmp11 = tl_math.log(tmp10) tmp12 = tmp0 - tmp11 tmp14 = tmp12 * tmp13 tmp15 = tmp2 - tmp11 tmp17 = tmp15 * tmp16 tmp18 = tmp14 + tmp17 tmp19 = tmp5 - tmp11 tmp21 = tmp19 * tmp20 tmp22 = tmp18 + tmp21 tmp23 = tmp8 - tmp11 tmp25 = tmp23 * tmp24 tmp26 = tmp22 + tmp25 tmp27 = -tmp26 tmp28 = -tmp27 tmp29 = tl_math.exp(tmp28) tmp30 = 1.0 tmp30 - tmp29 tmp32 = tmp30 * tmp27 tmp33 = tl.broadcast_to(tmp32, [XBLOCK, RBLOCK]) tmp35 = tl.sum(tmp33, 1)[:, None] tmp36 = 64.0 tmp37 = tmp35 / tmp36 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp37, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__log_softmax_0[grid(256)](arg1_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg1_1 buf2 = empty_strided_cuda((), (), torch.float32) buf3 = buf2 del buf2 triton_per_fused__log_softmax_exp_mean_mul_neg_pow_rsub_sum_1[grid(1)]( buf3, buf0, arg0_1, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del buf0 return buf3, class FocalLossNew(nn.Module): def __init__(self, gamma=0, eps=1e-07): super(FocalLossNew, self).__init__() self.gamma = gamma self.eps = eps self.ce = torch.nn.CrossEntropyLoss(reduction='none') def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Lascarfo/kaggle-landmark-recognition-2020-1st-place	FocalLoss	false	2,501	[ "MIT" ]	f9007d81e59ecd1311bdea5586a426b8973a2eb8	https://github.com/Lascarfo/kaggle-landmark-recognition-2020-1st-place/tree/f9007d81e59ecd1311bdea5586a426b8973a2eb8
Attention	import math import torch import torch.nn as nn class Attention(nn.Module): """ Using two types of attention mechanism: "Dot" and "Bahdanau" """ def __init__(self, hidden_size, use_tanh=False, C=10, name='Bahdanau', use_cuda=True): super(Attention, self).__init__() self.use_tanh = use_tanh self.C = C self.name = name if name == 'Bahdanau': self.W_query = nn.Linear(hidden_size, hidden_size) self.W_ref = nn.Conv1d(hidden_size, hidden_size, 1, 1) V = torch.FloatTensor(hidden_size) if use_cuda: V = V self.V = nn.Parameter(V) self.V.data.uniform_(-(1.0 / math.sqrt(hidden_size)), 1.0 / math.sqrt(hidden_size)) def forward(self, query, ref): """ Args: query: [batch_size x hidden_size] ref: [batch_size x seq_len x hidden_size] """ batch_size = ref.size(0) seq_len = ref.size(1) if self.name == 'Bahdanau': ref = ref.permute(0, 2, 1) query = self.W_query(query).unsqueeze(2) ref = self.W_ref(ref) expanded_query = query.repeat(1, 1, seq_len) V = self.V.unsqueeze(0).unsqueeze(0).repeat(batch_size, 1, 1) logits = torch.bmm(V, torch.tanh(expanded_query + ref)).squeeze(1) elif self.name == 'Dot': query = query.unsqueeze(2) logits = torch.bmm(ref, query).squeeze(2) ref = ref.permute(0, 2, 1) else: raise NotImplementedError if self.use_tanh: logits = self.C * torch.tanh(logits) else: logits = logits return ref, logits def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'hidden_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y0 = yindex % 4 y1 = yindex // 4 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * x2 + 16 * y1), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 4 * y3), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_add_convolution_repeat_tanh_1(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x4 = xindex x1 = xindex // 4 % 4 x3 = xindex // 4 tmp0 = tl.load(in_out_ptr0 + x4, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x3, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp3 + tmp2 tmp5 = libdevice.tanh(tmp4) tl.store(in_out_ptr0 + x4, tmp2, xmask) tl.store(out_ptr0 + x4, tmp5, xmask) @triton.jit def triton_poi_fused_repeat_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4, 4, 1), (4, 1, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_3, primals_4, reinterpret_tensor( primals_2, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf0) del primals_2 del primals_3 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_convolution_0[grid(16, 4)](primals_1, buf1, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf2 = extern_kernels.convolution(buf1, primals_5, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4), (16, 4, 1)) buf3 = buf2 del buf2 buf4 = buf1 del buf1 triton_poi_fused_add_convolution_repeat_tanh_1[grid(64)](buf3, primals_6, buf0, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_6 buf5 = reinterpret_tensor(buf0, (4, 1, 4), (4, 16, 1), 0) del buf0 triton_poi_fused_repeat_2[grid(16)](primals_7, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_7 buf6 = empty_strided_cuda((4, 1, 4), (4, 4, 1), torch.float32) extern_kernels.bmm(buf5, buf4, out=buf6) return buf3, reinterpret_tensor(buf6, (4, 4), (4, 1), 0 ), primals_4, primals_5, reinterpret_tensor(primals_1, (4, 4, 4), ( 16, 1, 4), 0), buf4, reinterpret_tensor(buf5, (4, 4, 1), (4, 1, 4), 0) class AttentionNew(nn.Module): """ Using two types of attention mechanism: "Dot" and "Bahdanau" """ def __init__(self, hidden_size, use_tanh=False, C=10, name='Bahdanau', use_cuda=True): super(AttentionNew, self).__init__() self.use_tanh = use_tanh self.C = C self.name = name if name == 'Bahdanau': self.W_query = nn.Linear(hidden_size, hidden_size) self.W_ref = nn.Conv1d(hidden_size, hidden_size, 1, 1) V = torch.FloatTensor(hidden_size) if use_cuda: V = V self.V = nn.Parameter(V) self.V.data.uniform_(-(1.0 / math.sqrt(hidden_size)), 1.0 / math.sqrt(hidden_size)) def forward(self, input_0, input_1): primals_3 = self.V primals_2 = self.W_query.weight primals_6 = self.W_query.bias primals_5 = self.W_ref.weight primals_7 = self.W_ref.bias primals_4 = input_0 primals_1 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0], output[1]	Lance0226/CIS700_Convex_Hull_RL	Attention	false	2,502	[ "MIT" ]	3c87e063209d535d75fde719bf17f20dd5e68635	https://github.com/Lance0226/CIS700_Convex_Hull_RL/tree/3c87e063209d535d75fde719bf17f20dd5e68635
BothContextGate	import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class BothContextGate(nn.Module): """Apply the context gate to both contexts""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(BothContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh((1.0 - z) * target + z * source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_rsub_sigmoid_tanh_2(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp4 = tl.load(in_ptr1 + x0, xmask) tmp6 = tl.load(in_ptr2 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp2 = 1.0 tmp3 = tmp2 - tmp1 tmp5 = tmp3 * tmp4 tmp7 = tmp1 * tmp6 tmp8 = tmp5 + tmp7 tmp9 = libdevice.tanh(tmp8) tl.store(out_ptr0 + x0, tmp9, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_6 del primals_7 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf4) del primals_8 del primals_9 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused_add_mul_rsub_sigmoid_tanh_2[grid(16)](buf1, buf4, buf2, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) return buf5, primals_3, buf0, buf1, buf2, buf3, buf4, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class BothContextGateNew(nn.Module): """Apply the context gate to both contexts""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(BothContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]	LeeeeoLiu/OpenNMT-py	BothContextGate	false	2,503	[ "MIT" ]	9be3a8951e9181aabe5440e4ea98173b7e749b5c	https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c
GraphEmbedding	import math import torch import torch.nn as nn class GraphEmbedding(nn.Module): def __init__(self, input_size, ebd_size, use_cuda=True, use_sdne=True, add_noise=False, is_training=True): super(GraphEmbedding, self).__init__() self.use_cuda = use_cuda self.use_sdne = use_sdne self.add_noise = add_noise self.is_training = is_training ebd_size_1 = ebd_size * 4 if use_sdne else ebd_size ebd_size_2 = ebd_size * 2 ebd_size_3 = ebd_size self.embedding_1 = nn.Parameter(torch.FloatTensor(input_size, ebd_size_1)) if self.use_sdne: self.embedding_2 = nn.Parameter(torch.FloatTensor(ebd_size_1, ebd_size_2)) self.embedding_3 = nn.Parameter(torch.FloatTensor(ebd_size_2, ebd_size_3)) self.embedding_1.data.uniform_(-(1.0 / math.sqrt(ebd_size_1)), 1.0 / math.sqrt(ebd_size_1)) if self.use_sdne: self.embedding_2.data.uniform_(-(1.0 / math.sqrt(ebd_size_2)), 1.0 / math.sqrt(ebd_size_2)) self.embedding_3.data.uniform_(-(1.0 / math.sqrt(ebd_size_3)), 1.0 / math.sqrt(ebd_size_3)) def forward(self, inputs): """ :param inputs: tensor [batch, 2, seq_len] :return: embedded: tensor [batch, seq_len, embedding_size] Embed each node in the graph to a 128-dimension space """ batch_size = inputs.size(0) seq_len = inputs.size(2) embedding_1 = self.embedding_1.repeat(batch_size, 1, 1) if self.use_sdne: embedding_2 = self.embedding_2.repeat(batch_size, 1, 1) embedding_3 = self.embedding_3.repeat(batch_size, 1, 1) embedded = [] inputs = inputs.unsqueeze(1) for i in range(seq_len): embedding = torch.bmm(inputs[:, :, :, i].float(), embedding_1) if self.use_sdne: embedding = torch.bmm(embedding.float(), embedding_2) embedding = torch.bmm(embedding.float(), embedding_3) embedded.append(embedding) embedded = torch.cat(tuple(embedded), 1) return embedded def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, 'ebd_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_bmm_repeat_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 64 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 512 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 128 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_3(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 128 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 32 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_4(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_5(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_6(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_cat_7(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 4 % 4 x0 = xindex % 4 x2 = xindex // 16 x3 = xindex tmp0 = x1 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 1, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (x0 + 4 * x2), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 2, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (x0 + 4 * x2), tmp9 & xmask, eviction_policy= 'evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tmp12 = tl.full([1], 3, tl.int64) tmp13 = tmp0 < tmp12 tmp14 = tmp11 & tmp13 tmp15 = tl.load(in_ptr2 + (x0 + 4 * x2), tmp14 & xmask, eviction_policy ='evict_last', other=0.0) tmp16 = tmp0 >= tmp12 tl.full([1], 4, tl.int64) tmp19 = tl.load(in_ptr3 + (x0 + 4 * x2), tmp16 & xmask, eviction_policy ='evict_last', other=0.0) tmp20 = tl.where(tmp14, tmp15, tmp19) tmp21 = tl.where(tmp9, tmp10, tmp20) tmp22 = tl.where(tmp4, tmp5, tmp21) tl.store(out_ptr0 + x3, tmp22, xmask) def call(args): primals_1, primals_2, primals_3, primals_4 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 16), (16, 1)) assert_size_stride(primals_3, (16, 8), (8, 1)) assert_size_stride(primals_4, (8, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) get_raw_stream(0) triton_poi_fused_bmm_repeat_0[grid(16)](primals_1, buf0, 16, XBLOCK =16, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4, 16), (64, 16, 1), torch.float32) triton_poi_fused_repeat_1[grid(256)](primals_2, buf1, 256, XBLOCK= 128, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf0, buf1, out=buf2) buf3 = empty_strided_cuda((4, 16, 8), (128, 8, 1), torch.float32) triton_poi_fused_repeat_2[grid(512)](primals_3, buf3, 512, XBLOCK= 128, num_warps=4, num_stages=1) del primals_3 buf4 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf2, buf3, out=buf4) buf5 = empty_strided_cuda((4, 8, 4), (32, 4, 1), torch.float32) triton_poi_fused_repeat_3[grid(128)](primals_4, buf5, 128, XBLOCK= 128, num_warps=4, num_stages=1) del primals_4 buf6 = reinterpret_tensor(buf0, (4, 1, 4), (4, 4, 1), 0) del buf0 extern_kernels.bmm(buf4, buf5, out=buf6) buf7 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_4[grid(16)](primals_1, buf7, 16, XBLOCK=16, num_warps=1, num_stages=1) buf8 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf7, buf1, out=buf8) buf9 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf8, buf3, out=buf9) buf10 = reinterpret_tensor(buf7, (4, 1, 4), (4, 4, 1), 0) del buf7 extern_kernels.bmm(buf9, buf5, out=buf10) buf11 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_5[grid(16)](primals_1, buf11, 16, XBLOCK=16, num_warps=1, num_stages=1) buf12 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf11, buf1, out=buf12) buf13 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf12, buf3, out=buf13) buf14 = reinterpret_tensor(buf11, (4, 1, 4), (4, 4, 1), 0) del buf11 extern_kernels.bmm(buf13, buf5, out=buf14) buf15 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_6[grid(16)](primals_1, buf15, 16, XBLOCK=16, num_warps=1, num_stages=1) buf16 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf15, buf1, out=buf16) del buf1 buf17 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf16, buf3, out=buf17) buf18 = reinterpret_tensor(buf15, (4, 1, 4), (4, 4, 1), 0) del buf15 extern_kernels.bmm(buf17, buf5, out=buf18) buf19 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_cat_7[grid(64)](buf6, buf10, buf14, buf18, buf19, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf10 del buf14 del buf18 del buf6 return buf19, reinterpret_tensor(buf17, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf5, (4, 4, 8), (32, 1, 4), 0 ), reinterpret_tensor(buf16, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(buf3, (4, 8, 16), (128, 1, 8), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 3 ), reinterpret_tensor(buf13, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf12, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 2 ), reinterpret_tensor(buf9, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf8, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 1 ), reinterpret_tensor(buf4, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf2, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 0) class GraphEmbeddingNew(nn.Module): def __init__(self, input_size, ebd_size, use_cuda=True, use_sdne=True, add_noise=False, is_training=True): super(GraphEmbeddingNew, self).__init__() self.use_cuda = use_cuda self.use_sdne = use_sdne self.add_noise = add_noise self.is_training = is_training ebd_size_1 = ebd_size * 4 if use_sdne else ebd_size ebd_size_2 = ebd_size * 2 ebd_size_3 = ebd_size self.embedding_1 = nn.Parameter(torch.FloatTensor(input_size, ebd_size_1)) if self.use_sdne: self.embedding_2 = nn.Parameter(torch.FloatTensor(ebd_size_1, ebd_size_2)) self.embedding_3 = nn.Parameter(torch.FloatTensor(ebd_size_2, ebd_size_3)) self.embedding_1.data.uniform_(-(1.0 / math.sqrt(ebd_size_1)), 1.0 / math.sqrt(ebd_size_1)) if self.use_sdne: self.embedding_2.data.uniform_(-(1.0 / math.sqrt(ebd_size_2)), 1.0 / math.sqrt(ebd_size_2)) self.embedding_3.data.uniform_(-(1.0 / math.sqrt(ebd_size_3)), 1.0 / math.sqrt(ebd_size_3)) def forward(self, input_0): primals_2 = self.embedding_1 primals_3 = self.embedding_2 primals_4 = self.embedding_3 primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]	Lance0226/CIS700_Convex_Hull_RL	GraphEmbedding	false	2,504	[ "MIT" ]	3c87e063209d535d75fde719bf17f20dd5e68635	https://github.com/Lance0226/CIS700_Convex_Hull_RL/tree/3c87e063209d535d75fde719bf17f20dd5e68635
GeM	import torch from torch import nn from torch.nn import functional as F from torch.nn.parameter import Parameter def gem(x, p=3, eps=1e-06): return F.avg_pool2d(x.clamp(min=eps).pow(p), (x.size(-2), x.size(-1))).pow( 1.0 / p) class GeM(nn.Module): def __init__(self, p=3, eps=1e-06, p_trainable=True): super(GeM, self).__init__() if p_trainable: self.p = Parameter(torch.ones(1) * p) else: self.p = p self.eps = eps def forward(self, x): return gem(x, p=self.p, eps=self.eps) def __repr__(self): return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(self. p.data.tolist()[0]) + ', ' + 'eps=' + str(self.eps) + ')' def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn from torch.nn import functional as F from torch.nn.parameter import Parameter assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp3 = tl.load(in_ptr1 + 0) tmp4 = tl.broadcast_to(tmp3, [XBLOCK]) tmp1 = 1e-06 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp5 = libdevice.pow(tmp2, tmp4) tl.store(out_ptr0 + x0, tmp5, xmask) @triton.jit def triton_poi_fused_avg_pool2d_mul_pow_reciprocal_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 16 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (1 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_ptr0 + (2 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp5 = tl.load(in_ptr0 + (3 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp7 = tl.load(in_ptr0 + (4 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp9 = tl.load(in_ptr0 + (5 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp11 = tl.load(in_ptr0 + (6 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp13 = tl.load(in_ptr0 + (7 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp15 = tl.load(in_ptr0 + (8 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp17 = tl.load(in_ptr0 + (9 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp19 = tl.load(in_ptr0 + (10 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp21 = tl.load(in_ptr0 + (11 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp23 = tl.load(in_ptr0 + (12 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp25 = tl.load(in_ptr0 + (13 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp27 = tl.load(in_ptr0 + (14 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp29 = tl.load(in_ptr0 + (15 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp33 = tl.load(in_ptr1 + 0) tmp34 = tl.broadcast_to(tmp33, [XBLOCK]) tmp2 = tmp1 + tmp0 tmp4 = tmp3 + tmp2 tmp6 = tmp5 + tmp4 tmp8 = tmp7 + tmp6 tmp10 = tmp9 + tmp8 tmp12 = tmp11 + tmp10 tmp14 = tmp13 + tmp12 tmp16 = tmp15 + tmp14 tmp18 = tmp17 + tmp16 tmp20 = tmp19 + tmp18 tmp22 = tmp21 + tmp20 tmp24 = tmp23 + tmp22 tmp26 = tmp25 + tmp24 tmp28 = tmp27 + tmp26 tmp30 = tmp29 + tmp28 tmp31 = 0.0625 tmp32 = tmp30 * tmp31 tmp35 = tl.full([1], 1, tl.int32) tmp36 = tmp35 / tmp34 tmp37 = 1.0 tmp38 = tmp36 * tmp37 tmp39 = libdevice.pow(tmp32, tmp38) tl.store(out_ptr0 + x0, tmp32, xmask) tl.store(out_ptr1 + x0, tmp39, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (1,), (1,)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_pow_0[grid(256)](primals_2, primals_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) buf2 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused_avg_pool2d_mul_pow_reciprocal_1[grid(16)](buf0, primals_1, buf1, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) return buf2, primals_1, primals_2, buf0, buf1, buf2 def gem(x, p=3, eps=1e-06): return F.avg_pool2d(x.clamp(min=eps).pow(p), (x.size(-2), x.size(-1))).pow( 1.0 / p) class GeMNew(nn.Module): def __init__(self, p=3, eps=1e-06, p_trainable=True): super(GeMNew, self).__init__() if p_trainable: self.p = Parameter(torch.ones(1) * p) else: self.p = p self.eps = eps def __repr__(self): return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(self. p.data.tolist()[0]) + ', ' + 'eps=' + str(self.eps) + ')' def forward(self, input_0): primals_1 = self.p primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]	Lascarfo/kaggle-landmark-recognition-2020-1st-place	GeM	false	2,505	[ "MIT" ]	f9007d81e59ecd1311bdea5586a426b8973a2eb8	https://github.com/Lascarfo/kaggle-landmark-recognition-2020-1st-place/tree/f9007d81e59ecd1311bdea5586a426b8973a2eb8
FocalLossBinary	import torch import torch.nn.functional import torch.jit import torch.nn.functional as F from functools import partial from torch.nn.modules.loss import _Loss def reduced_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', threshold: 'float'=0.5, gamma: 'float'=2.0, reduction='mean'): """ Compute reduced focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" \| "mean" \| "sum" \| "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. Note: :attr:`size_average` and :attr:`reduce` are in the process of being deprecated, and in the meantime, specifying either of those two args will override :attr:`reduction`. "batchwise_mean" computes mean loss per sample in batch. Default: "mean" See https://arxiv.org/abs/1903.01347 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) focal_reduction = ((1.0 - pt) / threshold).pow(gamma) focal_reduction[pt < threshold] = 1 loss = -focal_reduction * logpt if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss def sigmoid_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', gamma: 'float'=2.0, alpha: 'float'=0.25, reduction: 'str'='mean'): """ Compute binary focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" \| "mean" \| "sum" \| "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. See https://github.com/open-mmlab/mmdetection/blob/master/mmdet/core/loss/losses.py # noqa: E501 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) loss = -(1 - pt).pow(gamma) * logpt if alpha is not None: loss = loss * (alpha * targets + (1 - alpha) * (1 - targets)) if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss class FocalLossBinary(_Loss): def __init__(self, ignore: 'int'=None, reduced: 'bool'=False, gamma: 'float'=2.0, alpha: 'float'=0.25, threshold: 'float'=0.5, reduction: 'str'='mean'): """ Compute focal loss for binary classification problem. """ super().__init__() self.ignore = ignore if reduced: self.loss_fn = partial(reduced_focal_loss, gamma=gamma, threshold=threshold, reduction=reduction) else: self.loss_fn = partial(sigmoid_focal_loss, gamma=gamma, alpha= alpha, reduction=reduction) def forward(self, logits, targets): """ Args: logits: [bs; ...] targets: [bs; ...] """ targets = targets.view(-1) logits = logits.view(-1) if self.ignore is not None: not_ignored = targets != self.ignore logits = logits[not_ignored] targets = targets[not_ignored] loss = self.loss_fn(logits, targets) return loss def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice, math as tl_math import torch.nn.functional import torch.jit import torch.nn.functional as F from functools import partial from torch.nn.modules.loss import _Loss assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_binary_cross_entropy_with_logits_exp_mean_mul_neg_pow_rsub_0( in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp3 = tl.load(in_ptr1 + r0, None) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tmp4 = tmp2 * tmp3 tmp5 = 0.0 tmp6 = triton_helpers.minimum(tmp5, tmp3) tmp7 = tl_math.abs(tmp3) tmp8 = -tmp7 tmp9 = tl_math.exp(tmp8) tmp10 = libdevice.log1p(tmp9) tmp11 = tmp6 - tmp10 tmp12 = tmp4 - tmp11 tmp13 = -tmp12 tmp14 = tl_math.exp(tmp13) tmp15 = tmp1 - tmp14 tmp16 = tmp15 * tmp15 tmp17 = -tmp16 tmp18 = tmp17 * tmp13 tmp19 = 0.25 tmp20 = tmp0 * tmp19 tmp21 = 0.75 tmp22 = tmp2 * tmp21 tmp23 = tmp20 + tmp22 tmp24 = tmp18 * tmp23 tmp25 = tl.broadcast_to(tmp24, [RBLOCK]) tmp27 = triton_helpers.promote_to_tensor(tl.sum(tmp25, 0)) tmp28 = 256.0 tmp29 = tmp27 / tmp28 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp29, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_binary_cross_entropy_with_logits_exp_mean_mul_neg_pow_rsub_0[ grid(1)](buf1, arg0_1, arg1_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf1, def reduced_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', threshold: 'float'=0.5, gamma: 'float'=2.0, reduction='mean'): """ Compute reduced focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" \| "mean" \| "sum" \| "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. Note: :attr:`size_average` and :attr:`reduce` are in the process of being deprecated, and in the meantime, specifying either of those two args will override :attr:`reduction`. "batchwise_mean" computes mean loss per sample in batch. Default: "mean" See https://arxiv.org/abs/1903.01347 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) focal_reduction = ((1.0 - pt) / threshold).pow(gamma) focal_reduction[pt < threshold] = 1 loss = -focal_reduction * logpt if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss def sigmoid_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', gamma: 'float'=2.0, alpha: 'float'=0.25, reduction: 'str'='mean'): """ Compute binary focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" \| "mean" \| "sum" \| "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. See https://github.com/open-mmlab/mmdetection/blob/master/mmdet/core/loss/losses.py # noqa: E501 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) loss = -(1 - pt).pow(gamma) * logpt if alpha is not None: loss = loss * (alpha * targets + (1 - alpha) * (1 - targets)) if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss class FocalLossBinaryNew(_Loss): def __init__(self, ignore: 'int'=None, reduced: 'bool'=False, gamma: 'float'=2.0, alpha: 'float'=0.25, threshold: 'float'=0.5, reduction: 'str'='mean'): """ Compute focal loss for binary classification problem. """ super().__init__() self.ignore = ignore if reduced: self.loss_fn = partial(reduced_focal_loss, gamma=gamma, threshold=threshold, reduction=reduction) else: self.loss_fn = partial(sigmoid_focal_loss, gamma=gamma, alpha= alpha, reduction=reduction) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	LeAlex27/nnUNet	FocalLossBinary	false	2,506	[ "Apache-2.0" ]	9b6912f80904af9eaa4db41cd7e5c7f20058cdde	https://github.com/LeAlex27/nnUNet/tree/9b6912f80904af9eaa4db41cd7e5c7f20058cdde
SourceContextGate	import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class SourceContextGate(nn.Module): """Apply the context gate only to the source context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(SourceContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh(target + z * source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_sigmoid_tanh_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp5 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp4 = tl.sigmoid(tmp3) tmp6 = tmp4 * tmp5 tmp7 = tmp2 + tmp6 tmp8 = libdevice.tanh(tmp7) tl.store(in_out_ptr0 + x2, tmp8, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_6 del primals_7 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8 ), 0), out=buf4) del primals_8 buf5 = buf4 del buf4 triton_poi_fused_add_mul_sigmoid_tanh_2[grid(16)](buf5, primals_9, buf1, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_9 return buf5, primals_3, buf0, buf1, buf2, buf3, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class SourceContextGateNew(nn.Module): """Apply the context gate only to the source context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(SourceContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]	LeeeeoLiu/OpenNMT-py	SourceContextGate	false	2,507	[ "MIT" ]	9be3a8951e9181aabe5440e4ea98173b7e749b5c	https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c
TargetContextGate	import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class TargetContextGate(nn.Module): """Apply the context gate only to the target context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(TargetContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh(z * target + source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_sigmoid_tanh_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp2 = tl.load(in_ptr1 + x2, xmask) tmp4 = tl.load(in_out_ptr0 + x2, xmask) tmp5 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.sigmoid(tmp0) tmp3 = tmp1 * tmp2 tmp6 = tmp4 + tmp5 tmp7 = tmp3 + tmp6 tmp8 = libdevice.tanh(tmp7) tl.store(in_out_ptr0 + x2, tmp8, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf2) del primals_6 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf4) del primals_8 del primals_9 buf5 = buf2 del buf2 triton_poi_fused_add_mul_sigmoid_tanh_2[grid(16)](buf5, buf1, buf4, primals_7, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_7 return buf5, primals_3, buf0, buf1, buf3, buf4, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class TargetContextGateNew(nn.Module): """Apply the context gate only to the target context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(TargetContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]	LeeeeoLiu/OpenNMT-py	TargetContextGate	false	2,508	[ "MIT" ]	9be3a8951e9181aabe5440e4ea98173b7e749b5c	https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c
Foo	import torch import torch.nn.functional import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd class Foo(torch.nn.Module): def __init__(self, size): super(Foo, self).__init__() self.n = torch.nn.Parameter(torch.ones(size)) self.m = torch.nn.Parameter(torch.ones(size)) def forward(self, input): return self.n * input + self.m def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'size': 4}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_mul_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask) tmp3 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 * tmp1 tmp4 = tmp2 + tmp3 tl.store(out_ptr0 + x2, tmp4, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4,), (1,)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_mul_0[grid(256)](primals_1, primals_2, primals_3, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_1 del primals_3 return buf0, primals_2 class FooNew(torch.nn.Module): def __init__(self, size): super(FooNew, self).__init__() self.n = torch.nn.Parameter(torch.ones(size)) self.m = torch.nn.Parameter(torch.ones(size)) def forward(self, input_0): primals_1 = self.n primals_3 = self.m primals_2 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	Liuhongzhi2018/Person_ReID	Foo	false	2,509	[ "MIT" ]	51c576ed5b4ed960801669d6d59c0a77405b369d	https://github.com/Liuhongzhi2018/Person_ReID/tree/51c576ed5b4ed960801669d6d59c0a77405b369d
ScaledDotProductAtten	import torch import numpy as np from torch import nn class ScaledDotProductAtten(nn.Module): """ Scaled dot-product attention mechainsm 公式： $ Attention(Q, K, V) = softmax(rac{Q K^T}{\\sqrt{d_k}})V $ ![](https://raw.githubusercontent.com/LinXueyuanStdio/scRNN-seq/master/art/2.png) """ def __init__(self, encode_size, atten_dropout=0.1): super(ScaledDotProductAtten, self).__init__() encode_size = 2 encode_size self.scale = encode_size ** -0.5 self.dropout = nn.Dropout(atten_dropout) self.softmax = nn.Softmax(dim=2) def forward(self, query, key, value, atten_mask=None): """ 前向传播. Args: Q: Queries，[B, L_q, D_q] K: Keys，[B, L_k, D_k] V: Values，[B, L_v, D_v]，一般来说就是k scale: 缩放因子，一个浮点标量 attn_mask: Masking，[B, L_q, L_k] Returns: 上下文张量和attetention张量 """ atten = torch.bmm(query, key.transpose(1, 2)) * self.scale if atten_mask: atten.masked_fill_(atten_mask, -np.inf) atten = self.softmax(atten) atten = self.dropout(atten) context = torch.bmm(atten, value) return context, atten def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4]) ] def get_init_inputs(): return [[], {'encode_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tmp4 = tmp3 * tmp1 tmp6 = tmp5 * tmp1 tmp7 = triton_helpers.maximum(tmp4, tmp6) tmp9 = tmp8 * tmp1 tmp10 = triton_helpers.maximum(tmp7, tmp9) tmp12 = tmp11 * tmp1 tmp13 = triton_helpers.maximum(tmp10, tmp12) tmp14 = tmp2 - tmp13 tmp15 = 0.3535533905932738 tmp16 = tmp14 * tmp15 tmp17 = tl_math.exp(tmp16) tl.store(out_ptr0 + x2, tmp17, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4), (16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(arg1_1, reinterpret_tensor(arg0_1, (4, 4, 4), ( 16, 1, 4), 0), out=buf0) del arg0_1 del arg1_1 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(64)](buf0, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = buf0 del buf0 triton_poi_fused__softmax_1[grid(64)](buf1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) buf3 = buf1 del buf1 extern_kernels.bmm(buf2, arg2_1, out=buf3) del arg2_1 return buf3, buf2 class ScaledDotProductAttenNew(nn.Module): """ Scaled dot-product attention mechainsm 公式： $ Attention(Q, K, V) = softmax(rac{Q K^T}{\\sqrt{d_k}})V $ ![](https://raw.githubusercontent.com/LinXueyuanStdio/scRNN-seq/master/art/2.png) """ def __init__(self, encode_size, atten_dropout=0.1): super(ScaledDotProductAttenNew, self).__init__() encode_size = 2 encode_size self.scale = encode_size ** -0.5 self.dropout = nn.Dropout(atten_dropout) self.softmax = nn.Softmax(dim=2) def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0], output[1]	LinXueyuanStdio/scRNN-seq	ScaledDotProductAtten	false	2,510	[ "Apache-2.0" ]	87e11a56acb18a86fa4fb309d33a1bc02bf38b39	https://github.com/LinXueyuanStdio/scRNN-seq/tree/87e11a56acb18a86fa4fb309d33a1bc02bf38b39
FunctionalRelu6	import torch class FunctionalRelu6(torch.nn.Module): def forward(self, x): return torch.nn.functional.relu6(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_hardtanh_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.0 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = 6.0 tmp4 = triton_helpers.minimum(tmp2, tmp3) tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_hardtanh_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class FunctionalRelu6New(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	FunctionalRelu6	false	2,511	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TokenEmbedding	import torch import torch.nn as nn class TokenEmbedding(nn.Module): def __init__(self, c_in, d_model): super(TokenEmbedding, self).__init__() padding = 1 if torch.__version__ >= '1.5.0' else 2 self.tokenConv = nn.Conv1d(in_channels=c_in, out_channels=d_model, kernel_size=3, padding=padding, padding_mode='circular') for m in self.modules(): if isinstance(m, nn.Conv1d): nn.init.kaiming_normal_(m.weight, mode='fan_in', nonlinearity='leaky_relu') def forward(self, x): x = self.tokenConv(x.permute(0, 2, 1)).transpose(1, 2) return x def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'c_in': 4, 'd_model': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_copy_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 24 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel y0 = yindex % 6 x2 = xindex y1 = yindex // 6 tmp0 = y0 tmp1 = tl.full([1, 1], 5, tl.int64) tmp2 = tmp0 >= tmp1 tmp3 = tl.broadcast_to(-4 + y0, [XBLOCK, YBLOCK]) tmp4 = tl.full([1, 1], 1, tl.int64) tmp5 = tmp3 < tmp4 tmp6 = tmp5 & tmp2 tmp7 = tl.broadcast_to(y0, [XBLOCK, YBLOCK]) tmp8 = tmp7 >= tmp4 tmp9 = tmp7 < tmp1 tmp10 = tmp8 & tmp9 tmp11 = tmp10 & tmp6 tmp12 = tl.load(in_ptr0 + (-4 + x2 + 4 * y0 + 16 * y1), tmp11 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp13 = float('nan') tmp14 = tl.where(tmp10, tmp12, tmp13) tmp15 = tl.full(tmp14.shape, 0.0, tmp14.dtype) tmp16 = tl.where(tmp6, tmp14, tmp15) tmp17 = tmp3 >= tmp4 tmp18 = tmp3 < tmp1 tmp19 = tmp17 & tmp18 tmp20 = tmp19 & tmp2 tmp21 = tl.load(in_ptr0 + (-20 + x2 + 4 * y0 + 16 * y1), tmp20 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp22 = tl.where(tmp19, tmp21, tmp13) tmp23 = tl.where(tmp5, tmp16, tmp22) tmp24 = tl.full(tmp23.shape, 0.0, tmp23.dtype) tmp25 = tl.where(tmp2, tmp23, tmp24) tmp26 = tmp0 < tmp4 tmp27 = tl.broadcast_to(4 + y0, [XBLOCK, YBLOCK]) tmp28 = tmp27 >= tmp4 tmp29 = tmp27 < tmp1 tmp30 = tmp28 & tmp29 tmp31 = tmp30 & tmp26 tmp32 = tl.load(in_ptr0 + (12 + x2 + 4 * y0 + 16 * y1), tmp31 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp33 = tl.where(tmp30, tmp32, tmp13) tmp34 = tl.full(tmp33.shape, 0.0, tmp33.dtype) tmp35 = tl.where(tmp26, tmp33, tmp34) tmp36 = tmp0 >= tmp4 tmp37 = tmp0 < tmp1 tmp38 = tmp36 & tmp37 tmp39 = tl.load(in_ptr0 + (-4 + x2 + 4 * y0 + 16 * y1), tmp38 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp40 = tl.where(tmp38, tmp39, tmp13) tmp41 = tl.where(tmp26, tmp35, tmp40) tmp42 = tl.where(tmp2, tmp25, tmp41) tl.store(out_ptr0 + (y0 + 6 * x2 + 24 * y1), tmp42, xmask & ymask) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 4 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4, 3), (12, 3, 1)) assert_size_stride(primals_3, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf1 = empty_strided_cuda((4, 4, 6), (24, 6, 1), torch.float32) get_raw_stream(0) triton_poi_fused_copy_0[grid(24, 4)](primals_1, buf1, 24, 4, XBLOCK =4, YBLOCK=32, num_warps=4, num_stages=1) del primals_1 buf2 = extern_kernels.convolution(buf1, primals_2, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4), (16, 4, 1)) buf3 = buf2 del buf2 triton_poi_fused_convolution_1[grid(64)](buf3, primals_3, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_3 return reinterpret_tensor(buf3, (4, 4, 4), (16, 1, 4), 0), primals_2, buf1 class TokenEmbeddingNew(nn.Module): def __init__(self, c_in, d_model): super(TokenEmbeddingNew, self).__init__() padding = 1 if torch.__version__ >= '1.5.0' else 2 self.tokenConv = nn.Conv1d(in_channels=c_in, out_channels=d_model, kernel_size=3, padding=padding, padding_mode='circular') for m in self.modules(): if isinstance(m, nn.Conv1d): nn.init.kaiming_normal_(m.weight, mode='fan_in', nonlinearity='leaky_relu') def forward(self, input_0): primals_2 = self.tokenConv.weight primals_3 = self.tokenConv.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	Linan2018/Informer2020	TokenEmbedding	false	2,512	[ "Apache-2.0" ]	30e63a7d3ed9310b917b05c4d60b340d2dd0517a	https://github.com/Linan2018/Informer2020/tree/30e63a7d3ed9310b917b05c4d60b340d2dd0517a
Div	import torch class Div(torch.nn.Module): def __init__(self): super(Div, self).__init__() def forward(self, x, y): return x / y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class DivNew(torch.nn.Module): def __init__(self): super(DivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	Div	false	2,513	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TemporalEmbedding	import math import torch import torch.nn as nn class FixedEmbedding(nn.Module): def __init__(self, c_in, d_model): super(FixedEmbedding, self).__init__() w = torch.zeros(c_in, d_model).float() w.require_grad = False position = torch.arange(0, c_in).float().unsqueeze(1) div_term = (torch.arange(0, d_model, 2).float() * -(math.log( 10000.0) / d_model)).exp() w[:, 0::2] = torch.sin(position * div_term) w[:, 1::2] = torch.cos(position * div_term) self.emb = nn.Embedding(c_in, d_model) self.emb.weight = nn.Parameter(w, requires_grad=False) def forward(self, x): return self.emb(x).detach() class TemporalEmbedding(nn.Module): def __init__(self, d_model, embed_type='fixed', freq='h'): super(TemporalEmbedding, self).__init__() minute_size = 4 hour_size = 24 weekday_size = 7 day_size = 32 month_size = 13 Embed = FixedEmbedding if embed_type == 'fixed' else nn.Embedding if freq == 't': self.minute_embed = Embed(minute_size, d_model) self.hour_embed = Embed(hour_size, d_model) self.weekday_embed = Embed(weekday_size, d_model) self.day_embed = Embed(day_size, d_model) self.month_embed = Embed(month_size, d_model) def forward(self, x): x = x.long() minute_x = self.minute_embed(x[:, :, 4]) if hasattr(self, 'minute_embed') else 0.0 hour_x = self.hour_embed(x[:, :, 3]) weekday_x = self.weekday_embed(x[:, :, 2]) day_x = self.day_embed(x[:, :, 1]) month_x = self.month_embed(x[:, :, 0]) return hour_x + weekday_x + day_x + month_x + minute_x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'d_model': 4}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_embedding_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 4 % 4 x2 = xindex // 16 x0 = xindex % 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (12 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp8 = tl.load(in_ptr0 + (8 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp17 = tl.load(in_ptr0 + (4 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp26 = tl.load(in_ptr0 + (x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp1 = tmp0.to(tl.int64) tmp2 = tl.full([XBLOCK], 24, tl.int32) tmp3 = tmp1 + tmp2 tmp4 = tmp1 < 0 tmp5 = tl.where(tmp4, tmp3, tmp1) tl.device_assert((0 <= tmp5) & (tmp5 < 24) \| ~xmask, 'index out of bounds: 0 <= tmp5 < 24') tmp7 = tl.load(in_ptr1 + (x0 + 4 * tmp5), xmask) tmp9 = tmp8.to(tl.int64) tmp10 = tl.full([XBLOCK], 7, tl.int32) tmp11 = tmp9 + tmp10 tmp12 = tmp9 < 0 tmp13 = tl.where(tmp12, tmp11, tmp9) tl.device_assert((0 <= tmp13) & (tmp13 < 7) \| ~xmask, 'index out of bounds: 0 <= tmp13 < 7') tmp15 = tl.load(in_ptr2 + (x0 + 4 * tmp13), xmask) tmp16 = tmp7 + tmp15 tmp18 = tmp17.to(tl.int64) tmp19 = tl.full([XBLOCK], 32, tl.int32) tmp20 = tmp18 + tmp19 tmp21 = tmp18 < 0 tmp22 = tl.where(tmp21, tmp20, tmp18) tl.device_assert((0 <= tmp22) & (tmp22 < 32) \| ~xmask, 'index out of bounds: 0 <= tmp22 < 32') tmp24 = tl.load(in_ptr3 + (x0 + 4 * tmp22), xmask) tmp25 = tmp16 + tmp24 tmp27 = tmp26.to(tl.int64) tmp28 = tl.full([XBLOCK], 13, tl.int32) tmp29 = tmp27 + tmp28 tmp30 = tmp27 < 0 tmp31 = tl.where(tmp30, tmp29, tmp27) tl.device_assert((0 <= tmp31) & (tmp31 < 13) \| ~xmask, 'index out of bounds: 0 <= tmp31 < 13') tmp33 = tl.load(in_ptr4 + (x0 + 4 * tmp31), xmask) tmp34 = tmp25 + tmp33 tmp35 = 0.0 tmp36 = tmp34 + tmp35 tl.store(out_ptr0 + x4, tmp36, xmask) def call(args): arg0_1, arg1_1, arg2_1, arg3_1, arg4_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (24, 4), (4, 1)) assert_size_stride(arg2_1, (7, 4), (4, 1)) assert_size_stride(arg3_1, (32, 4), (4, 1)) assert_size_stride(arg4_1, (13, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_embedding_0[grid(256)](arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 del arg2_1 del arg3_1 del arg4_1 return buf0, class FixedEmbedding(nn.Module): def __init__(self, c_in, d_model): super(FixedEmbedding, self).__init__() w = torch.zeros(c_in, d_model).float() w.require_grad = False position = torch.arange(0, c_in).float().unsqueeze(1) div_term = (torch.arange(0, d_model, 2).float() * -(math.log( 10000.0) / d_model)).exp() w[:, 0::2] = torch.sin(position * div_term) w[:, 1::2] = torch.cos(position * div_term) self.emb = nn.Embedding(c_in, d_model) self.emb.weight = nn.Parameter(w, requires_grad=False) def forward(self, x): return self.emb(x).detach() class TemporalEmbeddingNew(nn.Module): def __init__(self, d_model, embed_type='fixed', freq='h'): super(TemporalEmbeddingNew, self).__init__() minute_size = 4 hour_size = 24 weekday_size = 7 day_size = 32 month_size = 13 Embed = FixedEmbedding if embed_type == 'fixed' else nn.Embedding if freq == 't': self.minute_embed = Embed(minute_size, d_model) self.hour_embed = Embed(hour_size, d_model) self.weekday_embed = Embed(weekday_size, d_model) self.day_embed = Embed(day_size, d_model) self.month_embed = Embed(month_size, d_model) def forward(self, input_0): arg1_1 = self.hour_embed.emb.weight arg2_1 = self.weekday_embed.emb.weight arg3_1 = self.day_embed.emb.weight arg4_1 = self.month_embed.emb.weight arg0_1 = input_0 output = call([arg0_1, arg1_1, arg2_1, arg3_1, arg4_1]) return output[0]	Linan2018/Informer2020	TemporalEmbedding	false	2,514	[ "Apache-2.0" ]	30e63a7d3ed9310b917b05c4d60b340d2dd0517a	https://github.com/Linan2018/Informer2020/tree/30e63a7d3ed9310b917b05c4d60b340d2dd0517a
LT	import torch class LT(torch.nn.Module): def __init__(self): super(LT, self).__init__() def forward(self, x, y): return x < y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_lt_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 < tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_lt_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class LTNew(torch.nn.Module): def __init__(self): super(LTNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	LT	false	2,515	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
FFN	import torch import torch.utils.data import torchvision.transforms.functional as F import torch.nn as nn import torch.nn.functional as F class FFN(nn.Module): def __init__(self, d_model, d_ffn, dropout=0): super().__init__() self.linear1 = nn.Linear(d_model, d_ffn) self.activation = F.relu self.dropout1 = nn.Dropout(dropout) self.linear2 = nn.Linear(d_ffn, d_model) self.dropout2 = nn.Dropout(dropout) self.norm = nn.LayerNorm(d_model) def forward(self, tgt): tgt2 = self.linear2(self.dropout1(self.activation(self.linear1(tgt)))) tgt = tgt + self.dropout2(tgt2) tgt = self.norm(tgt) return tgt def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'d_model': 4, 'd_ffn': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import torch.utils.data import torchvision.transforms.functional as F import torch.nn as nn import torch.nn.functional as F assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_relu_threshold_backward_0(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) @triton.jit def triton_poi_fused_add_native_layer_norm_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp12 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp9 = tmp7 + tmp8 tmp10 = tmp6 + tmp9 tmp13 = tmp11 + tmp12 tmp14 = tmp10 + tmp13 tmp15 = 4.0 tmp16 = tmp14 / tmp15 tmp17 = tmp2 - tmp16 tmp18 = tmp17 * tmp17 tmp19 = tmp5 - tmp16 tmp20 = tmp19 * tmp19 tmp21 = tmp18 + tmp20 tmp22 = tmp9 - tmp16 tmp23 = tmp22 * tmp22 tmp24 = tmp21 + tmp23 tmp25 = tmp13 - tmp16 tmp26 = tmp25 * tmp25 tmp27 = tmp24 + tmp26 tmp28 = tmp27 / tmp15 tl.store(out_ptr0 + x0, tmp16, xmask) tl.store(out_ptr1 + x0, tmp28, xmask) @triton.jit def triton_poi_fused_add_native_layer_norm_2(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + x2, xmask) tmp3 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr3 + x1, xmask, eviction_policy='evict_last') tmp10 = tl.load(in_ptr4 + x0, xmask, eviction_policy='evict_last') tmp12 = tl.load(in_ptr5 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp6 = 1e-05 tmp7 = tmp5 + tmp6 tmp8 = libdevice.rsqrt(tmp7) tmp9 = tmp4 * tmp8 tmp11 = tmp9 * tmp10 tmp13 = tmp11 + tmp12 tl.store(out_ptr0 + x2, tmp13, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 buf6 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf1, primals_2, buf6, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, reinterpret_tensor(buf1, (64, 4), ( 4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_5 buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf4 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused_add_native_layer_norm_1[grid(64)](primals_3, buf2, buf3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_native_layer_norm_2[grid(256)](primals_3, buf2, buf3, buf4, primals_6, primals_7, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf3 del buf4 del primals_7 return buf5, primals_3, primals_6, reinterpret_tensor(buf1, (64, 4), (4, 1), 0), buf2, primals_4, buf6 class FFNNew(nn.Module): def __init__(self, d_model, d_ffn, dropout=0): super().__init__() self.linear1 = nn.Linear(d_model, d_ffn) self.activation = F.relu self.dropout1 = nn.Dropout(dropout) self.linear2 = nn.Linear(d_ffn, d_model) self.dropout2 = nn.Dropout(dropout) self.norm = nn.LayerNorm(d_model) def forward(self, input_0): primals_1 = self.linear1.weight primals_2 = self.linear1.bias primals_4 = self.linear2.weight primals_5 = self.linear2.bias primals_6 = self.norm.weight primals_7 = self.norm.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]	Anonymous1376/MOTR	FFN	false	2,516	[ "Apache-2.0" ]	804cac1a22068af8a8ae127eead8399026d07419	https://github.com/Anonymous1376/MOTR/tree/804cac1a22068af8a8ae127eead8399026d07419
MConnBlock	import torch import torch.nn as nn import torch.nn.functional as F import torch.cuda import torch.distributed class MConn(nn.Module): """ My custom connection module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConn, self).__init__() self.linear1 = nn.Linear(_dim_1, _dim_2) self.linear2 = nn.Linear(_dim_2, _dim_3) if not _linear: self.linearw = nn.Linear(_dim_1, _dim_3) self.USE_RS = True else: self.USE_RS = False if _ln_size is not None: self.layer_norm = nn.LayerNorm(_ln_size) self.USE_LN = True else: self.USE_LN = False def forward(self, _input): _output = self.linear2(F.leaky_relu(F.dropout(self.linear1(_input), p=0.3), inplace=True)) if self.USE_RS: output = F.dropout(self.linearw(_input), p=0.3) return self.layer_norm(_output + output ) if self.USE_LN else _output + output else: return self.layer_norm(_output) if self.USE_LN else _output class MConnBlock(nn.Module): """ My custom connection block module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConnBlock, self).__init__() _mid_ln_size = (_ln_size[0], _dim_2) if _ln_size else None self.MConn1 = MConn(_dim_1, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn6 = MConn(_dim_2, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn7 = MConn(_dim_2, _dim_2, _dim_3, _linear, _ln_size) def forward(self, _input): _output = self.MConn1(_input) _output = self.MConn6(_output) _output = self.MConn7(_output) return _output def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'_dim_1': 4, '_dim_2': 4, '_dim_3': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.functional as F import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_leaky_relu_leaky_relu_backward_0(in_out_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_out_ptr0 + x0, xmask) tmp1 = 0.0 tmp2 = tmp0 > tmp1 tmp3 = 0.01 tmp4 = tmp0 * tmp3 tmp5 = tl.where(tmp2, tmp0, tmp4) tmp6 = tmp5 > tmp1 tl.store(in_out_ptr0 + x0, tmp5, xmask) tl.store(out_ptr0 + x0, tmp6, xmask) @triton.jit def triton_poi_fused_add_1(in_out_ptr0, in_ptr0, in_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tl.store(in_out_ptr0 + x2, tmp4, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13, primals_14, primals_15, primals_16, primals_17, primals_18, primals_19) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 4), (4, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (4, 4), (4, 1)) assert_size_stride(primals_11, (4,), (1,)) assert_size_stride(primals_12, (4, 4), (4, 1)) assert_size_stride(primals_13, (4,), (1,)) assert_size_stride(primals_14, (4, 4), (4, 1)) assert_size_stride(primals_15, (4,), (1,)) assert_size_stride(primals_16, (4, 4), (4, 1)) assert_size_stride(primals_17, (4,), (1,)) assert_size_stride(primals_18, (4, 4), (4, 1)) assert_size_stride(primals_19, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf0) del primals_1 del primals_2 buf1 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf2 = buf1[0] buf3 = buf1[1] del buf1 buf4 = buf2 del buf2 buf35 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf4, buf35, 256, XBLOCK=128, num_warps=4, num_stages=1) buf5 = buf0 del buf0 extern_kernels.mm(reinterpret_tensor(buf4, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf5) buf6 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf6) del primals_6 del primals_7 buf7 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf6, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf8 = buf7[0] buf9 = buf7[1] del buf7 buf10 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused_add_1[grid(256)](buf10, primals_5, buf8, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_5 buf11 = reinterpret_tensor(buf8, (64, 4), (4, 1), 0) del buf8 extern_kernels.addmm(primals_9, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), reinterpret_tensor(primals_8, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf11) del primals_9 buf12 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf11, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf13 = buf12[0] buf14 = buf12[1] del buf12 buf15 = buf13 del buf13 buf34 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf15, buf34, 256, XBLOCK=128, num_warps=4, num_stages=1) buf16 = buf11 del buf11 extern_kernels.mm(reinterpret_tensor(buf15, (64, 4), (4, 1), 0), reinterpret_tensor(primals_10, (4, 4), (1, 4), 0), out=buf16) buf17 = buf6 del buf6 extern_kernels.addmm(primals_13, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), reinterpret_tensor(primals_12, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf17) del primals_13 buf18 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf17, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf19 = buf18[0] buf20 = buf18[1] del buf18 buf21 = reinterpret_tensor(buf16, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf16 triton_poi_fused_add_1[grid(256)](buf21, primals_11, buf19, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_11 buf22 = reinterpret_tensor(buf19, (64, 4), (4, 1), 0) del buf19 extern_kernels.addmm(primals_15, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), reinterpret_tensor(primals_14, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf22) del primals_15 buf23 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf22, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf24 = buf23[0] buf25 = buf23[1] del buf23 buf26 = buf24 del buf24 buf33 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf26, buf33, 256, XBLOCK=128, num_warps=4, num_stages=1) buf27 = buf22 del buf22 extern_kernels.mm(reinterpret_tensor(buf26, (64, 4), (4, 1), 0), reinterpret_tensor(primals_16, (4, 4), (1, 4), 0), out=buf27) buf28 = buf17 del buf17 extern_kernels.addmm(primals_19, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), reinterpret_tensor(primals_18, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf28) del primals_19 buf29 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf28, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) del buf28 buf30 = buf29[0] buf31 = buf29[1] del buf29 buf32 = reinterpret_tensor(buf27, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf27 triton_poi_fused_add_1[grid(256)](buf32, primals_17, buf30, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf30 del primals_17 return (buf32, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), buf3, reinterpret_tensor(buf4, (64, 4), (4, 1), 0), buf9, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), buf14, reinterpret_tensor(buf15, (64, 4), (4, 1), 0), buf20, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), buf25, reinterpret_tensor(buf26, (64, 4), (4, 1), 0), buf31, primals_18, primals_16, buf33, primals_14, primals_12, primals_10, buf34, primals_8, primals_4, buf35) class MConn(nn.Module): """ My custom connection module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConn, self).__init__() self.linear1 = nn.Linear(_dim_1, _dim_2) self.linear2 = nn.Linear(_dim_2, _dim_3) if not _linear: self.linearw = nn.Linear(_dim_1, _dim_3) self.USE_RS = True else: self.USE_RS = False if _ln_size is not None: self.layer_norm = nn.LayerNorm(_ln_size) self.USE_LN = True else: self.USE_LN = False def forward(self, _input): _output = self.linear2(F.leaky_relu(F.dropout(self.linear1(_input), p=0.3), inplace=True)) if self.USE_RS: output = F.dropout(self.linearw(_input), p=0.3) return self.layer_norm(_output + output ) if self.USE_LN else _output + output else: return self.layer_norm(_output) if self.USE_LN else _output class MConnBlockNew(nn.Module): """ My custom connection block module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConnBlockNew, self).__init__() _mid_ln_size = (_ln_size[0], _dim_2) if _ln_size else None self.MConn1 = MConn(_dim_1, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn6 = MConn(_dim_2, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn7 = MConn(_dim_2, _dim_2, _dim_3, _linear, _ln_size) def forward(self, input_0): primals_1 = self.MConn1.linear1.weight primals_2 = self.MConn1.linear1.bias primals_4 = self.MConn1.linear2.weight primals_5 = self.MConn1.linear2.bias primals_6 = self.MConn1.linearw.weight primals_7 = self.MConn1.linearw.bias primals_8 = self.MConn6.linear1.weight primals_9 = self.MConn6.linear1.bias primals_10 = self.MConn6.linear2.weight primals_11 = self.MConn6.linear2.bias primals_12 = self.MConn6.linearw.weight primals_13 = self.MConn6.linearw.bias primals_14 = self.MConn7.linear1.weight primals_15 = self.MConn7.linear1.bias primals_16 = self.MConn7.linear2.weight primals_17 = self.MConn7.linear2.bias primals_18 = self.MConn7.linearw.weight primals_19 = self.MConn7.linearw.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13, primals_14, primals_15, primals_16, primals_17, primals_18, primals_19]) return output[0]	LeeeeoLiu/OpenNMT-py	MConnBlock	false	2,517	[ "MIT" ]	9be3a8951e9181aabe5440e4ea98173b7e749b5c	https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c
IMul	import torch class IMul(torch.nn.Module): def __init__(self): super(IMul, self).__init__() def forward(self, x, y): x *= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IMulNew(torch.nn.Module): def __init__(self): super(IMulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	IMul	false	2,518	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
SoftGeneratorAttention	import torch import torch.nn.functional as F import torch.nn as nn class SoftGeneratorAttention(nn.Module): def __init__(self): nn.Module.__init__(self) def apply_bn(self, x): bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, key, x): attn = torch.mul(key, x).sum(dim=1) attn = F.softmax(attn) return attn def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_sum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 16 x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 64 * x1), xmask) tmp1 = tl.load(in_ptr1 + (x0 + 64 * x1), xmask) tmp3 = tl.load(in_ptr0 + (16 + x0 + 64 * x1), xmask) tmp4 = tl.load(in_ptr1 + (16 + x0 + 64 * x1), xmask) tmp7 = tl.load(in_ptr0 + (32 + x0 + 64 * x1), xmask) tmp8 = tl.load(in_ptr1 + (32 + x0 + 64 * x1), xmask) tmp11 = tl.load(in_ptr0 + (48 + x0 + 64 * x1), xmask) tmp12 = tl.load(in_ptr1 + (48 + x0 + 64 * x1), xmask) tmp2 = tmp0 * tmp1 tmp5 = tmp3 * tmp4 tmp6 = tmp2 + tmp5 tmp9 = tmp7 * tmp8 tmp10 = tmp6 + tmp9 tmp13 = tmp11 * tmp12 tmp14 = tmp10 + tmp13 tl.store(out_ptr0 + x2, tmp14, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 16 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 16 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_sum_0[grid(64)](arg1_1, arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 del arg1_1 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(64)](buf0, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = buf0 del buf0 triton_poi_fused__softmax_2[grid(64)](buf1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf1 return buf2, class SoftGeneratorAttentionNew(nn.Module): def __init__(self): nn.Module.__init__(self) def apply_bn(self, x): bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	LinChen-65/pygcn	SoftGeneratorAttention	false	2,519	[ "MIT" ]	0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb	https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb
FloorDivConst	import torch class FloorDivConst(torch.nn.Module): def __init__(self): super(FloorDivConst, self).__init__() def forward(self, x): return x // 2.0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class FloorDivConstNew(torch.nn.Module): def __init__(self): super(FloorDivConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	FloorDivConst	false	2,520	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
DownBlock	import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class DownBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(DownBlock, self).__init__() self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): l0 = self.down_conv1(x) h0 = self.down_conv2(l0) l1 = self.down_conv3(h0 - x) return l1 + l0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10) = args args.clear() assert_size_stride(primals_1, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 1, 1), (4, 1, 1, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(16)](buf1, primals_2, primals_4, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 4, 4), (64, 16, 4, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_1[grid(256)](buf4, primals_6, primals_7, primals_3, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 1, 1), (4, 1, 1, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_add_convolution_2[grid(16)](buf7, primals_9, primals_10, buf2, buf8, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_9 return (buf8, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, buf1, buf2, buf4, buf5, buf7) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class DownBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(DownBlockNew, self).__init__() self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.down_conv1.conv.weight primals_2 = self.down_conv1.conv.bias primals_4 = self.down_conv1.act.weight primals_5 = self.down_conv2.deconv.weight primals_6 = self.down_conv2.deconv.bias primals_7 = self.down_conv2.act.weight primals_8 = self.down_conv3.conv.weight primals_9 = self.down_conv3.conv.bias primals_10 = self.down_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10]) return output[0]	DengZeshuai/DBPN-Pytorch	DownBlock	false	2,521	[ "MIT" ]	a90d241a1c4b07830c6d812ad8389d13e8cf05d1	https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1
EQ	import torch class EQ(torch.nn.Module): def __init__(self): super(EQ, self).__init__() def forward(self, x, y): return x == y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_eq_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 == tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_eq_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class EQNew(torch.nn.Module): def __init__(self): super(EQNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	EQ	false	2,522	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
MaxElementwise	import torch class MaxElementwise(torch.nn.Module): def forward(self, x, y): return torch.max(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_maximum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = triton_helpers.maximum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_maximum_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MaxElementwiseNew(torch.nn.Module): def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	MaxElementwise	false	2,523	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
Clone	import torch class Clone(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): return x.clone() def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tl.store(out_ptr0 + x0, tmp0, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class CloneNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	Clone	false	2,524	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
FloorDivAssign	import torch class FloorDivAssign(torch.nn.Module): def __init__(self): super(FloorDivAssign, self).__init__() def forward(self, x, y): x //= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr1 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class FloorDivAssignNew(torch.nn.Module): def __init__(self): super(FloorDivAssignNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	FloorDivAssign	false	2,525	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TripletSoftmaxLoss	import torch import torch.nn as nn import torch.nn.functional as F class TripletSoftmaxLoss(nn.Module): def __init__(self, margin=0.0, lambda_factor=0.01): super(TripletSoftmaxLoss, self).__init__() self.margin = margin self.loss_fn = nn.CrossEntropyLoss() self.lambda_factor = lambda_factor def forward(self, anchor, positive, negative, outputs, labels): distance_positive = torch.abs(anchor - positive).sum(1) distance_negative = torch.abs(anchor - negative).sum(1) losses = F.relu(distance_positive - distance_negative + self.margin) loss_softmax = self.loss_fn(input=outputs, target=labels) loss_total = self.lambda_factor * losses.sum() + loss_softmax return loss_total, losses.sum(), loss_softmax def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_abs_add_relu_sub_sum_0(in_ptr0, in_ptr1, in_ptr2, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex % 16 r1 = rindex // 16 tmp0 = tl.load(in_ptr0 + (r0 + 64 * r1), None) tmp1 = tl.load(in_ptr1 + (r0 + 64 * r1), None) tmp4 = tl.load(in_ptr0 + (16 + r0 + 64 * r1), None) tmp5 = tl.load(in_ptr1 + (16 + r0 + 64 * r1), None) tmp9 = tl.load(in_ptr0 + (32 + r0 + 64 * r1), None) tmp10 = tl.load(in_ptr1 + (32 + r0 + 64 * r1), None) tmp14 = tl.load(in_ptr0 + (48 + r0 + 64 * r1), None) tmp15 = tl.load(in_ptr1 + (48 + r0 + 64 * r1), None) tmp19 = tl.load(in_ptr2 + (r0 + 64 * r1), None) tmp22 = tl.load(in_ptr2 + (16 + r0 + 64 * r1), None) tmp26 = tl.load(in_ptr2 + (32 + r0 + 64 * r1), None) tmp30 = tl.load(in_ptr2 + (48 + r0 + 64 * r1), None) tmp2 = tmp0 - tmp1 tmp3 = tl_math.abs(tmp2) tmp6 = tmp4 - tmp5 tmp7 = tl_math.abs(tmp6) tmp8 = tmp3 + tmp7 tmp11 = tmp9 - tmp10 tmp12 = tl_math.abs(tmp11) tmp13 = tmp8 + tmp12 tmp16 = tmp14 - tmp15 tmp17 = tl_math.abs(tmp16) tmp18 = tmp13 + tmp17 tmp20 = tmp0 - tmp19 tmp21 = tl_math.abs(tmp20) tmp23 = tmp4 - tmp22 tmp24 = tl_math.abs(tmp23) tmp25 = tmp21 + tmp24 tmp27 = tmp9 - tmp26 tmp28 = tl_math.abs(tmp27) tmp29 = tmp25 + tmp28 tmp31 = tmp14 - tmp30 tmp32 = tl_math.abs(tmp31) tmp33 = tmp29 + tmp32 tmp34 = tmp18 - tmp33 tmp35 = 0.0 tmp36 = tmp34 + tmp35 tmp37 = tl.full([1, 1], 0, tl.int32) tmp38 = triton_helpers.maximum(tmp37, tmp36) tmp39 = tl.broadcast_to(tmp38, [XBLOCK, RBLOCK]) tmp41 = tl.sum(tmp39, 1)[:, None] tl.store(out_ptr1 + tl.full([XBLOCK, 1], 0, tl.int32), tmp41, None) tl.store(out_ptr2 + tl.full([XBLOCK, 1], 0, tl.int32), tmp41, None) @triton.jit def triton_poi_fused__log_softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_per_fused__log_softmax_add_div_mul_neg_sum_2(in_out_ptr0, in_out_ptr1, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r3 = rindex r0 = rindex % 16 r2 = rindex // 64 tmp0 = tl.load(in_ptr0 + r3, None) tmp1 = tl.load(in_ptr0 + (r0 + 64 * r2), None, eviction_policy='evict_last' ) tmp3 = tl.load(in_ptr0 + (16 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (32 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp9 = tl.load(in_ptr0 + (48 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp14 = tl.load(in_ptr1 + r3, None) tmp22 = tl.load(in_out_ptr1 + 0) tmp23 = tl.broadcast_to(tmp22, [1]) tmp2 = tl_math.exp(tmp1) tmp4 = tl_math.exp(tmp3) tmp5 = tmp2 + tmp4 tmp7 = tl_math.exp(tmp6) tmp8 = tmp5 + tmp7 tmp10 = tl_math.exp(tmp9) tmp11 = tmp8 + tmp10 tmp12 = tl_math.log(tmp11) tmp13 = tmp0 - tmp12 tmp15 = tmp13 * tmp14 tmp16 = tl.broadcast_to(tmp15, [RBLOCK]) tmp18 = triton_helpers.promote_to_tensor(tl.sum(tmp16, 0)) tmp19 = -tmp18 tmp20 = 0.015625 tmp21 = tmp19 * tmp20 tmp24 = 0.01 tmp25 = tmp23 * tmp24 tmp26 = tmp25 + tmp21 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp21, None) tl.debug_barrier() tl.store(in_out_ptr1 + tl.full([1], 0, tl.int32), tmp26, None) def call(args): arg0_1, arg1_1, arg2_1, arg3_1, arg4_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg3_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg4_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf1 = empty_strided_cuda((), (), torch.float32) buf5 = empty_strided_cuda((), (), torch.float32) get_raw_stream(0) triton_per_fused_abs_add_relu_sub_sum_0[grid(1)](arg0_1, arg1_1, arg2_1, buf1, buf5, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax_1[grid(256)](arg4_1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg4_1 buf3 = empty_strided_cuda((), (), torch.float32) buf4 = buf3 del buf3 buf6 = buf1 del buf1 triton_per_fused__log_softmax_add_div_mul_neg_sum_2[grid(1)](buf4, buf6, buf2, arg3_1, 1, 256, num_warps=2, num_stages=1) del arg3_1 del buf2 return buf6, buf5, buf4 class TripletSoftmaxLossNew(nn.Module): def __init__(self, margin=0.0, lambda_factor=0.01): super(TripletSoftmaxLossNew, self).__init__() self.margin = margin self.loss_fn = nn.CrossEntropyLoss() self.lambda_factor = lambda_factor def forward(self, input_0, input_1, input_2, input_3, input_4): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 arg3_1 = input_3 arg4_1 = input_4 output = call([arg0_1, arg1_1, arg2_1, arg3_1, arg4_1]) return output[0], output[1], output[2]	Lm0079/MetricLearningIdentification	TripletSoftmaxLoss	false	2,526	[ "MIT" ]	3c2c0512fe2fbbb6aacb958106d5f6a03baedc35	https://github.com/Lm0079/MetricLearningIdentification/tree/3c2c0512fe2fbbb6aacb958106d5f6a03baedc35
FloorDiv	import torch class FloorDiv(torch.nn.Module): def __init__(self): super(FloorDiv, self).__init__() def forward(self, x, y): return x // y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class FloorDivNew(torch.nn.Module): def __init__(self): super(FloorDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	FloorDiv	false	2,527	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
SoftGeneratorPoolMLP	import torch import torch.nn.functional as F import torch.nn as nn from torch.nn import Linear class SoftGeneratorPoolMLP(nn.Module): def __init__(self, nin, nhid1, nhid2, nout=1, bias=True): nn.Module.__init__(self) self.bias = bias self.linear1 = Linear(nin, nhid1, bias=self.bias) self.linear2 = Linear(nhid1, nhid2, bias=self.bias) self.linear3 = Linear(nhid2, nin, bias=self.bias) """ def apply_bn(self, x): # Batch normalization of 3D tensor x bn_module = nn.BatchNorm1d(x.size()).cuda() return bn_module(x) """ def forward(self, x): x = torch.mean(x, dim=0).unsqueeze(0) x = F.relu(self.linear1(x)) x = F.relu(self.linear2(x)) x = self.linear3(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'nin': 4, 'nhid1': 4, 'nhid2': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn from torch.nn import Linear assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mean_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr0 + (64 + x0), xmask) tmp3 = tl.load(in_ptr0 + (128 + x0), xmask) tmp5 = tl.load(in_ptr0 + (192 + x0), xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tl.store(out_ptr0 + x0, tmp8, xmask) @triton.jit def triton_poi_fused_relu_threshold_backward_1(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mean_0[grid(64)](primals_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_1 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf0, (16, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = reinterpret_tensor(buf1, (1, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 buf7 = empty_strided_cuda((1, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(64)](buf2, primals_3, buf7, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_3 buf3 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf2, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf3) buf4 = reinterpret_tensor(buf3, (1, 4, 4, 4), (64, 16, 4, 1), 0) del buf3 buf6 = empty_strided_cuda((1, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(64)](buf4, primals_5, buf6, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_5 buf5 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, reinterpret_tensor(buf4, (16, 4), ( 4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf5) del primals_7 return reinterpret_tensor(buf5, (1, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(buf0, (16, 4), (4, 1), 0), reinterpret_tensor( buf2, (16, 4), (4, 1), 0), reinterpret_tensor(buf4, (16, 4), (4, 1), 0 ), primals_6, buf6, primals_4, buf7 class SoftGeneratorPoolMLPNew(nn.Module): def __init__(self, nin, nhid1, nhid2, nout=1, bias=True): nn.Module.__init__(self) self.bias = bias self.linear1 = Linear(nin, nhid1, bias=self.bias) self.linear2 = Linear(nhid1, nhid2, bias=self.bias) self.linear3 = Linear(nhid2, nin, bias=self.bias) """ def apply_bn(self, x): # Batch normalization of 3D tensor x bn_module = nn.BatchNorm1d(x.size()).cuda() return bn_module(x) """ def forward(self, input_0): primals_2 = self.linear1.weight primals_3 = self.linear1.bias primals_4 = self.linear2.weight primals_5 = self.linear2.bias primals_6 = self.linear3.weight primals_7 = self.linear3.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]	LinChen-65/pygcn	SoftGeneratorPoolMLP	false	2,528	[ "MIT" ]	0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb	https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb
IDiv	import torch class IDiv(torch.nn.Module): def __init__(self): super(IDiv, self).__init__() def forward(self, x, y): x /= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IDivNew(torch.nn.Module): def __init__(self): super(IDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	IDiv	false	2,529	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
IAdd	import torch class IAdd(torch.nn.Module): def __init__(self): super(IAdd, self).__init__() def forward(self, x, y): x += y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_add_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IAddNew(torch.nn.Module): def __init__(self): super(IAddNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	IAdd	false	2,530	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TensorClamp	import torch class TensorClamp(torch.nn.Module): def forward(self, x): return x.clamp(-0.1, 0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = -0.1 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = 0.1 tmp4 = triton_helpers.minimum(tmp2, tmp3) tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	TensorClamp	false	2,531	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
MaxPool1D	import torch class MaxPool1D(torch.nn.Module): def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False): super().__init__() self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode def forward(self, x): return torch.nn.functional.max_pool1d(x, self.kernel_size, stride= self.stride, padding=self.padding, ceil_mode=self.ceil_mode) def get_inputs(): return [torch.rand([4, 4])] def get_init_inputs(): return [[], {'kernel_size': 4}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_max_pool2d_with_indices_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last') tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tl.store(out_ptr0 + x0, tmp6, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 1), (1, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused_max_pool2d_with_indices_0[grid(4)](arg0_1, buf0, 4, XBLOCK=4, num_warps=1, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 1), (1, 1), 0), class MaxPool1DNew(torch.nn.Module): def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False): super().__init__() self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	MaxPool1D	false	2,532	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TensorClampMin	import torch class TensorClampMin(torch.nn.Module): def forward(self, x): return x.clamp_min(-0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_min_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = -0.1 tmp2 = triton_helpers.maximum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_min_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampMinNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	TensorClampMin	false	2,533	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
Pow	import torch class Pow(torch.nn.Module): def __init__(self): super(Pow, self).__init__() def forward(self, x, y): return x ** y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.pow(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class PowNew(torch.nn.Module): def __init__(self): super(PowNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	Pow	false	2,534	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
GT	import torch class GT(torch.nn.Module): def __init__(self): super(GT, self).__init__() def forward(self, x, y): return x > y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_gt_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 > tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_gt_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class GTNew(torch.nn.Module): def __init__(self): super(GTNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	GT	false	2,535	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RpowFloat	import torch class RpowFloat(torch.nn.Module): def __init__(self): super(RpowFloat, self).__init__() def forward(self, x): return 2.0 ** x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = libdevice.exp2(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RpowFloatNew(torch.nn.Module): def __init__(self): super(RpowFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RpowFloat	false	2,536	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
ModConst	import torch class ModConst(torch.nn.Module): def __init__(self): super(ModConst, self).__init__() def forward(self, x): return x % 2.0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_remainder_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 2.0 tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr0 + x0, tmp10, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class ModConstNew(torch.nn.Module): def __init__(self): super(ModConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	ModConst	false	2,537	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
MinElementwise	import torch class MinElementwise(torch.nn.Module): def forward(self, x, y): return torch.min(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_minimum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = triton_helpers.minimum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_minimum_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MinElementwiseNew(torch.nn.Module): def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	MinElementwise	false	2,538	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RDivFloat	import torch class RDivFloat(torch.nn.Module): def __init__(self): super(RDivFloat, self).__init__() def forward(self, x): return 100.0 / x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_reciprocal_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.full([1], 1, tl.int32) tmp2 = tmp1 / tmp0 tmp3 = 100.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_reciprocal_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RDivFloatNew(torch.nn.Module): def __init__(self): super(RDivFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RDivFloat	false	2,539	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TensorSigmoid	import torch class TensorSigmoid(torch.nn.Module): def __init__(self): super(TensorSigmoid, self).__init__() def forward(self, x): return x.sigmoid() def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sigmoid_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sigmoid_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorSigmoidNew(torch.nn.Module): def __init__(self): super(TensorSigmoidNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	TensorSigmoid	false	2,540	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RpowInt	import torch class RpowInt(torch.nn.Module): def __init__(self): super(RpowInt, self).__init__() def forward(self, x): return 2 ** x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = libdevice.exp2(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RpowIntNew(torch.nn.Module): def __init__(self): super(RpowIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RpowInt	false	2,541	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
FunctionalConv3d	import torch class FunctionalConv3d(torch.nn.Module): def __init__(self, args, kwargs): super().__init__() self.conv = torch.nn.Conv3d(args, **kwargs) def forward(self, x): x = torch.nn.functional.conv3d(x, self.conv.weight, self.conv.bias, self.conv.stride, self.conv.padding, self.conv.dilation, self. conv.groups) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4, 'kernel_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_out_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4, 4), (256, 64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(reinterpret_tensor(primals_3, (1, 4, 4, 4, 4), (256, 64, 16, 4, 1), 0), primals_1, stride=(1, 1, 1), padding=(0, 0, 0), dilation=(1, 1, 1), transposed=False, output_padding=(0, 0, 0), groups=1, bias=None) assert_size_stride(buf0, (1, 4, 1, 1, 1), (4, 1, 1, 1, 1)) buf1 = reinterpret_tensor(buf0, (1, 4, 1, 1, 1), (4, 1, 4, 4, 4), 0) del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(4)](buf1, primals_2, 4, XBLOCK= 4, num_warps=1, num_stages=1) del primals_2 return reinterpret_tensor(buf1, (4, 1, 1, 1), (1, 1, 1, 1), 0 ), primals_1, reinterpret_tensor(primals_3, (1, 4, 4, 4, 4), (256, 64, 16, 4, 1), 0) class FunctionalConv3dNew(torch.nn.Module): def __init__(self, args, kwargs): super().__init__() self.conv = torch.nn.Conv3d(args, **kwargs) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	Ilyabasharov/torch2trt	FunctionalConv3d	false	2,542	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
PositionwiseFeedForward	import torch from torch import nn import torch.nn.functional as F class PositionwiseFeedForward(nn.Module): """ a　two layer feed forward""" def __init__(self, model_dim=512, ffn_dim=2048, dropout=0.1): super(PositionwiseFeedForward, self).__init__() self.w1 = nn.Conv1d(model_dim, ffn_dim, 1) self.w2 = nn.Conv1d(ffn_dim, model_dim, 1) self.layer_norm = nn.LayerNorm(model_dim) self.dropout = nn.Dropout(dropout) def forward(self, x): residual = x output = x.transpose(1, 2) output = self.w2(F.relu(self.w1(output))) output = self.dropout(output.transpose(1, 2)) output = self.layer_norm(residual + output) return output def get_inputs(): return [torch.rand([4, 512, 512])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 512 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y0 = yindex % 512 y1 = yindex // 512 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 512 * x2 + 262144 * y1), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 512 * y3), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_relu_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 512 % 2048 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x3, tmp4, None) @triton.jit def triton_poi_fused_convolution_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 512 % 512 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_red_fused_add_native_layer_norm_3(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr, RBLOCK: tl. constexpr): rnumel = 128 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rbase = tl.arange(0, RBLOCK)[None, :] x4 = xindex x0 = xindex % 4 x1 = xindex // 4 % 512 x2 = xindex // 2048 tmp4_mean = tl.zeros([XBLOCK, RBLOCK], tl.float32) tmp4_m2 = tl.zeros([XBLOCK, RBLOCK], tl.float32) tmp4_weight = tl.zeros([XBLOCK, RBLOCK], tl.float32) for roffset in range(0, rnumel, RBLOCK): rindex = roffset + rbase rmask = rindex < rnumel r3 = rindex tmp0 = tl.load(in_ptr0 + (r3 + 128 * x4), rmask, eviction_policy= 'evict_first', other=0.0) tmp1 = tl.load(in_ptr1 + (x1 + 512 * r3 + 65536 * x0 + 262144 * x2), rmask, eviction_policy='evict_last', other=0.0) tmp2 = tmp0 + tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp4_mean_next, tmp4_m2_next, tmp4_weight_next = (triton_helpers. welford_reduce(tmp3, tmp4_mean, tmp4_m2, tmp4_weight, roffset == 0) ) tmp4_mean = tl.where(rmask, tmp4_mean_next, tmp4_mean) tmp4_m2 = tl.where(rmask, tmp4_m2_next, tmp4_m2) tmp4_weight = tl.where(rmask, tmp4_weight_next, tmp4_weight) tmp4_tmp, tmp5_tmp, tmp6_tmp = triton_helpers.welford(tmp4_mean, tmp4_m2, tmp4_weight, 1) tmp4 = tmp4_tmp[:, None] tmp5 = tmp5_tmp[:, None] tmp6 = tmp6_tmp[:, None] tl.store(out_ptr0 + x4, tmp4, None) tl.store(out_ptr1 + x4, tmp5, None) tl.store(out_ptr2 + x4, tmp6, None) @triton.jit def triton_per_fused_add_native_layer_norm_4(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 4 * x0), None) tmp1 = tl.load(in_ptr1 + (r1 + 4 * x0), None) tmp2 = tl.load(in_ptr2 + (r1 + 4 * x0), None) tmp3 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp4 = tl.broadcast_to(tmp1, [XBLOCK, RBLOCK]) tmp5 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp7, tmp8, tmp9 = triton_helpers.welford(tmp3, tmp4, tmp5, 1) tmp10 = tmp7[:, None] tmp11 = tmp8[:, None] tmp9[:, None] tmp13 = 512.0 tmp14 = tmp11 / tmp13 tmp15 = 1e-05 tmp16 = tmp14 + tmp15 tmp17 = libdevice.rsqrt(tmp16) tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp17, None) tl.store(out_ptr0 + x0, tmp10, None) @triton.jit def triton_poi_fused_add_native_layer_norm_5(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 512 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 512 y1 = yindex // 512 tmp0 = tl.load(in_ptr0 + (x2 + 512 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + (y0 + 512 * x2 + 262144 * y1), xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + y3, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr3 + y3, None, eviction_policy='evict_last') tmp7 = tl.load(in_ptr4 + x2, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr5 + x2, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp6 = tmp4 * tmp5 tmp8 = tmp6 * tmp7 tmp10 = tmp8 + tmp9 tl.store(out_ptr0 + (x2 + 512 * y3), tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 512, 512), (262144, 512, 1)) assert_size_stride(primals_2, (2048, 512, 1), (512, 1, 1)) assert_size_stride(primals_3, (2048,), (1,)) assert_size_stride(primals_4, (512, 2048, 1), (2048, 1, 1)) assert_size_stride(primals_5, (512,), (1,)) assert_size_stride(primals_6, (512,), (1,)) assert_size_stride(primals_7, (512,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 512, 512), (262144, 512, 1), torch. float32) get_raw_stream(0) triton_poi_fused_convolution_0[grid(2048, 512)](primals_1, buf0, 2048, 512, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf1, (4, 2048, 512), (1048576, 512, 1)) buf2 = buf1 del buf1 triton_poi_fused_convolution_relu_1[grid(4194304)](buf2, primals_3, 4194304, XBLOCK=1024, num_warps=4, num_stages=1) del primals_3 buf3 = extern_kernels.convolution(buf2, primals_4, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf3, (4, 512, 512), (262144, 512, 1)) buf4 = buf3 del buf3 triton_poi_fused_convolution_2[grid(1048576)](buf4, primals_5, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 buf5 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) buf6 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) buf7 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) triton_red_fused_add_native_layer_norm_3[grid(8192)](primals_1, buf4, buf5, buf6, buf7, 8192, 128, XBLOCK=64, RBLOCK=8, num_warps=4, num_stages=1) buf8 = empty_strided_cuda((4, 512, 1), (512, 1, 1), torch.float32) buf9 = empty_strided_cuda((4, 512, 1), (512, 1, 2048), torch.float32) buf11 = reinterpret_tensor(buf9, (4, 512, 1), (512, 1, 1), 0) del buf9 triton_per_fused_add_native_layer_norm_4[grid(2048)](buf11, buf5, buf6, buf7, buf8, 2048, 4, XBLOCK=128, num_warps=4, num_stages=1) del buf5 del buf6 del buf7 buf12 = buf0 del buf0 triton_poi_fused_add_native_layer_norm_5[grid(2048, 512)](primals_1, buf4, buf8, buf11, primals_6, primals_7, buf12, 2048, 512, XBLOCK=64, YBLOCK=64, num_warps=8, num_stages=1) del primals_7 return (buf12, primals_1, primals_2, primals_4, primals_6, buf2, buf4, buf8, buf11) class PositionwiseFeedForwardNew(nn.Module): """ a　two layer feed forward""" def __init__(self, model_dim=512, ffn_dim=2048, dropout=0.1): super(PositionwiseFeedForwardNew, self).__init__() self.w1 = nn.Conv1d(model_dim, ffn_dim, 1) self.w2 = nn.Conv1d(ffn_dim, model_dim, 1) self.layer_norm = nn.LayerNorm(model_dim) self.dropout = nn.Dropout(dropout) def forward(self, input_0): primals_2 = self.w1.weight primals_3 = self.w1.bias primals_4 = self.w2.weight primals_5 = self.w2.bias primals_6 = self.layer_norm.weight primals_7 = self.layer_norm.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]	LinXueyuanStdio/scRNN-seq	PositionwiseFeedForward	false	2,543	[ "Apache-2.0" ]	87e11a56acb18a86fa4fb309d33a1bc02bf38b39	https://github.com/LinXueyuanStdio/scRNN-seq/tree/87e11a56acb18a86fa4fb309d33a1bc02bf38b39
RSubInt	import torch class RSubInt(torch.nn.Module): def __init__(self): super(RSubInt, self).__init__() def forward(self, x): return 1 - x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_rsub_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_rsub_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RSubIntNew(torch.nn.Module): def __init__(self): super(RSubIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RSubInt	false	2,544	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
ISub	import torch class ISub(torch.nn.Module): def __init__(self): super(ISub, self).__init__() def forward(self, x, y): x -= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class ISubNew(torch.nn.Module): def __init__(self): super(ISubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	ISub	false	2,545	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
Sub	import torch class Sub(torch.nn.Module): def __init__(self): super(Sub, self).__init__() def forward(self, x, y): return x - y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class SubNew(torch.nn.Module): def __init__(self): super(SubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	Sub	false	2,546	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TensorClampMax	import torch class TensorClampMax(torch.nn.Module): def forward(self, x): return x.clamp_max(0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_max_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.1 tmp2 = triton_helpers.minimum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_max_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampMaxNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	TensorClampMax	false	2,547	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RAddFloat	import torch class RAddFloat(torch.nn.Module): def __init__(self): super(RAddFloat, self).__init__() def forward(self, x): return 1.0 + x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RAddFloatNew(torch.nn.Module): def __init__(self): super(RAddFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RAddFloat	false	2,548	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RMulInt	import torch class RMulInt(torch.nn.Module): def __init__(self): super(RMulInt, self).__init__() def forward(self, x): return 10 * x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 10.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RMulIntNew(torch.nn.Module): def __init__(self): super(RMulIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RMulInt	false	2,549	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
ModAssign	import torch class ModAssign(torch.nn.Module): def __init__(self): super(ModAssign, self).__init__() def forward(self, x, y): x %= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_remainder_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr1 + x0, tmp10, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class ModAssignNew(torch.nn.Module): def __init__(self): super(ModAssignNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	ModAssign	false	2,550	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RDivInt	import torch class RDivInt(torch.nn.Module): def __init__(self): super(RDivInt, self).__init__() def forward(self, x): return 100 / x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_reciprocal_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.full([1], 1, tl.int32) tmp2 = tmp1 / tmp0 tmp3 = 100.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_reciprocal_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RDivIntNew(torch.nn.Module): def __init__(self): super(RDivIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RDivInt	false	2,551	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
GeM	import torch import torch.nn as nn import torch.nn.functional as F import torch.nn.functional from torch.nn import Parameter from torch.nn.parameter import Parameter import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd class GeM(nn.Module): def __init__(self, p=3.0, eps=1e-06, freeze_p=True): super(GeM, self).__init__() self.p = p if freeze_p else Parameter(torch.ones(1) * p) self.eps = eps def forward(self, x): return F.adaptive_avg_pool2d(x.clamp(min=self.eps).pow(self.p), (1, 1) ).pow(1.0 / self.p) def __repr__(self): if isinstance(self.p, float): p = self.p else: p = self.p.data.tolist()[0] return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(p ) + ', ' + 'eps=' + str(self.eps) + ')' def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.nn.functional from torch.nn import Parameter from torch.nn.parameter import Parameter import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_per_fused_clamp_mean_pow_0(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 16 RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 16 * x0), xmask, other=0.0) tmp1 = 1e-06 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = tmp2 * tmp2 tmp4 = tmp3 * tmp2 tmp5 = tl.broadcast_to(tmp4, [XBLOCK, RBLOCK]) tmp7 = tl.where(xmask, tmp5, 0) tmp8 = tl.sum(tmp7, 1)[:, None] tmp9 = 16.0 tmp10 = tmp8 / tmp9 tmp11 = 0.3333333333333333 tmp12 = libdevice.pow(tmp10, tmp11) tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp12, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 16, 16), torch.float32) buf1 = reinterpret_tensor(buf0, (4, 4, 1, 1), (4, 1, 1, 1), 0) del buf0 get_raw_stream(0) triton_per_fused_clamp_mean_pow_0[grid(16)](buf1, arg0_1, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 return buf1, class GeMNew(nn.Module): def __init__(self, p=3.0, eps=1e-06, freeze_p=True): super(GeMNew, self).__init__() self.p = p if freeze_p else Parameter(torch.ones(1) * p) self.eps = eps def __repr__(self): if isinstance(self.p, float): p = self.p else: p = self.p.data.tolist()[0] return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(p ) + ', ' + 'eps=' + str(self.eps) + ')' def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Liuhongzhi2018/Person_ReID	GeM	false	2,552	[ "MIT" ]	51c576ed5b4ed960801669d6d59c0a77405b369d	https://github.com/Liuhongzhi2018/Person_ReID/tree/51c576ed5b4ed960801669d6d59c0a77405b369d
RMulFloat	import torch class RMulFloat(torch.nn.Module): def __init__(self): super(RMulFloat, self).__init__() def forward(self, x): return 10.0 * x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 10.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RMulFloatNew(torch.nn.Module): def __init__(self): super(RMulFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RMulFloat	false	2,553	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
NotEqual	import torch class NotEqual(torch.nn.Module): def __init__(self): super(NotEqual, self).__init__() def forward(self, x, y): return x != y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class NotEqualNew(torch.nn.Module): def __init__(self): super(NotEqualNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	NotEqual	false	2,554	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
D_DownBlock	import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class D_DownBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, num_stages=1, bias=True, activation='prelu', norm=None): super(D_DownBlock, self).__init__() self.conv = ConvBlock(num_filter * num_stages, num_filter, 1, 1, 0, activation, norm=None) self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): x = self.conv(x) l0 = self.down_conv1(x) h0 = self.down_conv2(l0) l1 = self.down_conv3(h0 - x) return l1 + l0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_1(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_3(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13) = args args.clear() assert_size_stride(primals_1, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) assert_size_stride(primals_11, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_12, (4,), (1,)) assert_size_stride(primals_13, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 4, 4), (64, 16, 4, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(256)](buf1, primals_2, primals_4, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 1, 1), (4, 1, 1, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_1[grid(16)](buf4, primals_6, primals_7, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 4, 4), (64, 16, 4, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_2[grid(256)](buf7, primals_9, primals_10, buf2, buf8, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_9 buf9 = extern_kernels.convolution(buf8, primals_11, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf9, (4, 4, 1, 1), (4, 1, 1, 1)) buf10 = buf9 del buf9 buf11 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_add_convolution_3[grid(16)](buf10, primals_12, primals_13, buf5, buf11, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_12 return (buf11, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, primals_11, primals_13, buf1, buf2, buf4, buf5, buf7, buf8, buf10) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class D_DownBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, num_stages=1, bias=True, activation='prelu', norm=None): super(D_DownBlockNew, self).__init__() self.conv = ConvBlock(num_filter * num_stages, num_filter, 1, 1, 0, activation, norm=None) self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.conv.conv.weight primals_2 = self.conv.conv.bias primals_4 = self.conv.act.weight primals_5 = self.down_conv1.conv.weight primals_6 = self.down_conv1.conv.bias primals_7 = self.down_conv1.act.weight primals_8 = self.down_conv2.deconv.weight primals_9 = self.down_conv2.deconv.bias primals_10 = self.down_conv2.act.weight primals_11 = self.down_conv3.conv.weight primals_12 = self.down_conv3.conv.bias primals_13 = self.down_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13]) return output[0]	DengZeshuai/DBPN-Pytorch	D_DownBlock	false	2,555	[ "MIT" ]	a90d241a1c4b07830c6d812ad8389d13e8cf05d1	https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1
NotEqualConst	import torch class NotEqualConst(torch.nn.Module): def __init__(self): super(NotEqualConst, self).__init__() def forward(self, x): return x != 13.62 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 13.62 tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class NotEqualConstNew(torch.nn.Module): def __init__(self): super(NotEqualConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	NotEqualConst	false	2,556	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchMod	import torch class TorchMod(torch.nn.Module): def __init__(self): super(TorchMod, self).__init__() def forward(self, x, y): return torch.fmod(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_fmod_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.fmod(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_fmod_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchModNew(torch.nn.Module): def __init__(self): super(TorchModNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchMod	false	2,557	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchFloorDiv	import torch class TorchFloorDiv(torch.nn.Module): def __init__(self): super(TorchFloorDiv, self).__init__() def forward(self, x, y): return torch.floor_divide(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchFloorDivNew(torch.nn.Module): def __init__(self): super(TorchFloorDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchFloorDiv	false	2,558	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchSub	import torch class TorchSub(torch.nn.Module): def __init__(self): super(TorchSub, self).__init__() def forward(self, x, y): return torch.sub(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchSubNew(torch.nn.Module): def __init__(self): super(TorchSubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchSub	false	2,559	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
RSubFloat	import torch class RSubFloat(torch.nn.Module): def __init__(self): super(RSubFloat, self).__init__() def forward(self, x): return 1.0 - x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_rsub_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_rsub_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RSubFloatNew(torch.nn.Module): def __init__(self): super(RSubFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Ilyabasharov/torch2trt	RSubFloat	false	2,560	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchMul	import torch class TorchMul(torch.nn.Module): def __init__(self): super(TorchMul, self).__init__() def forward(self, x, y): return torch.mul(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchMulNew(torch.nn.Module): def __init__(self): super(TorchMulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchMul	false	2,561	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchNotEqual	import torch class TorchNotEqual(torch.nn.Module): def __init__(self): super(TorchNotEqual, self).__init__() def forward(self, x, y): return torch.ne(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchNotEqualNew(torch.nn.Module): def __init__(self): super(TorchNotEqualNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchNotEqual	false	2,562	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
Upsampler	import math import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class Upsampler(torch.nn.Module): def __init__(self, scale, n_feat, bn=False, act='prelu', bias=True): super(Upsampler, self).__init__() modules = [] for _ in range(int(math.log(scale, 2))): modules.append(ConvBlock(n_feat, 4 * n_feat, 3, 1, 1, bias, activation=None, norm=None)) modules.append(torch.nn.PixelShuffle(2)) if bn: modules.append(torch.nn.BatchNorm2d(n_feat)) self.up = torch.nn.Sequential(*modules) self.activation = act if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): out = self.up(x) if self.activation is not None: out = self.act(out) return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'scale': 1.0, 'n_feat': 4}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp3 = tl.load(in_ptr1 + 0) tmp4 = tl.broadcast_to(tmp3, [XBLOCK]) tmp1 = 0.0 tmp2 = tmp0 > tmp1 tmp5 = tmp4 * tmp0 tmp6 = tl.where(tmp2, tmp0, tmp5) tl.store(out_ptr0 + x0, tmp6, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_0[grid(256)](primals_1, primals_2, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 return buf0, primals_1 class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class UpsamplerNew(torch.nn.Module): def __init__(self, scale, n_feat, bn=False, act='prelu', bias=True): super(UpsamplerNew, self).__init__() modules = [] for _ in range(int(math.log(scale, 2))): modules.append(ConvBlock(n_feat, 4 * n_feat, 3, 1, 1, bias, activation=None, norm=None)) modules.append(torch.nn.PixelShuffle(2)) if bn: modules.append(torch.nn.BatchNorm2d(n_feat)) self.up = torch.nn.Sequential(*modules) self.activation = act if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, input_0): primals_2 = self.act.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0]	DengZeshuai/DBPN-Pytorch	Upsampler	false	2,563	[ "MIT" ]	a90d241a1c4b07830c6d812ad8389d13e8cf05d1	https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1
TorchPow	import torch class TorchPow(torch.nn.Module): def __init__(self): super(TorchPow, self).__init__() def forward(self, x, y): return torch.pow(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.pow(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchPowNew(torch.nn.Module): def __init__(self): super(TorchPowNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchPow	false	2,564	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
Mod	import torch class Mod(torch.nn.Module): def __init__(self): super(Mod, self).__init__() def forward(self, x, y): return x % y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_remainder_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr0 + x0, tmp10, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class ModNew(torch.nn.Module): def __init__(self): super(ModNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	Mod	false	2,565	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
ContextGate	import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_sigmoid_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.sigmoid(tmp2) tl.store(in_out_ptr0 + x2, tmp3, xmask) @triton.jit def triton_poi_fused_cat_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), out=buf1) del primals_4 buf2 = buf1 del buf1 triton_poi_fused_sigmoid_1[grid(16)](buf2, primals_5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_5 buf3 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf3) del primals_6 del primals_7 buf4 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_2[grid(32)](primals_1, primals_2, buf4, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf4, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf5) del primals_8 del primals_9 return buf2, buf3, buf5, primals_3, buf0, buf2, buf4 class ContextGateNew(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGateNew, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, input_0, input_1, input_2): primals_4 = self.gate.weight primals_5 = self.gate.bias primals_1 = self.source_proj.weight primals_7 = self.source_proj.bias primals_8 = self.target_proj.weight primals_9 = self.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0], output[1], output[2]	LeeeeoLiu/OpenNMT-py	ContextGate	false	2,566	[ "MIT" ]	9be3a8951e9181aabe5440e4ea98173b7e749b5c	https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c
PixelShuffle	import torch import torch.nn as nn import torch.nn.parallel class PixelShuffle(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, x): ry = self.ry rx = self.rx [B, C, H, W] = list(x.shape) x = x.reshape(B, C // (ry * rx), ry, rx, H, W) x = x.permute(0, 1, 4, 2, 5, 3) x = x.reshape(B, C // (ry * rx), H * ry, W * rx) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.parallel assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 128 xnumel = 2 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x4 = xindex y0 = yindex % 4 y1 = yindex // 4 % 2 y2 = yindex // 8 % 4 y3 = yindex // 32 y5 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * y2 + 16 * x4 + 32 * y1 + 64 * y3), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x4 + 2 * y5), tmp0, xmask & ymask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 4, 2, 4, 2), (64, 64, 16, 8, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(128, 2)](arg0_1, buf0, 128, 2, XBLOCK =2, YBLOCK=64, num_warps=4, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 1, 8, 8), (64, 64, 8, 1), 0), class PixelShuffleNew(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	LonglifeHyun/GANda_text-to-image	PixelShuffle	false	2,567	[ "MIT" ]	095ded617e4df7d7ff7f4954381dde77db6d6883	https://github.com/LonglifeHyun/GANda_text-to-image/tree/095ded617e4df7d7ff7f4954381dde77db6d6883
Mul	import torch class Mul(torch.nn.Module): def __init__(self): super(Mul, self).__init__() def forward(self, x, y): return x * y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MulNew(torch.nn.Module): def __init__(self): super(MulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	Mul	false	2,568	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
PixelUnshuffle	import torch import torch.nn as nn import torch.nn.parallel class PixelUnshuffle(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, x): ry = self.ry rx = self.rx [B, C, H, W] = list(x.shape) x = x.reshape(B, C, H // ry, ry, W // rx, rx) x = x.permute(0, 1, 3, 5, 2, 4) x = x.reshape(B, C * (ry * rx), H // ry, W // rx) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.parallel assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 64 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x3 = xindex % 2 x4 = xindex // 2 y0 = yindex % 2 y1 = yindex // 2 % 2 y2 = yindex // 4 x6 = xindex y5 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 2 * x3 + 4 * y1 + 8 * x4 + 16 * y2), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x6 + 4 * y5), tmp0, xmask & ymask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 2, 2, 2, 2), (64, 16, 8, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(64, 4)](arg0_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 16, 2, 2), (64, 4, 2, 1), 0), class PixelUnshuffleNew(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	LonglifeHyun/GANda_text-to-image	PixelUnshuffle	false	2,569	[ "MIT" ]	095ded617e4df7d7ff7f4954381dde77db6d6883	https://github.com/LonglifeHyun/GANda_text-to-image/tree/095ded617e4df7d7ff7f4954381dde77db6d6883
TorchDiv	import torch class TorchDiv(torch.nn.Module): def __init__(self): super(TorchDiv, self).__init__() def forward(self, x, y): return torch.div(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchDivNew(torch.nn.Module): def __init__(self): super(TorchDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchDiv	false	2,570	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
TorchAdd	import torch class TorchAdd(torch.nn.Module): def __init__(self): super(TorchAdd, self).__init__() def forward(self, x, y): return torch.add(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchAddNew(torch.nn.Module): def __init__(self): super(TorchAddNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Ilyabasharov/torch2trt	TorchAdd	false	2,571	[ "MIT" ]	76bf298b3da408509665e23e2494922b131afb10	https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10
UpBlock	import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class UpBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(UpBlock, self).__init__() self.up_conv1 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv2 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv3 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): h0 = self.up_conv1(x) l0 = self.up_conv2(h0) h1 = self.up_conv3(l0 - x) return h1 + h0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 256 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp8, None) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 256 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, None) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp10, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10) = args args.clear() assert_size_stride(primals_1, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 16, 16), (1024, 256, 16, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(4096)](buf1, primals_2, primals_4, buf2, 4096, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 4, 4), (64, 16, 4, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_1[grid(256)](buf4, primals_6, primals_7, primals_3, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 16, 16), (1024, 256, 16, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) triton_poi_fused__prelu_kernel_add_convolution_2[grid(4096)](buf7, primals_9, primals_10, buf2, buf8, 4096, XBLOCK=256, num_warps= 4, num_stages=1) del primals_9 return (buf8, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, buf1, buf2, buf4, buf5, buf7) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class UpBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(UpBlockNew, self).__init__() self.up_conv1 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv2 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv3 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.up_conv1.deconv.weight primals_2 = self.up_conv1.deconv.bias primals_4 = self.up_conv1.act.weight primals_5 = self.up_conv2.conv.weight primals_6 = self.up_conv2.conv.bias primals_7 = self.up_conv2.act.weight primals_8 = self.up_conv3.deconv.weight primals_9 = self.up_conv3.deconv.bias primals_10 = self.up_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10]) return output[0]	DengZeshuai/DBPN-Pytorch	UpBlock	false	2,572	[ "MIT" ]	a90d241a1c4b07830c6d812ad8389d13e8cf05d1	https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1
AtenSoftmaxRepalce	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AtenSoftmaxRepalce(nn.Module): def __init__(self, dim=-1): super(AtenSoftmaxRepalce, self).__init__() self.softmax = torch.nn.Softmax(dim) def forward(self, x): return self.softmax(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf0 return buf1, class AtenSoftmaxRepalceNew(nn.Module): def __init__(self, dim=-1): super(AtenSoftmaxRepalceNew, self).__init__() self.softmax = torch.nn.Softmax(dim) def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	JudeDavis1/intel-extension-for-pytorch	AtenSoftmaxRepalce	false	2,573	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
UPChannelBAN	import torch import torch.nn.functional as F import torch.nn as nn def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class BAN(nn.Module): """ BAN基础构造函数 """ def __init__(self): super(BAN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelBAN(BAN): def __init__(self, feature_in=256, cls_out_channels=2): super(UPChannelBAN, self).__init__() cls_output = cls_out_channels loc_output = 4 self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, z_f, x_f): cls_kernel = self.template_cls_conv(z_f) loc_kernel = self.template_loc_conv(z_f) cls_feature = self.search_cls_conv(x_f) loc_feature = self.search_loc_conv(x_f) cls = xcorr_fast(cls_feature, cls_kernel) loc = self.loc_adjust(xcorr_fast(loc_feature, loc_kernel)) return cls, loc def get_inputs(): return [torch.rand([4, 256, 64, 64]), torch.rand([4, 256, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional as F import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_view_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 512 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 3844 % 256 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_poi_fused_convolution_view_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 1024 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12 ) = args args.clear() assert_size_stride(primals_1, (512, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_2, (512,), (1,)) assert_size_stride(primals_3, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_4, (1024, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_5, (1024,), (1,)) assert_size_stride(primals_6, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_9, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_10, (256,), (1,)) assert_size_stride(primals_11, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_12, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 512, 62, 62), (1968128, 3844, 62, 1)) buf1 = extern_kernels.convolution(primals_3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 1024, 62, 62), (3936256, 3844, 62, 1)) buf2 = extern_kernels.convolution(primals_8, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf3 = extern_kernels.convolution(primals_8, primals_9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf4 = buf0 del buf0 buf5 = reinterpret_tensor(buf4, (8, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf4 get_raw_stream(0) triton_poi_fused_convolution_view_0[grid(7872512)](buf5, primals_2, 7872512, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf6 = buf2 del buf2 triton_poi_fused_convolution_1[grid(3936256)](buf6, primals_7, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_7 buf7 = extern_kernels.convolution(reinterpret_tensor(buf6, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf5, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf7, (1, 8, 1, 1), (8, 1, 1, 1)) buf8 = buf1 del buf1 buf9 = reinterpret_tensor(buf8, (16, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf8 triton_poi_fused_convolution_view_2[grid(15745024)](buf9, primals_5, 15745024, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf10 = buf3 del buf3 triton_poi_fused_convolution_1[grid(3936256)](buf10, primals_10, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_10 buf11 = extern_kernels.convolution(reinterpret_tensor(buf10, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf11, (1, 16, 1, 1), (16, 1, 1, 1)) buf12 = extern_kernels.convolution(reinterpret_tensor(buf11, (4, 4, 1, 1), (4, 1, 1, 1), 0), primals_11, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf12, (4, 4, 1, 1), (4, 1, 1, 1)) buf13 = buf12 del buf12 triton_poi_fused_convolution_3[grid(16)](buf13, primals_12, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_12 return (reinterpret_tensor(buf7, (4, 2, 1, 1), (2, 1, 1, 1), 0), buf13, primals_1, primals_3, primals_4, primals_6, primals_8, primals_9, primals_11, buf5, reinterpret_tensor(buf6, (1, 1024, 62, 62), ( 3936256, 3844, 62, 1), 0), buf9, reinterpret_tensor(buf10, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), reinterpret_tensor(buf11, (4, 4, 1, 1), (4, 1, 1, 1), 0)) def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class BAN(nn.Module): """ BAN基础构造函数 """ def __init__(self): super(BAN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelBANNew(BAN): def __init__(self, feature_in=256, cls_out_channels=2): super(UPChannelBANNew, self).__init__() cls_output = cls_out_channels loc_output = 4 self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, input_0, input_1): primals_1 = self.template_cls_conv.weight primals_2 = self.template_cls_conv.bias primals_4 = self.template_loc_conv.weight primals_5 = self.template_loc_conv.bias primals_6 = self.search_cls_conv.weight primals_7 = self.search_cls_conv.bias primals_9 = self.search_loc_conv.weight primals_10 = self.search_loc_conv.bias primals_11 = self.loc_adjust.weight primals_12 = self.loc_adjust.bias primals_3 = input_0 primals_8 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12]) return output[0], output[1]	IRLSCU/siamban	UPChannelBAN	false	2,574	[ "Apache-2.0" ]	abb12d028e93aaee74efc5042a5bb305c7805053	https://github.com/IRLSCU/siamban/tree/abb12d028e93aaee74efc5042a5bb305c7805053
inplace_softmax	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class inplace_softmax(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): x1 = x + 1 x2 = nn.Softmax(dim=-1)(x1) return x2 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_add_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp1 = 1.0 tmp2 = tmp0 + tmp1 tmp4 = tmp3 + tmp1 tmp6 = tmp5 + tmp1 tmp7 = triton_helpers.maximum(tmp4, tmp6) tmp9 = tmp8 + tmp1 tmp10 = triton_helpers.maximum(tmp7, tmp9) tmp12 = tmp11 + tmp1 tmp13 = triton_helpers.maximum(tmp10, tmp12) tmp14 = tmp2 - tmp13 tmp15 = tl_math.exp(tmp14) tl.store(out_ptr0 + x2, tmp15, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_add_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf0 return buf1, class inplace_softmaxNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	JudeDavis1/intel-extension-for-pytorch	inplace_softmax	false	2,575	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
CharbonnierLoss	import functools import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def reduce_loss(loss, reduction): """Reduce loss as specified. Args: loss (Tensor): Elementwise loss tensor. reduction (str): Options are 'none', 'mean' and 'sum'. Returns: Tensor: Reduced loss tensor. """ reduction_enum = F._Reduction.get_enum(reduction) if reduction_enum == 0: return loss elif reduction_enum == 1: return loss.mean() else: return loss.sum() def weight_reduce_loss(loss, weight=None, reduction='mean'): """Apply element-wise weight and reduce loss. Args: loss (Tensor): Element-wise loss. weight (Tensor): Element-wise weights. Default: None. reduction (str): Same as built-in losses of PyTorch. Options are 'none', 'mean' and 'sum'. Default: 'mean'. Returns: Tensor: Loss values. """ if weight is not None: assert weight.dim() == loss.dim() assert weight.size(1) == 1 or weight.size(1) == loss.size(1) loss = loss * weight if weight is None or reduction == 'sum': loss = reduce_loss(loss, reduction) elif reduction == 'mean': if weight.size(1) > 1: weight = weight.sum() else: weight = weight.sum() * loss.size(1) loss = loss.sum() / weight return loss def weighted_loss(loss_func): """Create a weighted version of a given loss function. To use this decorator, the loss function must have the signature like `loss_func(pred, target, kwargs)`. The function only needs to compute element-wise loss without any reduction. This decorator will add weight and reduction arguments to the function. The decorated function will have the signature like `loss_func(pred, target, weight=None, reduction='mean', kwargs)`. :Example: >>> import torch >>> @weighted_loss >>> def l1_loss(pred, target): >>> return (pred - target).abs() >>> pred = torch.Tensor([0, 2, 3]) >>> target = torch.Tensor([1, 1, 1]) >>> weight = torch.Tensor([1, 0, 1]) >>> l1_loss(pred, target) tensor(1.3333) >>> l1_loss(pred, target, weight) tensor(1.5000) >>> l1_loss(pred, target, reduction='none') tensor([1., 1., 2.]) >>> l1_loss(pred, target, weight, reduction='sum') tensor(3.) """ @functools.wraps(loss_func) def wrapper(pred, target, weight=None, reduction='mean', kwargs): loss = loss_func(pred, target, kwargs) loss = weight_reduce_loss(loss, weight, reduction) return loss return wrapper @weighted_loss def charbonnier_loss(pred, target, eps=1e-12): return torch.sqrt((pred - target) 2 + eps) class CharbonnierLoss(nn.Module): """Charbonnier loss (one variant of Robust L1Loss, a differentiable variant of L1Loss). Described in "Deep Laplacian Pyramid Networks for Fast and Accurate Super-Resolution". Args: loss_weight (float): Loss weight for L1 loss. Default: 1.0. reduction (str): Specifies the reduction to apply to the output. Supported choices are 'none' \| 'mean' \| 'sum'. Default: 'mean'. eps (float): A value used to control the curvature near zero. Default: 1e-12. """ def __init__(self, loss_weight=1.0, reduction='mean', eps=1e-12): super(CharbonnierLoss, self).__init__() if reduction not in ['none', 'mean', 'sum']: raise ValueError( f'Unsupported reduction mode: {reduction}. Supported ones are: {_reduction_modes}' ) self.loss_weight = loss_weight self.reduction = reduction self.eps = eps def forward(self, pred, target, weight=None, kwargs): """ Args: pred (Tensor): of shape (N, C, H, W). Predicted tensor. target (Tensor): of shape (N, C, H, W). Ground truth tensor. weight (Tensor, optional): of shape (N, C, H, W). Element-wise weights. Default: None. """ return self.loss_weight * charbonnier_loss(pred, target, weight, eps=self.eps, reduction=self.reduction) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import functools from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_mean_mul_pow_sqrt_sub_0(in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr1 + r0, None) tmp2 = tmp0 - tmp1 tmp3 = tmp2 * tmp2 tmp4 = 1e-12 tmp5 = tmp3 + tmp4 tmp6 = libdevice.sqrt(tmp5) tmp7 = tl.broadcast_to(tmp6, [RBLOCK]) tmp9 = triton_helpers.promote_to_tensor(tl.sum(tmp7, 0)) tmp10 = 256.0 tmp11 = tmp9 / tmp10 tmp12 = 1.0 tmp13 = tmp11 * tmp12 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp13, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_mean_mul_pow_sqrt_sub_0[grid(1)](buf1, arg0_1, arg1_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf1, def reduce_loss(loss, reduction): """Reduce loss as specified. Args: loss (Tensor): Elementwise loss tensor. reduction (str): Options are 'none', 'mean' and 'sum'. Returns: Tensor: Reduced loss tensor. """ reduction_enum = F._Reduction.get_enum(reduction) if reduction_enum == 0: return loss elif reduction_enum == 1: return loss.mean() else: return loss.sum() def weight_reduce_loss(loss, weight=None, reduction='mean'): """Apply element-wise weight and reduce loss. Args: loss (Tensor): Element-wise loss. weight (Tensor): Element-wise weights. Default: None. reduction (str): Same as built-in losses of PyTorch. Options are 'none', 'mean' and 'sum'. Default: 'mean'. Returns: Tensor: Loss values. """ if weight is not None: assert weight.dim() == loss.dim() assert weight.size(1) == 1 or weight.size(1) == loss.size(1) loss = loss * weight if weight is None or reduction == 'sum': loss = reduce_loss(loss, reduction) elif reduction == 'mean': if weight.size(1) > 1: weight = weight.sum() else: weight = weight.sum() * loss.size(1) loss = loss.sum() / weight return loss def weighted_loss(loss_func): """Create a weighted version of a given loss function. To use this decorator, the loss function must have the signature like `loss_func(pred, target, kwargs)`. The function only needs to compute element-wise loss without any reduction. This decorator will add weight and reduction arguments to the function. The decorated function will have the signature like `loss_func(pred, target, weight=None, reduction='mean', kwargs)`. :Example: >>> import torch >>> @weighted_loss >>> def l1_loss(pred, target): >>> return (pred - target).abs() >>> pred = torch.Tensor([0, 2, 3]) >>> target = torch.Tensor([1, 1, 1]) >>> weight = torch.Tensor([1, 0, 1]) >>> l1_loss(pred, target) tensor(1.3333) >>> l1_loss(pred, target, weight) tensor(1.5000) >>> l1_loss(pred, target, reduction='none') tensor([1., 1., 2.]) >>> l1_loss(pred, target, weight, reduction='sum') tensor(3.) """ @functools.wraps(loss_func) def wrapper(pred, target, weight=None, reduction='mean', kwargs): loss = loss_func(pred, target, kwargs) loss = weight_reduce_loss(loss, weight, reduction) return loss return wrapper @weighted_loss def charbonnier_loss(pred, target, eps=1e-12): return torch.sqrt((pred - target) ** 2 + eps) class CharbonnierLossNew(nn.Module): """Charbonnier loss (one variant of Robust L1Loss, a differentiable variant of L1Loss). Described in "Deep Laplacian Pyramid Networks for Fast and Accurate Super-Resolution". Args: loss_weight (float): Loss weight for L1 loss. Default: 1.0. reduction (str): Specifies the reduction to apply to the output. Supported choices are 'none' \| 'mean' \| 'sum'. Default: 'mean'. eps (float): A value used to control the curvature near zero. Default: 1e-12. """ def __init__(self, loss_weight=1.0, reduction='mean', eps=1e-12): super(CharbonnierLossNew, self).__init__() if reduction not in ['none', 'mean', 'sum']: raise ValueError( f'Unsupported reduction mode: {reduction}. Supported ones are: {_reduction_modes}' ) self.loss_weight = loss_weight self.reduction = reduction self.eps = eps def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	Lotayou/BasicSR	CharbonnierLoss	false	2,576	[ "Apache-2.0", "MIT" ]	6cf9a706dd680d54f7dc26e87318ff79f76c0dbf	https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf
MHAScoresCalculation	import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class MHAScoresCalculation(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(MHAScoresCalculation, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, mat1, mat2, bias): mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) scores = qk + bias return self.softmax(scores) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 4, 4, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_add_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp12 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = triton_helpers.maximum(tmp2, tmp5) tmp9 = tmp7 + tmp8 tmp10 = triton_helpers.maximum(tmp6, tmp9) tmp13 = tmp11 + tmp12 tmp14 = triton_helpers.maximum(tmp10, tmp13) tmp15 = tmp2 - tmp14 tmp16 = tl_math.exp(tmp15) tmp17 = tmp5 - tmp14 tmp18 = tl_math.exp(tmp17) tmp19 = tmp16 + tmp18 tmp20 = tmp9 - tmp14 tmp21 = tl_math.exp(tmp20) tmp22 = tmp19 + tmp21 tmp23 = tmp13 - tmp14 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tl.store(out_ptr0 + x0, tmp14, xmask) tl.store(out_ptr1 + x0, tmp25, xmask) @triton.jit def triton_poi_fused__softmax_add_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp5 = tl_math.exp(tmp4) tmp7 = tmp5 / tmp6 tl.store(in_out_ptr0 + x2, tmp7, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_add_1[grid(64)](buf1, arg2_1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_add_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class MHAScoresCalculationNew(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(MHAScoresCalculationNew, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]	JudeDavis1/intel-extension-for-pytorch	MHAScoresCalculation	false	2,577	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
AddLayerNorm_v1	import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AddLayerNorm_v1(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm_v1, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, x, y, z): x = x + y + z return self.layernorm(x) def get_inputs(): return [torch.rand([4, 4, 32, 32]), torch.rand([4, 4, 32, 32]), torch. rand([4, 4, 32, 32])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_native_layer_norm_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, out_ptr2, out_ptr3, xnumel, rnumel, XBLOCK: tl.constexpr ): xnumel = 512 RBLOCK: tl.constexpr = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 32 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 32 * x0), xmask, other=0.0) tmp3 = tl.load(in_ptr2 + (r1 + 32 * x0), xmask, other=0.0) tmp28 = tl.load(in_ptr3 + r1, None, eviction_policy='evict_last') tmp30 = tl.load(in_ptr4 + r1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = tl.broadcast_to(tmp4, [XBLOCK, RBLOCK]) tl.where(xmask, tmp5, 0) tmp8 = tl.broadcast_to(tmp5, [XBLOCK, RBLOCK]) tmp10 = tl.where(xmask, tmp8, 0) tmp11 = tl.sum(tmp10, 1)[:, None] tmp12 = tl.full([XBLOCK, 1], 32, tl.int32) tmp13 = tmp12.to(tl.float32) tmp14 = tmp11 / tmp13 tmp15 = tmp5 - tmp14 tmp16 = tmp15 * tmp15 tmp17 = tl.broadcast_to(tmp16, [XBLOCK, RBLOCK]) tmp19 = tl.where(xmask, tmp17, 0) tmp20 = tl.sum(tmp19, 1)[:, None] tmp21 = tmp4 - tmp14 tmp22 = 32.0 tmp23 = tmp20 / tmp22 tmp24 = 1e-05 tmp25 = tmp23 + tmp24 tmp26 = libdevice.rsqrt(tmp25) tmp27 = tmp21 * tmp26 tmp29 = tmp27 * tmp28 tmp31 = tmp29 + tmp30 tl.store(out_ptr2 + (r1 + 32 * x0), tmp27, xmask) tl.store(out_ptr3 + (r1 + 32 * x0), tmp31, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_2, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_3, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_4, (32,), (1,)) assert_size_stride(primals_5, (32,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf3 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) buf4 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) get_raw_stream(0) triton_per_fused_add_native_layer_norm_0[grid(512)](primals_1, primals_2, primals_3, primals_4, primals_5, buf3, buf4, 512, 32, XBLOCK=32, num_warps=8, num_stages=1) del primals_1 del primals_2 del primals_3 del primals_4 del primals_5 return buf4, buf3 class AddLayerNorm_v1New(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm_v1New, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, input_0, input_1, input_2): primals_4 = self.layernorm.weight primals_5 = self.layernorm.bias primals_1 = input_0 primals_2 = input_1 primals_3 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]	JudeDavis1/intel-extension-for-pytorch	AddLayerNorm_v1	false	2,578	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
DistilMHAScoresCalculation_v2	import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class DistilMHAScoresCalculation_v2(nn.Module): def __init__(self, dim_per_head): super(DistilMHAScoresCalculation_v2, self).__init__() self.dim_per_head = dim_per_head def forward(self, mat1, mat2, mask): mask_shape = [mat1.shape[0], 1, 1, mat1.shape[3]] mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) mask = (mask == 0).view(mask_shape).expand_as(qk) qk = qk.masked_fill(mask, -float('inf')) return nn.functional.softmax(qk, dim=-1) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 1, 1, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_masked_fill_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + 4 * x2, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (1 + 4 * x2), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp13 = tl.load(in_ptr1 + (2 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp18 = tl.load(in_ptr1 + (3 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp6 == tmp1 tmp9 = tl.where(tmp7, tmp4, tmp8) tmp10 = triton_helpers.maximum(tmp5, tmp9) tmp12 = tmp11 == tmp1 tmp14 = tl.where(tmp12, tmp4, tmp13) tmp15 = triton_helpers.maximum(tmp10, tmp14) tmp17 = tmp16 == tmp1 tmp19 = tl.where(tmp17, tmp4, tmp18) tmp20 = triton_helpers.maximum(tmp15, tmp19) tmp21 = tmp5 - tmp20 tmp22 = tl_math.exp(tmp21) tmp23 = tmp9 - tmp20 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tmp26 = tmp14 - tmp20 tmp27 = tl_math.exp(tmp26) tmp28 = tmp25 + tmp27 tmp29 = tmp19 - tmp20 tmp30 = tl_math.exp(tmp29) tmp31 = tmp28 + tmp30 tl.store(out_ptr0 + x2, tmp20, xmask) tl.store(out_ptr1 + x2, tmp31, xmask) @triton.jit def triton_poi_fused__softmax_masked_fill_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex // 64 x3 = xindex x4 = xindex // 4 tmp0 = tl.load(in_ptr0 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_out_ptr0 + x3, xmask) tmp6 = tl.load(in_ptr1 + x4, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp5 - tmp6 tmp8 = tl_math.exp(tmp7) tmp10 = tmp8 / tmp9 tl.store(in_out_ptr0 + x3, tmp10, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 1, 1, 4), (4, 4, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_masked_fill_1[grid(64)](arg2_1, buf1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_masked_fill_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class DistilMHAScoresCalculation_v2New(nn.Module): def __init__(self, dim_per_head): super(DistilMHAScoresCalculation_v2New, self).__init__() self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]	JudeDavis1/intel-extension-for-pytorch	DistilMHAScoresCalculation_v2	false	2,579	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
DistilMHAScoresCalculation_v1	import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class DistilMHAScoresCalculation_v1(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(DistilMHAScoresCalculation_v1, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, mat1, mat2, mask): mask_shape = [mat1.shape[0], 1, 1, mat1.shape[3]] mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) mask = (mask == 0).view(mask_shape).expand_as(qk) qk.masked_fill_(mask, -float('inf')) return self.softmax(qk) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 1, 1, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + 4 * x2, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (1 + 4 * x2), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp13 = tl.load(in_ptr1 + (2 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp18 = tl.load(in_ptr1 + (3 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp6 == tmp1 tmp9 = tl.where(tmp7, tmp4, tmp8) tmp10 = triton_helpers.maximum(tmp5, tmp9) tmp12 = tmp11 == tmp1 tmp14 = tl.where(tmp12, tmp4, tmp13) tmp15 = triton_helpers.maximum(tmp10, tmp14) tmp17 = tmp16 == tmp1 tmp19 = tl.where(tmp17, tmp4, tmp18) tmp20 = triton_helpers.maximum(tmp15, tmp19) tmp21 = tmp5 - tmp20 tmp22 = tl_math.exp(tmp21) tmp23 = tmp9 - tmp20 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tmp26 = tmp14 - tmp20 tmp27 = tl_math.exp(tmp26) tmp28 = tmp25 + tmp27 tmp29 = tmp19 - tmp20 tmp30 = tl_math.exp(tmp29) tmp31 = tmp28 + tmp30 tl.store(out_ptr0 + x2, tmp20, xmask) tl.store(out_ptr1 + x2, tmp31, xmask) @triton.jit def triton_poi_fused__softmax_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex // 64 x3 = xindex x4 = xindex // 4 tmp0 = tl.load(in_ptr0 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_out_ptr0 + x3, xmask) tmp6 = tl.load(in_ptr1 + x4, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp5 - tmp6 tmp8 = tl_math.exp(tmp7) tmp10 = tmp8 / tmp9 tl.store(in_out_ptr0 + x3, tmp10, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 1, 1, 4), (4, 4, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_1[grid(64)](arg2_1, buf1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class DistilMHAScoresCalculation_v1New(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(DistilMHAScoresCalculation_v1New, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]	JudeDavis1/intel-extension-for-pytorch	DistilMHAScoresCalculation_v1	false	2,580	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
ConvTranspose2d	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class ConvTranspose2d(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, stride=1, padding=0, output_padding=0, groups=1, bias=True, dilation=1): super(ConvTranspose2d, self).__init__() self.conv_transpose2d = nn.ConvTranspose2d(in_channels, out_channels, kernel_size, stride, padding, output_padding, groups, bias, dilation) def forward(self, x): x = self.conv_transpose2d(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4, 'kernel_size': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 784 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 49 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 7, 7), (196, 49, 7, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(784)](buf1, primals_2, 784, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 return buf1, primals_1, primals_3 class ConvTranspose2dNew(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, stride=1, padding=0, output_padding=0, groups=1, bias=True, dilation=1): super(ConvTranspose2dNew, self).__init__() self.conv_transpose2d = nn.ConvTranspose2d(in_channels, out_channels, kernel_size, stride, padding, output_padding, groups, bias, dilation) def forward(self, input_0): primals_1 = self.conv_transpose2d.weight primals_2 = self.conv_transpose2d.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	JudeDavis1/intel-extension-for-pytorch	ConvTranspose2d	false	2,581	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
LinearAdd	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class LinearAdd(nn.Module): def __init__(self, in_channels, out_channels, kwargs): super(LinearAdd, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, kwargs) self.linear1 = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, x): x1 = x.clone() return torch.add(self.linear(x), self.linear1(x1)) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_0(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp4 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tl.store(in_out_ptr0 + x2, tmp6, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf0) del primals_2 buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_0[grid(256)](buf2, primals_3, buf1, primals_5, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf1 del primals_3 del primals_5 return buf2, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0) class LinearAddNew(nn.Module): def __init__(self, in_channels, out_channels, kwargs): super(LinearAddNew, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, kwargs) self.linear1 = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, input_0): primals_2 = self.linear.weight primals_3 = self.linear.bias primals_4 = self.linear1.weight primals_5 = self.linear1.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]	JudeDavis1/intel-extension-for-pytorch	LinearAdd	false	2,582	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
hsigmoid	import torch import torch.onnx import torch import torch.nn as nn import torch.nn.functional as F class hsigmoid(nn.Module): def forward(self, x): out = F.relu6(x + 3, inplace=True) / 6 return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.onnx import torch import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_div_hardtanh_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 3.0 tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = triton_helpers.maximum(tmp2, tmp3) tmp5 = 6.0 tmp6 = triton_helpers.minimum(tmp4, tmp5) tmp7 = 0.16666666666666666 tmp8 = tmp6 * tmp7 tl.store(out_ptr0 + x0, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_div_hardtanh_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class hsigmoidNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	LukasKratochvila/pytorch-ssd	hsigmoid	false	2,583	[ "MIT" ]	de6ed2be6ce0b03634d4cbf41622cfe5c87d077c	https://github.com/LukasKratochvila/pytorch-ssd/tree/de6ed2be6ce0b03634d4cbf41622cfe5c87d077c
LinearSwish	import torch import torch.nn as nn import torch.cuda import torch.nn.functional as F import torch.backends.cudnn import torch.backends.mkl class LinearSwish(nn.Module): def __init__(self, in_channels, out_channels, kwargs): super(LinearSwish, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, kwargs) def forward(self, x): linear_res = self.linear(x) return F.silu(linear_res) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_silu_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf0) del primals_1 del primals_2 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_silu_0[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) return buf1, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), buf0 class LinearSwishNew(nn.Module): def __init__(self, in_channels, out_channels, kwargs): super(LinearSwishNew, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, kwargs) def forward(self, input_0): primals_1 = self.linear.weight primals_2 = self.linear.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	JudeDavis1/intel-extension-for-pytorch	LinearSwish	false	2,584	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
EqualLinear	from torch.autograd import Function import math import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None \| str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch.autograd import Function import math from torch import nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4,), (1,)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(16)](primals_2, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_2 buf1 = empty_strided_cuda((4,), (1,), torch.float32) triton_poi_fused_mul_1[grid(4)](primals_1, buf1, 4, XBLOCK=4, num_warps=1, num_stages=1) del primals_1 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(buf1, reinterpret_tensor(primals_3, (64, 4), ( 4, 1), 0), reinterpret_tensor(buf0, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del buf0 del buf1 return reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0) def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinearNew(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None \| str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinearNew, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) def forward(self, input_0): primals_2 = self.weight primals_1 = self.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	Lotayou/BasicSR	EqualLinear	false	2,585	[ "Apache-2.0", "MIT" ]	6cf9a706dd680d54f7dc26e87318ff79f76c0dbf	https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf
AddLayerNorm	import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AddLayerNorm(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, x, y): x = torch.add(x, y) return self.layernorm(x) def get_inputs(): return [torch.rand([4, 4, 32, 32]), torch.rand([4, 4, 32, 32])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_native_layer_norm_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr2, out_ptr3, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 512 RBLOCK: tl.constexpr = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 32 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 32 * x0), xmask, other=0.0) tmp26 = tl.load(in_ptr2 + r1, None, eviction_policy='evict_last') tmp28 = tl.load(in_ptr3 + r1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tl.where(xmask, tmp3, 0) tmp6 = tl.broadcast_to(tmp3, [XBLOCK, RBLOCK]) tmp8 = tl.where(xmask, tmp6, 0) tmp9 = tl.sum(tmp8, 1)[:, None] tmp10 = tl.full([XBLOCK, 1], 32, tl.int32) tmp11 = tmp10.to(tl.float32) tmp12 = tmp9 / tmp11 tmp13 = tmp3 - tmp12 tmp14 = tmp13 * tmp13 tmp15 = tl.broadcast_to(tmp14, [XBLOCK, RBLOCK]) tmp17 = tl.where(xmask, tmp15, 0) tmp18 = tl.sum(tmp17, 1)[:, None] tmp19 = tmp2 - tmp12 tmp20 = 32.0 tmp21 = tmp18 / tmp20 tmp22 = 1e-05 tmp23 = tmp21 + tmp22 tmp24 = libdevice.rsqrt(tmp23) tmp25 = tmp19 * tmp24 tmp27 = tmp25 * tmp26 tmp29 = tmp27 + tmp28 tl.store(out_ptr2 + (r1 + 32 * x0), tmp25, xmask) tl.store(out_ptr3 + (r1 + 32 * x0), tmp29, xmask) def call(args): primals_1, primals_2, primals_3, primals_4 = args args.clear() assert_size_stride(primals_1, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_2, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_3, (32,), (1,)) assert_size_stride(primals_4, (32,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf3 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) buf4 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) get_raw_stream(0) triton_per_fused_add_native_layer_norm_0[grid(512)](primals_2, primals_1, primals_3, primals_4, buf3, buf4, 512, 32, XBLOCK=8, num_warps=2, num_stages=1) del primals_1 del primals_2 del primals_3 del primals_4 return buf4, buf3 class AddLayerNormNew(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNormNew, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, input_0, input_1): primals_3 = self.layernorm.weight primals_4 = self.layernorm.bias primals_1 = input_0 primals_2 = input_1 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]	JudeDavis1/intel-extension-for-pytorch	AddLayerNorm	false	2,586	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
Module	from torch.nn import Module import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Module(torch.nn.Module): def __init__(self): super(Module, self).__init__() self.conv = torch.nn.Conv2d(1, 10, 5, 1) def forward(self, x): y = self.conv(x) return y def get_inputs(): return [torch.rand([4, 1, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 144000 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 3600 % 10 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (10, 1, 5, 5), (25, 25, 5, 1)) assert_size_stride(primals_2, (10,), (1,)) assert_size_stride(primals_3, (4, 1, 64, 64), (4096, 4096, 64, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 10, 60, 60), (36000, 3600, 60, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(144000)](buf1, primals_2, 144000, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 return buf1, primals_1, primals_3 class ModuleNew(torch.nn.Module): def __init__(self): super(ModuleNew, self).__init__() self.conv = torch.nn.Conv2d(1, 10, 5, 1) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]	JudeDavis1/intel-extension-for-pytorch	Module	false	2,587	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
Bottleneck_v1	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Bottleneck_v1(nn.Module): def __init__(self): super(Bottleneck_v1, self).__init__() self.conv1 = nn.Conv2d(64, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.downsample = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, x): y1 = self.conv1(x).relu_() y2 = self.conv2(y1).relu_() y3 = self.conv3(y2) y3 += self.downsample(x) return y3.relu_() def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_relu_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 64 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, None) @triton.jit def triton_poi_fused_add_convolution_relu_3(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl. constexpr): xnumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 4096 y1 = yindex // 4096 tmp0 = tl.load(in_ptr0 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr3 + x2, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp7 = tl.full([1, 1], 0, tl.int32) tmp8 = triton_helpers.maximum(tmp7, tmp6) tl.store(out_ptr0 + (y0 + 4096 * x2 + 1048576 * y1), tmp8, xmask) @triton.jit def triton_poi_fused_threshold_backward_4(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 256 y1 = yindex // 256 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), None, eviction_policy= 'evict_last') tmp1 = 0.0 tmp2 = tmp0 <= tmp1 tl.store(out_ptr0 + (y0 + 256 * x2 + 1048576 * y1), tmp2, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (64, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_2, (64,), (1,)) assert_size_stride(primals_3, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_4, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) assert_size_stride(primals_6, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_9, (256,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) get_raw_stream(0) triton_poi_fused_0[grid(256, 4096)](primals_3, buf0, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_3 buf1 = empty_strided_cuda((64, 64, 3, 3), (576, 1, 192, 64), torch. float32) triton_poi_fused_1[grid(4096, 9)](primals_4, buf1, 4096, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_4 buf2 = extern_kernels.convolution(buf0, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf3 = buf2 del buf2 triton_poi_fused_convolution_relu_2[grid(1048576)](buf3, primals_2, 1048576, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf4 = extern_kernels.convolution(buf3, buf1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_2[grid(1048576)](buf5, primals_5, 1048576, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf6 = extern_kernels.convolution(buf5, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf7 = extern_kernels.convolution(buf0, primals_8, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf7, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf8 = empty_strided_cuda((4, 256, 64, 64), (1048576, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_relu_3[grid(16384, 256)](buf6, primals_7, buf7, primals_9, buf8, 16384, 256, XBLOCK=32, YBLOCK =32, num_warps=4, num_stages=1) del buf6 del buf7 del primals_7 del primals_9 buf9 = empty_strided_cuda((4, 256, 64, 64), (1048576, 1, 16384, 256 ), torch.bool) triton_poi_fused_threshold_backward_4[grid(1024, 4096)](buf8, buf9, 1024, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) return buf8, primals_1, buf0, buf1, primals_6, primals_8, buf3, buf5, buf9 class Bottleneck_v1New(nn.Module): def __init__(self): super(Bottleneck_v1New, self).__init__() self.conv1 = nn.Conv2d(64, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.downsample = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, input_0): primals_1 = self.conv1.weight primals_2 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_6 = self.conv3.weight primals_7 = self.conv3.bias primals_8 = self.downsample.weight primals_9 = self.downsample.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]	JudeDavis1/intel-extension-for-pytorch	Bottleneck_v1	false	2,588	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
DivLoss	import torch from torch import nn from torch.optim.lr_scheduler import * class DivLoss(nn.Module): def __init__(self): super(DivLoss, self).__init__() def forward(self, scores): mu = scores.mean(0) std = ((scores - mu) ** 2).mean(0, keepdim=True).clamp(min=1e-12).sqrt( ) loss_std = -std.sum() return loss_std def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn from torch.optim.lr_scheduler import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_clamp_mean_neg_pow_sqrt_sub_sum_0(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr0 + (64 + r0), None) tmp3 = tl.load(in_ptr0 + (128 + r0), None) tmp5 = tl.load(in_ptr0 + (192 + r0), None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tmp9 = tmp0 - tmp8 tmp10 = tmp9 * tmp9 tmp11 = tmp1 - tmp8 tmp12 = tmp11 * tmp11 tmp13 = tmp10 + tmp12 tmp14 = tmp3 - tmp8 tmp15 = tmp14 * tmp14 tmp16 = tmp13 + tmp15 tmp17 = tmp5 - tmp8 tmp18 = tmp17 * tmp17 tmp19 = tmp16 + tmp18 tmp20 = tmp19 / tmp7 tmp21 = 1e-12 tmp22 = triton_helpers.maximum(tmp20, tmp21) tmp23 = libdevice.sqrt(tmp22) tmp24 = tl.broadcast_to(tmp23, [XBLOCK, RBLOCK]) tmp26 = tl.sum(tmp24, 1)[:, None] tmp27 = -tmp26 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp27, None) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_clamp_mean_neg_pow_sqrt_sub_sum_0[grid(1)](buf1, arg0_1, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 return buf1, class DivLossNew(nn.Module): def __init__(self): super(DivLossNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	Luxios22/IDM	DivLoss	false	2,589	[ "MIT" ]	8d51103b7c252e6304e2a361976e16ed4b523944	https://github.com/Luxios22/IDM/tree/8d51103b7c252e6304e2a361976e16ed4b523944
SimpleNet	import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class SimpleNet(torch.nn.Module): def __init__(self): super(SimpleNet, self).__init__() self.conv = torch.nn.Conv2d(64, 128, (3, 3), stride=(2, 2), padding =(1, 1), bias=False) def forward(self, x): x1 = self.conv(x) y = torch.flatten(x1, start_dim=1) return y def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_view_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x0 = xindex % 131072 x1 = xindex // 131072 x2 = xindex tmp0 = tl.load(in_ptr0 + (128 * (x0 % 1024) + 131072 * x1 + x0 // 1024), None, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, None) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (128, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_2, (4, 64, 64, 64), (262144, 4096, 64, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((128, 64, 3, 3), (576, 1, 192, 64), torch .float32) get_raw_stream(0) triton_poi_fused_0[grid(8192, 9)](primals_1, buf0, 8192, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_1 buf1 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) triton_poi_fused_1[grid(256, 4096)](primals_2, buf1, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, buf0, stride=(2, 2), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 128, 32, 32), (131072, 1, 4096, 128)) buf3 = empty_strided_cuda((4, 131072), (131072, 1), torch.float32) triton_poi_fused_view_2[grid(524288)](buf2, buf3, 524288, XBLOCK= 1024, num_warps=4, num_stages=1) del buf2 return buf3, buf0, buf1 class SimpleNetNew(torch.nn.Module): def __init__(self): super(SimpleNetNew, self).__init__() self.conv = torch.nn.Conv2d(64, 128, (3, 3), stride=(2, 2), padding =(1, 1), bias=False) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]	JudeDavis1/intel-extension-for-pytorch	SimpleNet	false	2,590	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
Swish	import torch import torch.nn import torch.nn as nn class Swish(nn.Module): """Applies the element-wise function: .. math:: \\text{Swish}(x) = x * \\text{Sigmoid}(\\alpha * x) for constant value alpha. Citation: Searching for Activation Functions, Ramachandran et al., 2017, https://arxiv.org/abs/1710.05941. Shape: - Input: :math:`(N, )` where `` means, any number of additional dimensions - Output: :math:`(N, )`, same shape as the input Examples:: >>> m = Act['swish']() >>> input = torch.randn(2) >>> output = m(input) """ def __init__(self, alpha=1.0): super().__init__() self.alpha = alpha def forward(self, input: 'torch.Tensor') ->torch.Tensor: return input torch.sigmoid(self.alpha * input) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_sigmoid_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tmp3 = tl.sigmoid(tmp2) tmp4 = tmp0 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_sigmoid_0[grid(256)](arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 return buf0, class SwishNew(nn.Module): """Applies the element-wise function: .. math:: \\text{Swish}(x) = x * \\text{Sigmoid}(\\alpha * x) for constant value alpha. Citation: Searching for Activation Functions, Ramachandran et al., 2017, https://arxiv.org/abs/1710.05941. Shape: - Input: :math:`(N, )` where `` means, any number of additional dimensions - Output: :math:`(N, *)`, same shape as the input Examples:: >>> m = Act['swish']() >>> input = torch.randn(2) >>> output = m(input) """ def __init__(self, alpha=1.0): super().__init__() self.alpha = alpha def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	LucasFidon/MONAI	Swish	false	2,591	[ "Apache-2.0" ]	a7ef9d567775dd7a222f93bab08191c0e3532c92	https://github.com/LucasFidon/MONAI/tree/a7ef9d567775dd7a222f93bab08191c0e3532c92
DiceLoss	import collections import torch import warnings from typing import Optional from typing import Union from typing import Any from typing import Callable from typing import Tuple import torch.nn from torch.nn.modules.loss import _Loss from enum import Enum import collections.abc def issequenceiterable(obj: 'Any') ->bool: """ Determine if the object is an iterable sequence and is not a string. """ if torch.is_tensor(obj): return int(obj.dim()) > 0 return isinstance(obj, collections.abc.Iterable) and not isinstance(obj, str) def ensure_tuple(vals: 'Any') ->Tuple[Any, ...]: """ Returns a tuple of `vals`. """ if not issequenceiterable(vals): vals = vals, return tuple(vals) def ensure_tuple_size(tup: 'Any', dim: 'int', pad_val: 'Any'=0) ->Tuple[Any, ...]: """ Returns a copy of `tup` with `dim` values by either shortened or padded with `pad_val` as necessary. """ tup = ensure_tuple(tup) + (pad_val,) * dim return tuple(tup[:dim]) def one_hot(labels: 'torch.Tensor', num_classes: 'int', dtype: 'torch.dtype'=torch.float, dim: 'int'=1) ->torch.Tensor: """ For a tensor `labels` of dimensions B1[spatial_dims], return a tensor of dimensions `BN[spatial_dims]` for `num_classes` N number of classes. Example: For every value v = labels[b,1,h,w], the value in the result at [b,v,h,w] will be 1 and all others 0. Note that this will include the background label, thus a binary mask should be treated as having 2 classes. """ assert labels.dim() > 0, 'labels should have dim of 1 or more.' if labels.ndim < dim + 1: shape = ensure_tuple_size(labels.shape, dim + 1, 1) labels = labels.reshape(shape) sh = list(labels.shape) assert sh[dim ] == 1, 'labels should have a channel with length equals to one.' sh[dim] = num_classes o = torch.zeros(size=sh, dtype=dtype, device=labels.device) labels = o.scatter_(dim=dim, index=labels.long(), value=1) return labels class LossReduction(Enum): """ See also: - :py:class:`monai.losses.dice.DiceLoss` - :py:class:`monai.losses.dice.GeneralizedDiceLoss` - :py:class:`monai.losses.focal_loss.FocalLoss` - :py:class:`monai.losses.tversky.TverskyLoss` """ NONE = 'none' MEAN = 'mean' SUM = 'sum' class DiceLoss(_Loss): """ Compute average Dice loss between two tensors. It can support both multi-classes and multi-labels tasks. Input logits `input` (BNHW[D] where N is number of classes) is compared with ground truth `target` (BNHW[D]). Axis N of `input` is expected to have logit predictions for each class rather than being image channels, while the same axis of `target` can be 1 or N (one-hot format). The `smooth_nr` and `smooth_dr` parameters are values added to the intersection and union components of the inter-over-union calculation to smooth results respectively, these values should be small. The `include_background` class attribute can be set to False for an instance of DiceLoss to exclude the first category (channel index 0) which is by convention assumed to be background. If the non-background segmentations are small compared to the total image size they can get overwhelmed by the signal from the background so excluding it in such cases helps convergence. Milletari, F. et. al. (2016) V-Net: Fully Convolutional Neural Networks forVolumetric Medical Image Segmentation, 3DV, 2016. """ def __init__(self, include_background: 'bool'=True, to_onehot_y: 'bool' =False, sigmoid: 'bool'=False, softmax: 'bool'=False, other_act: 'Optional[Callable]'=None, squared_pred: 'bool'=False, jaccard: 'bool'=False, reduction: 'Union[LossReduction, str]'=LossReduction. MEAN, smooth_nr: 'float'=1e-05, smooth_dr: 'float'=1e-05, batch: 'bool'=False) ->None: """ Args: include_background: if False channel index 0 (background category) is excluded from the calculation. to_onehot_y: whether to convert `y` into the one-hot format. Defaults to False. sigmoid: if True, apply a sigmoid function to the prediction. softmax: if True, apply a softmax function to the prediction. other_act: if don't want to use `sigmoid` or `softmax`, use other callable function to execute other activation layers, Defaults to ``None``. for example: `other_act = torch.tanh`. squared_pred: use squared versions of targets and predictions in the denominator or not. jaccard: compute Jaccard Index (soft IoU) instead of dice or not. reduction: {``"none"``, ``"mean"``, ``"sum"``} Specifies the reduction to apply to the output. Defaults to ``"mean"``. - ``"none"``: no reduction will be applied. - ``"mean"``: the sum of the output will be divided by the number of elements in the output. - ``"sum"``: the output will be summed. smooth_nr: a small constant added to the numerator to avoid zero. smooth_dr: a small constant added to the denominator to avoid nan. batch: whether to sum the intersection and union areas over the batch dimension before the dividing. Defaults to False, a Dice loss value is computed independently from each item in the batch before any `reduction`. Raises: TypeError: When ``other_act`` is not an ``Optional[Callable]``. ValueError: When more than 1 of [``sigmoid=True``, ``softmax=True``, ``other_act is not None``]. Incompatible values. """ super().__init__(reduction=LossReduction(reduction).value) if other_act is not None and not callable(other_act): raise TypeError( f'other_act must be None or callable but is {type(other_act).__name__}.' ) if int(sigmoid) + int(softmax) + int(other_act is not None) > 1: raise ValueError( 'Incompatible values: more than 1 of [sigmoid=True, softmax=True, other_act is not None].' ) self.include_background = include_background self.to_onehot_y = to_onehot_y self.sigmoid = sigmoid self.softmax = softmax self.other_act = other_act self.squared_pred = squared_pred self.jaccard = jaccard self.smooth_nr = float(smooth_nr) self.smooth_dr = float(smooth_dr) self.batch = batch def forward(self, input: 'torch.Tensor', target: 'torch.Tensor' ) ->torch.Tensor: """ Args: input: the shape should be BNH[WD]. target: the shape should be BNH[WD]. Raises: ValueError: When ``self.reduction`` is not one of ["mean", "sum", "none"]. """ if self.sigmoid: input = torch.sigmoid(input) n_pred_ch = input.shape[1] if self.softmax: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `softmax=True` ignored.') else: input = torch.softmax(input, 1) if self.other_act is not None: input = self.other_act(input) if self.to_onehot_y: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `to_onehot_y=True` ignored.') else: target = one_hot(target, num_classes=n_pred_ch) if not self.include_background: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `include_background=False` ignored.' ) else: target = target[:, 1:] input = input[:, 1:] assert target.shape == input.shape, f'ground truth has differing shape ({target.shape}) from input ({input.shape})' reduce_axis = list(range(2, len(input.shape))) if self.batch: reduce_axis = [0] + reduce_axis intersection = torch.sum(target input, dim=reduce_axis) if self.squared_pred: target = torch.pow(target, 2) input = torch.pow(input, 2) ground_o = torch.sum(target, dim=reduce_axis) pred_o = torch.sum(input, dim=reduce_axis) denominator = ground_o + pred_o if self.jaccard: denominator = 2.0 * (denominator - intersection) f: 'torch.Tensor' = 1.0 - (2.0 * intersection + self.smooth_nr) / ( denominator + self.smooth_dr) if self.reduction == LossReduction.MEAN.value: f = torch.mean(f) elif self.reduction == LossReduction.SUM.value: f = torch.sum(f) elif self.reduction == LossReduction.NONE.value: pass else: raise ValueError( f'Unsupported reduction: {self.reduction}, available options are ["mean", "sum", "none"].' ) return f def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import collections from typing import Optional from typing import Union from typing import Any from typing import Callable from typing import Tuple import torch.nn from torch.nn.modules.loss import _Loss from enum import Enum import collections.abc assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_mul_sum_0(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 16 RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 16 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 16 * x0), xmask, other=0.0) tmp2 = tmp0 * tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp5 = tl.where(xmask, tmp3, 0) tmp6 = tl.sum(tmp5, 1)[:, None] tmp7 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp9 = tl.where(xmask, tmp7, 0) tmp10 = tl.sum(tmp9, 1)[:, None] tmp11 = tl.broadcast_to(tmp1, [XBLOCK, RBLOCK]) tmp13 = tl.where(xmask, tmp11, 0) tmp14 = tl.sum(tmp13, 1)[:, None] tl.store(out_ptr0 + x0, tmp6, xmask) tl.store(out_ptr1 + x0, tmp10, xmask) tl.store(out_ptr2 + x0, tmp14, xmask) @triton.jit def triton_per_fused_add_div_mean_mul_rsub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp5 = tl.load(in_ptr1 + r0, None) tmp6 = tl.load(in_ptr2 + r0, None) tmp1 = 2.0 tmp2 = tmp0 * tmp1 tmp3 = 1e-05 tmp4 = tmp2 + tmp3 tmp7 = tmp5 + tmp6 tmp8 = tmp7 + tmp3 tmp9 = tmp4 / tmp8 tmp10 = 1.0 tmp11 = tmp10 - tmp9 tmp12 = tl.broadcast_to(tmp11, [XBLOCK, RBLOCK]) tmp14 = tl.sum(tmp12, 1)[:, None] tmp15 = 16.0 tmp16 = tmp14 / tmp15 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp16, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_per_fused_mul_sum_0[grid(16)](arg1_1, arg0_1, buf0, buf1, buf2, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del arg1_1 buf3 = empty_strided_cuda((), (), torch.float32) buf4 = buf3 del buf3 triton_per_fused_add_div_mean_mul_rsub_1[grid(1)](buf4, buf0, buf1, buf2, 1, 16, XBLOCK=1, num_warps=2, num_stages=1) del buf0 del buf1 del buf2 return buf4, def issequenceiterable(obj: 'Any') ->bool: """ Determine if the object is an iterable sequence and is not a string. """ if torch.is_tensor(obj): return int(obj.dim()) > 0 return isinstance(obj, collections.abc.Iterable) and not isinstance(obj, str) def ensure_tuple(vals: 'Any') ->Tuple[Any, ...]: """ Returns a tuple of `vals`. """ if not issequenceiterable(vals): vals = vals, return tuple(vals) def ensure_tuple_size(tup: 'Any', dim: 'int', pad_val: 'Any'=0) ->Tuple[Any, ...]: """ Returns a copy of `tup` with `dim` values by either shortened or padded with `pad_val` as necessary. """ tup = ensure_tuple(tup) + (pad_val,) * dim return tuple(tup[:dim]) def one_hot(labels: 'torch.Tensor', num_classes: 'int', dtype: 'torch.dtype'=torch.float, dim: 'int'=1) ->torch.Tensor: """ For a tensor `labels` of dimensions B1[spatial_dims], return a tensor of dimensions `BN[spatial_dims]` for `num_classes` N number of classes. Example: For every value v = labels[b,1,h,w], the value in the result at [b,v,h,w] will be 1 and all others 0. Note that this will include the background label, thus a binary mask should be treated as having 2 classes. """ assert labels.dim() > 0, 'labels should have dim of 1 or more.' if labels.ndim < dim + 1: shape = ensure_tuple_size(labels.shape, dim + 1, 1) labels = labels.reshape(*shape) sh = list(labels.shape) assert sh[dim ] == 1, 'labels should have a channel with length equals to one.' sh[dim] = num_classes o = torch.zeros(size=sh, dtype=dtype, device=labels.device) labels = o.scatter_(dim=dim, index=labels.long(), value=1) return labels class LossReduction(Enum): """ See also: - :py:class:`monai.losses.dice.DiceLoss` - :py:class:`monai.losses.dice.GeneralizedDiceLoss` - :py:class:`monai.losses.focal_loss.FocalLoss` - :py:class:`monai.losses.tversky.TverskyLoss` """ NONE = 'none' MEAN = 'mean' SUM = 'sum' class DiceLossNew(_Loss): """ Compute average Dice loss between two tensors. It can support both multi-classes and multi-labels tasks. Input logits `input` (BNHW[D] where N is number of classes) is compared with ground truth `target` (BNHW[D]). Axis N of `input` is expected to have logit predictions for each class rather than being image channels, while the same axis of `target` can be 1 or N (one-hot format). The `smooth_nr` and `smooth_dr` parameters are values added to the intersection and union components of the inter-over-union calculation to smooth results respectively, these values should be small. The `include_background` class attribute can be set to False for an instance of DiceLoss to exclude the first category (channel index 0) which is by convention assumed to be background. If the non-background segmentations are small compared to the total image size they can get overwhelmed by the signal from the background so excluding it in such cases helps convergence. Milletari, F. et. al. (2016) V-Net: Fully Convolutional Neural Networks forVolumetric Medical Image Segmentation, 3DV, 2016. """ def __init__(self, include_background: 'bool'=True, to_onehot_y: 'bool' =False, sigmoid: 'bool'=False, softmax: 'bool'=False, other_act: 'Optional[Callable]'=None, squared_pred: 'bool'=False, jaccard: 'bool'=False, reduction: 'Union[LossReduction, str]'=LossReduction. MEAN, smooth_nr: 'float'=1e-05, smooth_dr: 'float'=1e-05, batch: 'bool'=False) ->None: """ Args: include_background: if False channel index 0 (background category) is excluded from the calculation. to_onehot_y: whether to convert `y` into the one-hot format. Defaults to False. sigmoid: if True, apply a sigmoid function to the prediction. softmax: if True, apply a softmax function to the prediction. other_act: if don't want to use `sigmoid` or `softmax`, use other callable function to execute other activation layers, Defaults to ``None``. for example: `other_act = torch.tanh`. squared_pred: use squared versions of targets and predictions in the denominator or not. jaccard: compute Jaccard Index (soft IoU) instead of dice or not. reduction: {``"none"``, ``"mean"``, ``"sum"``} Specifies the reduction to apply to the output. Defaults to ``"mean"``. - ``"none"``: no reduction will be applied. - ``"mean"``: the sum of the output will be divided by the number of elements in the output. - ``"sum"``: the output will be summed. smooth_nr: a small constant added to the numerator to avoid zero. smooth_dr: a small constant added to the denominator to avoid nan. batch: whether to sum the intersection and union areas over the batch dimension before the dividing. Defaults to False, a Dice loss value is computed independently from each item in the batch before any `reduction`. Raises: TypeError: When ``other_act`` is not an ``Optional[Callable]``. ValueError: When more than 1 of [``sigmoid=True``, ``softmax=True``, ``other_act is not None``]. Incompatible values. """ super().__init__(reduction=LossReduction(reduction).value) if other_act is not None and not callable(other_act): raise TypeError( f'other_act must be None or callable but is {type(other_act).__name__}.' ) if int(sigmoid) + int(softmax) + int(other_act is not None) > 1: raise ValueError( 'Incompatible values: more than 1 of [sigmoid=True, softmax=True, other_act is not None].' ) self.include_background = include_background self.to_onehot_y = to_onehot_y self.sigmoid = sigmoid self.softmax = softmax self.other_act = other_act self.squared_pred = squared_pred self.jaccard = jaccard self.smooth_nr = float(smooth_nr) self.smooth_dr = float(smooth_dr) self.batch = batch def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	LucasFidon/MONAI	DiceLoss	false	2,592	[ "Apache-2.0" ]	a7ef9d567775dd7a222f93bab08191c0e3532c92	https://github.com/LucasFidon/MONAI/tree/a7ef9d567775dd7a222f93bab08191c0e3532c92
softmax_with_multiuse_input	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class softmax_with_multiuse_input(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): x1 = nn.Softmax(dim=-1)(x) x2 = x + x1 return x1, x2 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_add_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr1 + x2, xmask) tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tmp10 = tmp9 + tmp8 tl.store(out_ptr0 + x2, tmp8, xmask) tl.store(out_ptr1 + x2, tmp10, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_add_1[grid(256)](buf0, arg0_1, buf1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del buf0 return buf1, buf2 class softmax_with_multiuse_inputNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0], output[1]	JudeDavis1/intel-extension-for-pytorch	softmax_with_multiuse_input	false	2,593	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
ToRGB	from torch.autograd import Function import math import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def make_resample_kernel(k): """Make resampling kernel for UpFirDn. Args: k (list[int]): A list indicating the 1D resample kernel magnitude. Returns: Tensor: 2D resampled kernel. """ k = torch.tensor(k, dtype=torch.float32) if k.ndim == 1: k = k[None, :] * k[:, None] k /= k.sum() return k def upfirdn2d_native(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1): _, channel, in_h, in_w = input.shape input = input.reshape(-1, in_h, in_w, 1) _, in_h, in_w, minor = input.shape kernel_h, kernel_w = kernel.shape out = input.view(-1, in_h, 1, in_w, 1, minor) out = F.pad(out, [0, 0, 0, up_x - 1, 0, 0, 0, up_y - 1]) out = out.view(-1, in_h * up_y, in_w * up_x, minor) out = F.pad(out, [0, 0, max(pad_x0, 0), max(pad_x1, 0), max(pad_y0, 0), max(pad_y1, 0)]) out = out[:, max(-pad_y0, 0):out.shape[1] - max(-pad_y1, 0), max(- pad_x0, 0):out.shape[2] - max(-pad_x1, 0), :] out = out.permute(0, 3, 1, 2) out = out.reshape([-1, 1, in_h * up_y + pad_y0 + pad_y1, in_w * up_x + pad_x0 + pad_x1]) w = torch.flip(kernel, [0, 1]).view(1, 1, kernel_h, kernel_w) out = F.conv2d(out, w) out = out.reshape(-1, minor, in_h * up_y + pad_y0 + pad_y1 - kernel_h + 1, in_w * up_x + pad_x0 + pad_x1 - kernel_w + 1) out = out.permute(0, 2, 3, 1) out = out[:, ::down_y, ::down_x, :] out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 return out.view(-1, channel, out_h, out_w) def upfirdn2d(input, kernel, up=1, down=1, pad=(0, 0)): if input.device.type == 'cpu': out = upfirdn2d_native(input, kernel, up, up, down, down, pad[0], pad[1], pad[0], pad[1]) else: out = UpFirDn2d.apply(input, kernel, (up, up), (down, down), (pad[0 ], pad[1], pad[0], pad[1])) return out def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class UpFirDn2dBackward(Function): @staticmethod def forward(ctx, grad_output, kernel, grad_kernel, up, down, pad, g_pad, in_size, out_size): up_x, up_y = up down_x, down_y = down g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 = g_pad grad_output = grad_output.reshape(-1, out_size[0], out_size[1], 1) grad_input = upfirdn2d_ext.upfirdn2d(grad_output, grad_kernel, down_x, down_y, up_x, up_y, g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1) grad_input = grad_input.view(in_size[0], in_size[1], in_size[2], in_size[3]) ctx.save_for_backward(kernel) pad_x0, pad_x1, pad_y0, pad_y1 = pad ctx.up_x = up_x ctx.up_y = up_y ctx.down_x = down_x ctx.down_y = down_y ctx.pad_x0 = pad_x0 ctx.pad_x1 = pad_x1 ctx.pad_y0 = pad_y0 ctx.pad_y1 = pad_y1 ctx.in_size = in_size ctx.out_size = out_size return grad_input @staticmethod def backward(ctx, gradgrad_input): kernel, = ctx.saved_tensors gradgrad_input = gradgrad_input.reshape(-1, ctx.in_size[2], ctx. in_size[3], 1) gradgrad_out = upfirdn2d_ext.upfirdn2d(gradgrad_input, kernel, ctx. up_x, ctx.up_y, ctx.down_x, ctx.down_y, ctx.pad_x0, ctx.pad_x1, ctx.pad_y0, ctx.pad_y1) gradgrad_out = gradgrad_out.view(ctx.in_size[0], ctx.in_size[1], ctx.out_size[0], ctx.out_size[1]) return gradgrad_out, None, None, None, None, None, None, None, None class UpFirDn2d(Function): @staticmethod def forward(ctx, input, kernel, up, down, pad): up_x, up_y = up down_x, down_y = down pad_x0, pad_x1, pad_y0, pad_y1 = pad kernel_h, kernel_w = kernel.shape _batch, channel, in_h, in_w = input.shape ctx.in_size = input.shape input = input.reshape(-1, in_h, in_w, 1) ctx.save_for_backward(kernel, torch.flip(kernel, [0, 1])) out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 ctx.out_size = out_h, out_w ctx.up = up_x, up_y ctx.down = down_x, down_y ctx.pad = pad_x0, pad_x1, pad_y0, pad_y1 g_pad_x0 = kernel_w - pad_x0 - 1 g_pad_y0 = kernel_h - pad_y0 - 1 g_pad_x1 = in_w * up_x - out_w * down_x + pad_x0 - up_x + 1 g_pad_y1 = in_h * up_y - out_h * down_y + pad_y0 - up_y + 1 ctx.g_pad = g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 out = upfirdn2d_ext.upfirdn2d(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1) out = out.view(-1, channel, out_h, out_w) return out @staticmethod def backward(ctx, grad_output): kernel, grad_kernel = ctx.saved_tensors grad_input = UpFirDn2dBackward.apply(grad_output, kernel, grad_kernel, ctx.up, ctx.down, ctx.pad, ctx.g_pad, ctx.in_size, ctx.out_size) return grad_input, None, None, None, None class UpFirDnUpsample(nn.Module): """Upsample, FIR filter, and downsample (upsampole version). References: 1. https://docs.scipy.org/doc/scipy/reference/generated/scipy.signal.upfirdn.html # noqa: E501 2. http://www.ece.northwestern.edu/local-apps/matlabhelp/toolbox/signal/upfirdn.html # noqa: E501 Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. factor (int): Upsampling scale factor. Default: 2. """ def __init__(self, resample_kernel, factor=2): super(UpFirDnUpsample, self).__init__() self.kernel = make_resample_kernel(resample_kernel) * factor ** 2 self.factor = factor pad = self.kernel.shape[0] - factor self.pad = (pad + 1) // 2 + factor - 1, pad // 2 def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=self.factor, down=1, pad=self.pad) return out def __repr__(self): return f'{self.__class__.__name__}(factor={self.factor})' class UpFirDnSmooth(nn.Module): """Upsample, FIR filter, and downsample (smooth version). Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. upsample_factor (int): Upsampling scale factor. Default: 1. downsample_factor (int): Downsampling scale factor. Default: 1. kernel_size (int): Kernel size: Deafult: 1. """ def __init__(self, resample_kernel, upsample_factor=1, downsample_factor=1, kernel_size=1): super(UpFirDnSmooth, self).__init__() self.upsample_factor = upsample_factor self.downsample_factor = downsample_factor self.kernel = make_resample_kernel(resample_kernel) if upsample_factor > 1: self.kernel = self.kernel * upsample_factor ** 2 if upsample_factor > 1: pad = self.kernel.shape[0] - upsample_factor - (kernel_size - 1) self.pad = (pad + 1) // 2 + upsample_factor - 1, pad // 2 + 1 elif downsample_factor > 1: pad = self.kernel.shape[0] - downsample_factor + (kernel_size - 1) self.pad = (pad + 1) // 2, pad // 2 else: raise NotImplementedError def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=1, down=1, pad=self.pad) return out def __repr__(self): return ( f'{self.__class__.__name__}(upsample_factor={self.upsample_factor}, downsample_factor={self.downsample_factor})' ) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None \| str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) class ModulatedConv2d(nn.Module): """Modulated Conv2d used in StyleGAN2. There is no bias in ModulatedConv2d. Args: in_channels (int): Channel number of the input. out_channels (int): Channel number of the output. kernel_size (int): Size of the convolving kernel. num_style_feat (int): Channel number of style features. demodulate (bool): Whether to demodulate in the conv layer. Default: True. sample_mode (str \| None): Indicating 'upsample', 'downsample' or None. Default: None. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). eps (float): A value added to the denominator for numerical stability. Default: 1e-8. """ def __init__(self, in_channels, out_channels, kernel_size, num_style_feat, demodulate=True, sample_mode=None, resample_kernel= (1, 3, 3, 1), eps=1e-08): super(ModulatedConv2d, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.kernel_size = kernel_size self.demodulate = demodulate self.sample_mode = sample_mode self.eps = eps if self.sample_mode == 'upsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=2, downsample_factor=1, kernel_size=kernel_size) elif self.sample_mode == 'downsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=1, downsample_factor=2, kernel_size=kernel_size) elif self.sample_mode is None: pass else: raise ValueError( f"Wrong sample mode {self.sample_mode}, supported ones are ['upsample', 'downsample', None]." ) self.scale = 1 / math.sqrt(in_channels * kernel_size ** 2) self.modulation = EqualLinear(num_style_feat, in_channels, bias= True, bias_init_val=1, lr_mul=1, activation=None) self.weight = nn.Parameter(torch.randn(1, out_channels, in_channels, kernel_size, kernel_size)) self.padding = kernel_size // 2 def forward(self, x, style): """Forward function. Args: x (Tensor): Tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). Returns: Tensor: Modulated tensor after convolution. """ b, c, h, w = x.shape style = self.modulation(style).view(b, 1, c, 1, 1) weight = self.scale * self.weight * style if self.demodulate: demod = torch.rsqrt(weight.pow(2).sum([2, 3, 4]) + self.eps) weight = weight * demod.view(b, self.out_channels, 1, 1, 1) weight = weight.view(b * self.out_channels, c, self.kernel_size, self.kernel_size) if self.sample_mode == 'upsample': x = x.view(1, b * c, h, w) weight = weight.view(b, self.out_channels, c, self.kernel_size, self.kernel_size) weight = weight.transpose(1, 2).reshape(b * c, self. out_channels, self.kernel_size, self.kernel_size) out = F.conv_transpose2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, out.shape[2:4]) out = self.smooth(out) elif self.sample_mode == 'downsample': x = self.smooth(x) x = x.view(1, b c, x.shape[2:4]) out = F.conv2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, out.shape[2:4]) else: x = x.view(1, b * c, h, w) out = F.conv2d(x, weight, padding=self.padding, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, kernel_size={self.kernel_size}, demodulate={self.demodulate}, sample_mode={self.sample_mode})' ) class ToRGB(nn.Module): """To RGB from features. Args: in_channels (int): Channel number of input. num_style_feat (int): Channel number of style features. upsample (bool): Whether to upsample. Default: True. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). """ def __init__(self, in_channels, num_style_feat, upsample=True, resample_kernel=(1, 3, 3, 1)): super(ToRGB, self).__init__() if upsample: self.upsample = UpFirDnUpsample(resample_kernel, factor=2) else: self.upsample = None self.modulated_conv = ModulatedConv2d(in_channels, 3, kernel_size=1, num_style_feat=num_style_feat, demodulate=False, sample_mode=None) self.bias = nn.Parameter(torch.zeros(1, 3, 1, 1)) def forward(self, x, style, skip=None): """Forward function. Args: x (Tensor): Feature tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). skip (Tensor): Base/skip tensor. Default: None. Returns: Tensor: RGB images. """ out = self.modulated_conv(x, style) out = out + self.bias if skip is not None: if self.upsample: skip = self.upsample(skip) out = out + skip return out def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'num_style_feat': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch.autograd import Function import math from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex % 12 x0 = xindex % 4 x2 = xindex // 12 x4 = xindex tmp0 = tl.load(in_ptr0 + x3, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x4, tmp4, xmask) @triton.jit def triton_poi_fused_add_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 192 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 3 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5, primals_6 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (1, 3, 4, 1, 1), (12, 4, 1, 1, 1)) assert_size_stride(primals_6, (1, 3, 1, 1), (3, 1, 1, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(16)](primals_3, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_3 buf1 = empty_strided_cuda((4,), (1,), torch.float32) triton_poi_fused_mul_1[grid(4)](primals_2, buf1, 4, XBLOCK=4, num_warps=1, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(buf1, primals_4, reinterpret_tensor(buf0, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del buf0 del buf1 buf3 = empty_strided_cuda((4, 3, 4, 1, 1), (12, 4, 1, 1, 1), torch. float32) triton_poi_fused_mul_2[grid(48)](primals_5, buf2, buf3, 48, XBLOCK= 64, num_warps=1, num_stages=1) buf4 = extern_kernels.convolution(reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0), reinterpret_tensor(buf3, (12, 4, 1, 1), (4, 1, 0, 0), 0), stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf4, (1, 12, 4, 4), (192, 16, 4, 1)) buf5 = reinterpret_tensor(buf4, (4, 3, 4, 4), (48, 16, 4, 1), 0) del buf4 triton_poi_fused_add_3[grid(192)](buf5, primals_6, 192, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 return buf5, primals_4, primals_5, buf2, reinterpret_tensor(buf3, (12, 4, 1, 1), (4, 1, 1, 1), 0), reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0) def make_resample_kernel(k): """Make resampling kernel for UpFirDn. Args: k (list[int]): A list indicating the 1D resample kernel magnitude. Returns: Tensor: 2D resampled kernel. """ k = torch.tensor(k, dtype=torch.float32) if k.ndim == 1: k = k[None, :] * k[:, None] k /= k.sum() return k def upfirdn2d_native(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1): _, channel, in_h, in_w = input.shape input = input.reshape(-1, in_h, in_w, 1) _, in_h, in_w, minor = input.shape kernel_h, kernel_w = kernel.shape out = input.view(-1, in_h, 1, in_w, 1, minor) out = F.pad(out, [0, 0, 0, up_x - 1, 0, 0, 0, up_y - 1]) out = out.view(-1, in_h * up_y, in_w * up_x, minor) out = F.pad(out, [0, 0, max(pad_x0, 0), max(pad_x1, 0), max(pad_y0, 0), max(pad_y1, 0)]) out = out[:, max(-pad_y0, 0):out.shape[1] - max(-pad_y1, 0), max(- pad_x0, 0):out.shape[2] - max(-pad_x1, 0), :] out = out.permute(0, 3, 1, 2) out = out.reshape([-1, 1, in_h * up_y + pad_y0 + pad_y1, in_w * up_x + pad_x0 + pad_x1]) w = torch.flip(kernel, [0, 1]).view(1, 1, kernel_h, kernel_w) out = F.conv2d(out, w) out = out.reshape(-1, minor, in_h * up_y + pad_y0 + pad_y1 - kernel_h + 1, in_w * up_x + pad_x0 + pad_x1 - kernel_w + 1) out = out.permute(0, 2, 3, 1) out = out[:, ::down_y, ::down_x, :] out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 return out.view(-1, channel, out_h, out_w) def upfirdn2d(input, kernel, up=1, down=1, pad=(0, 0)): if input.device.type == 'cpu': out = upfirdn2d_native(input, kernel, up, up, down, down, pad[0], pad[1], pad[0], pad[1]) else: out = UpFirDn2d.apply(input, kernel, (up, up), (down, down), (pad[0 ], pad[1], pad[0], pad[1])) return out def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class UpFirDn2dBackward(Function): @staticmethod def forward(ctx, grad_output, kernel, grad_kernel, up, down, pad, g_pad, in_size, out_size): up_x, up_y = up down_x, down_y = down g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 = g_pad grad_output = grad_output.reshape(-1, out_size[0], out_size[1], 1) grad_input = upfirdn2d_ext.upfirdn2d(grad_output, grad_kernel, down_x, down_y, up_x, up_y, g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1) grad_input = grad_input.view(in_size[0], in_size[1], in_size[2], in_size[3]) ctx.save_for_backward(kernel) pad_x0, pad_x1, pad_y0, pad_y1 = pad ctx.up_x = up_x ctx.up_y = up_y ctx.down_x = down_x ctx.down_y = down_y ctx.pad_x0 = pad_x0 ctx.pad_x1 = pad_x1 ctx.pad_y0 = pad_y0 ctx.pad_y1 = pad_y1 ctx.in_size = in_size ctx.out_size = out_size return grad_input @staticmethod def backward(ctx, gradgrad_input): kernel, = ctx.saved_tensors gradgrad_input = gradgrad_input.reshape(-1, ctx.in_size[2], ctx. in_size[3], 1) gradgrad_out = upfirdn2d_ext.upfirdn2d(gradgrad_input, kernel, ctx. up_x, ctx.up_y, ctx.down_x, ctx.down_y, ctx.pad_x0, ctx.pad_x1, ctx.pad_y0, ctx.pad_y1) gradgrad_out = gradgrad_out.view(ctx.in_size[0], ctx.in_size[1], ctx.out_size[0], ctx.out_size[1]) return gradgrad_out, None, None, None, None, None, None, None, None class UpFirDn2d(Function): @staticmethod def forward(ctx, input, kernel, up, down, pad): up_x, up_y = up down_x, down_y = down pad_x0, pad_x1, pad_y0, pad_y1 = pad kernel_h, kernel_w = kernel.shape _batch, channel, in_h, in_w = input.shape ctx.in_size = input.shape input = input.reshape(-1, in_h, in_w, 1) ctx.save_for_backward(kernel, torch.flip(kernel, [0, 1])) out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 ctx.out_size = out_h, out_w ctx.up = up_x, up_y ctx.down = down_x, down_y ctx.pad = pad_x0, pad_x1, pad_y0, pad_y1 g_pad_x0 = kernel_w - pad_x0 - 1 g_pad_y0 = kernel_h - pad_y0 - 1 g_pad_x1 = in_w * up_x - out_w * down_x + pad_x0 - up_x + 1 g_pad_y1 = in_h * up_y - out_h * down_y + pad_y0 - up_y + 1 ctx.g_pad = g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 out = upfirdn2d_ext.upfirdn2d(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1) out = out.view(-1, channel, out_h, out_w) return out @staticmethod def backward(ctx, grad_output): kernel, grad_kernel = ctx.saved_tensors grad_input = UpFirDn2dBackward.apply(grad_output, kernel, grad_kernel, ctx.up, ctx.down, ctx.pad, ctx.g_pad, ctx.in_size, ctx.out_size) return grad_input, None, None, None, None class UpFirDnUpsample(nn.Module): """Upsample, FIR filter, and downsample (upsampole version). References: 1. https://docs.scipy.org/doc/scipy/reference/generated/scipy.signal.upfirdn.html # noqa: E501 2. http://www.ece.northwestern.edu/local-apps/matlabhelp/toolbox/signal/upfirdn.html # noqa: E501 Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. factor (int): Upsampling scale factor. Default: 2. """ def __init__(self, resample_kernel, factor=2): super(UpFirDnUpsample, self).__init__() self.kernel = make_resample_kernel(resample_kernel) * factor ** 2 self.factor = factor pad = self.kernel.shape[0] - factor self.pad = (pad + 1) // 2 + factor - 1, pad // 2 def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=self.factor, down=1, pad=self.pad) return out def __repr__(self): return f'{self.__class__.__name__}(factor={self.factor})' class UpFirDnSmooth(nn.Module): """Upsample, FIR filter, and downsample (smooth version). Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. upsample_factor (int): Upsampling scale factor. Default: 1. downsample_factor (int): Downsampling scale factor. Default: 1. kernel_size (int): Kernel size: Deafult: 1. """ def __init__(self, resample_kernel, upsample_factor=1, downsample_factor=1, kernel_size=1): super(UpFirDnSmooth, self).__init__() self.upsample_factor = upsample_factor self.downsample_factor = downsample_factor self.kernel = make_resample_kernel(resample_kernel) if upsample_factor > 1: self.kernel = self.kernel * upsample_factor ** 2 if upsample_factor > 1: pad = self.kernel.shape[0] - upsample_factor - (kernel_size - 1) self.pad = (pad + 1) // 2 + upsample_factor - 1, pad // 2 + 1 elif downsample_factor > 1: pad = self.kernel.shape[0] - downsample_factor + (kernel_size - 1) self.pad = (pad + 1) // 2, pad // 2 else: raise NotImplementedError def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=1, down=1, pad=self.pad) return out def __repr__(self): return ( f'{self.__class__.__name__}(upsample_factor={self.upsample_factor}, downsample_factor={self.downsample_factor})' ) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None \| str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) class ModulatedConv2d(nn.Module): """Modulated Conv2d used in StyleGAN2. There is no bias in ModulatedConv2d. Args: in_channels (int): Channel number of the input. out_channels (int): Channel number of the output. kernel_size (int): Size of the convolving kernel. num_style_feat (int): Channel number of style features. demodulate (bool): Whether to demodulate in the conv layer. Default: True. sample_mode (str \| None): Indicating 'upsample', 'downsample' or None. Default: None. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). eps (float): A value added to the denominator for numerical stability. Default: 1e-8. """ def __init__(self, in_channels, out_channels, kernel_size, num_style_feat, demodulate=True, sample_mode=None, resample_kernel= (1, 3, 3, 1), eps=1e-08): super(ModulatedConv2d, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.kernel_size = kernel_size self.demodulate = demodulate self.sample_mode = sample_mode self.eps = eps if self.sample_mode == 'upsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=2, downsample_factor=1, kernel_size=kernel_size) elif self.sample_mode == 'downsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=1, downsample_factor=2, kernel_size=kernel_size) elif self.sample_mode is None: pass else: raise ValueError( f"Wrong sample mode {self.sample_mode}, supported ones are ['upsample', 'downsample', None]." ) self.scale = 1 / math.sqrt(in_channels * kernel_size ** 2) self.modulation = EqualLinear(num_style_feat, in_channels, bias= True, bias_init_val=1, lr_mul=1, activation=None) self.weight = nn.Parameter(torch.randn(1, out_channels, in_channels, kernel_size, kernel_size)) self.padding = kernel_size // 2 def forward(self, x, style): """Forward function. Args: x (Tensor): Tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). Returns: Tensor: Modulated tensor after convolution. """ b, c, h, w = x.shape style = self.modulation(style).view(b, 1, c, 1, 1) weight = self.scale * self.weight * style if self.demodulate: demod = torch.rsqrt(weight.pow(2).sum([2, 3, 4]) + self.eps) weight = weight * demod.view(b, self.out_channels, 1, 1, 1) weight = weight.view(b * self.out_channels, c, self.kernel_size, self.kernel_size) if self.sample_mode == 'upsample': x = x.view(1, b * c, h, w) weight = weight.view(b, self.out_channels, c, self.kernel_size, self.kernel_size) weight = weight.transpose(1, 2).reshape(b * c, self. out_channels, self.kernel_size, self.kernel_size) out = F.conv_transpose2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, out.shape[2:4]) out = self.smooth(out) elif self.sample_mode == 'downsample': x = self.smooth(x) x = x.view(1, b c, x.shape[2:4]) out = F.conv2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, out.shape[2:4]) else: x = x.view(1, b * c, h, w) out = F.conv2d(x, weight, padding=self.padding, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, kernel_size={self.kernel_size}, demodulate={self.demodulate}, sample_mode={self.sample_mode})' ) class ToRGBNew(nn.Module): """To RGB from features. Args: in_channels (int): Channel number of input. num_style_feat (int): Channel number of style features. upsample (bool): Whether to upsample. Default: True. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). """ def __init__(self, in_channels, num_style_feat, upsample=True, resample_kernel=(1, 3, 3, 1)): super(ToRGBNew, self).__init__() if upsample: self.upsample = UpFirDnUpsample(resample_kernel, factor=2) else: self.upsample = None self.modulated_conv = ModulatedConv2d(in_channels, 3, kernel_size=1, num_style_feat=num_style_feat, demodulate=False, sample_mode=None) self.bias = nn.Parameter(torch.zeros(1, 3, 1, 1)) def forward(self, input_0, input_1): primals_6 = self.bias primals_5 = self.modulated_conv.weight primals_3 = self.modulated_conv.modulation.weight primals_2 = self.modulated_conv.modulation.bias primals_1 = input_0 primals_4 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6]) return output[0]	Lotayou/BasicSR	ToRGB	false	2,594	[ "Apache-2.0", "MIT" ]	6cf9a706dd680d54f7dc26e87318ff79f76c0dbf	https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf
hswish	import torch import torch.onnx import torch import torch.nn as nn import torch.nn.functional as F class hswish(nn.Module): def forward(self, x): out = x * F.relu6(x + 3, inplace=True) / 6 return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.onnx import torch import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_div_hardtanh_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 3.0 tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = triton_helpers.maximum(tmp2, tmp3) tmp5 = 6.0 tmp6 = triton_helpers.minimum(tmp4, tmp5) tmp7 = tmp0 * tmp6 tmp8 = 0.16666666666666666 tmp9 = tmp7 * tmp8 tl.store(out_ptr0 + x0, tmp9, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_div_hardtanh_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class hswishNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]	LukasKratochvila/pytorch-ssd	hswish	false	2,595	[ "MIT" ]	de6ed2be6ce0b03634d4cbf41622cfe5c87d077c	https://github.com/LukasKratochvila/pytorch-ssd/tree/de6ed2be6ce0b03634d4cbf41622cfe5c87d077c
GeneratorGCN	from torch.nn import Module import math import torch import torch.nn.functional as F from torch.nn.parameter import Parameter from torch.nn.modules.module import Module import torch.nn as nn from torch.nn import Parameter from torch.nn import Module class GraphConvolution(Module): """ Simple GCN layer, similar to https://arxiv.org/abs/1609.02907 """ def __init__(self, in_features, out_features, bias=True): super(GraphConvolution, self).__init__() self.in_features = in_features self.out_features = out_features self.weight = Parameter(torch.FloatTensor(in_features, out_features)) if bias: self.bias = Parameter(torch.FloatTensor(out_features)) else: self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self): stdv = 1.0 / math.sqrt(self.weight.size(1)) torch.nn.init.kaiming_uniform_(self.weight) if self.bias is not None: self.bias.data.uniform_(-stdv, stdv) def forward(self, input, adj): support = torch.mm(input, self.weight) output = torch.spmm(adj, support) if self.bias is not None: return output + self.bias else: return output def __repr__(self): return self.__class__.__name__ + ' (' + str(self.in_features ) + ' -> ' + str(self.out_features) + ')' class GeneratorGCN(nn.Module): def __init__(self, nfeat, nhid, nclass, dropout, NN): super(GeneratorGCN, self).__init__() self.gc1 = GraphConvolution(nfeat, nhid) self.gc2 = GraphConvolution(nhid, nhid) self.gc3 = GraphConvolution(nhid, nclass) self.dropout = dropout self.NN = NN def apply_bn(self, x): """ Batch normalization of 3D tensor x """ bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, x, adj): x = F.relu(self.gc1(x, adj)) x = F.relu(self.gc2(x, adj)) x = F.relu(self.gc3(x, adj)) return x def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'nfeat': 4, 'nhid': 4, 'nclass': 4, 'dropout': 0.5, 'NN': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch.nn import Module import math from torch.nn.parameter import Parameter from torch.nn.modules.module import Module import torch.nn as nn from torch.nn import Parameter from torch.nn import Module assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_relu_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, xmask) @triton.jit def triton_poi_fused_add_relu_threshold_backward_1(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4,), (1,)) assert_size_stride(primals_5, (4, 4), (4, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_2, primals_1, out=buf0) del primals_1 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf0, out=buf1) buf2 = buf1 del buf1 get_raw_stream(0) triton_poi_fused_add_relu_0[grid(16)](buf2, primals_4, 16, XBLOCK= 16, num_warps=1, num_stages=1) del primals_4 buf3 = buf0 del buf0 extern_kernels.mm(buf2, primals_5, out=buf3) buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf3, out=buf4) buf5 = buf4 del buf4 triton_poi_fused_add_relu_0[grid(16)](buf5, primals_6, 16, XBLOCK= 16, num_warps=1, num_stages=1) del primals_6 buf6 = buf3 del buf3 extern_kernels.mm(buf5, primals_7, out=buf6) buf7 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf6, out=buf7) del buf6 buf8 = buf7 del buf7 buf9 = empty_strided_cuda((4, 4), (4, 1), torch.bool) triton_poi_fused_add_relu_threshold_backward_1[grid(16)](buf8, primals_8, buf9, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_8 return buf8, buf2, buf5, buf9, reinterpret_tensor(primals_3, (4, 4), (1, 4), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0 ), reinterpret_tensor(primals_5, (4, 4), (1, 4), 0 ), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0) class GraphConvolution(Module): """ Simple GCN layer, similar to https://arxiv.org/abs/1609.02907 """ def __init__(self, in_features, out_features, bias=True): super(GraphConvolution, self).__init__() self.in_features = in_features self.out_features = out_features self.weight = Parameter(torch.FloatTensor(in_features, out_features)) if bias: self.bias = Parameter(torch.FloatTensor(out_features)) else: self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self): stdv = 1.0 / math.sqrt(self.weight.size(1)) torch.nn.init.kaiming_uniform_(self.weight) if self.bias is not None: self.bias.data.uniform_(-stdv, stdv) def forward(self, input, adj): support = torch.mm(input, self.weight) output = torch.spmm(adj, support) if self.bias is not None: return output + self.bias else: return output def __repr__(self): return self.__class__.__name__ + ' (' + str(self.in_features ) + ' -> ' + str(self.out_features) + ')' class GeneratorGCNNew(nn.Module): def __init__(self, nfeat, nhid, nclass, dropout, NN): super(GeneratorGCNNew, self).__init__() self.gc1 = GraphConvolution(nfeat, nhid) self.gc2 = GraphConvolution(nhid, nhid) self.gc3 = GraphConvolution(nhid, nclass) self.dropout = dropout self.NN = NN def apply_bn(self, x): """ Batch normalization of 3D tensor x """ bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, input_0, input_1): primals_1 = self.gc1.weight primals_4 = self.gc1.bias primals_2 = self.gc2.weight primals_6 = self.gc2.bias primals_3 = self.gc3.weight primals_8 = self.gc3.bias primals_5 = input_0 primals_7 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8]) return output[0]	LinChen-65/pygcn	GeneratorGCN	false	2,596	[ "MIT" ]	0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb	https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb
Bottleneck_v2	import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Bottleneck_v2(nn.Module): def __init__(self): super(Bottleneck_v2, self).__init__() self.conv = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv1 = nn.Conv2d(256, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, x): x = self.conv(x) y1 = self.conv1(x).relu_() y2 = self.conv2(y1).relu_() y3 = self.conv3(y2) y3 += x return y3.relu_() def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 256 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, None) @triton.jit def triton_poi_fused_convolution_relu_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 64 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, None) @triton.jit def triton_poi_fused_add_convolution_relu_4(in_ptr0, in_ptr1, in_ptr2, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 4096 y1 = yindex // 4096 tmp0 = tl.load(in_ptr0 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = tl.full([1, 1], 0, tl.int32) tmp6 = triton_helpers.maximum(tmp5, tmp4) tl.store(out_ptr0 + (y0 + 4096 * x2 + 1048576 * y1), tmp6, xmask) @triton.jit def triton_poi_fused_threshold_backward_5(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 256 y1 = yindex // 256 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), None, eviction_policy= 'evict_last') tmp1 = 0.0 tmp2 = tmp0 <= tmp1 tl.store(out_ptr0 + (y0 + 256 * x2 + 1048576 * y1), tmp2, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_2, (256,), (1,)) assert_size_stride(primals_3, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_4, (64, 256, 1, 1), (256, 1, 1, 1)) assert_size_stride(primals_5, (64,), (1,)) assert_size_stride(primals_6, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_7, (64,), (1,)) assert_size_stride(primals_8, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_9, (256,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) get_raw_stream(0) triton_poi_fused_0[grid(256, 4096)](primals_3, buf0, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_3 buf1 = empty_strided_cuda((64, 64, 3, 3), (576, 1, 192, 64), torch. float32) triton_poi_fused_1[grid(4096, 9)](primals_6, buf1, 4096, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_6 buf2 = extern_kernels.convolution(buf0, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf3 = buf2 del buf2 triton_poi_fused_convolution_2[grid(4194304)](buf3, primals_2, 4194304, XBLOCK=1024, num_warps=4, num_stages=1) del primals_2 buf4 = extern_kernels.convolution(buf3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_3[grid(1048576)](buf5, primals_5, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 buf6 = extern_kernels.convolution(buf5, buf1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf7 = buf6 del buf6 triton_poi_fused_convolution_relu_3[grid(1048576)](buf7, primals_7, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_7 buf8 = extern_kernels.convolution(buf7, primals_8, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf8, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf9 = empty_strided_cuda((4, 256, 64, 64), (1048576, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_relu_4[grid(16384, 256)](buf8, primals_9, buf3, buf9, 16384, 256, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del buf8 del primals_9 buf10 = empty_strided_cuda((4, 256, 64, 64), (1048576, 1, 16384, 256), torch.bool) triton_poi_fused_threshold_backward_5[grid(1024, 4096)](buf9, buf10, 1024, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) return (buf9, primals_1, buf0, primals_4, buf1, primals_8, buf3, buf5, buf7, buf10) class Bottleneck_v2New(nn.Module): def __init__(self): super(Bottleneck_v2New, self).__init__() self.conv = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv1 = nn.Conv2d(256, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_4 = self.conv1.weight primals_5 = self.conv1.bias primals_6 = self.conv2.weight primals_7 = self.conv2.bias primals_8 = self.conv3.weight primals_9 = self.conv3.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]	JudeDavis1/intel-extension-for-pytorch	Bottleneck_v2	false	2,597	[ "Apache-2.0" ]	364e34cb4917a709f5108c07d4005bf82f3d5067	https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067
SoftEntropy	import torch import torch.nn.functional as F import torch.nn as nn from torch.nn import * class SoftEntropy(nn.Module): def __init__(self): super(SoftEntropy, self).__init__() self.logsoftmax = nn.LogSoftmax(dim=1) def forward(self, inputs, targets): log_probs = self.logsoftmax(inputs) loss = (-F.softmax(targets, dim=1).detach() * log_probs).mean(0).sum() return loss def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]	import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn from torch.nn import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x3, tmp9, xmask) @triton.jit def triton_poi_fused__log_softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused__log_softmax__softmax_mul_neg_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp10 = tl.load(in_ptr1 + x3, xmask) tmp11 = tl.load(in_ptr1 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp13 = tl.load(in_ptr1 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp16 = tl.load(in_ptr1 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp19 = tl.load(in_ptr1 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tmp9 = -tmp8 tmp12 = tl_math.exp(tmp11) tmp14 = tl_math.exp(tmp13) tmp15 = tmp12 + tmp14 tmp17 = tl_math.exp(tmp16) tmp18 = tmp15 + tmp17 tmp20 = tl_math.exp(tmp19) tmp21 = tmp18 + tmp20 tmp22 = tl_math.log(tmp21) tmp23 = tmp10 - tmp22 tmp24 = tmp9 * tmp23 tl.store(out_ptr0 + x3, tmp24, xmask) @triton.jit def triton_per_fused_mean_sum_3(in_ptr0, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr0 + (64 + r0), None) tmp3 = tl.load(in_ptr0 + (128 + r0), None) tmp5 = tl.load(in_ptr0 + (192 + r0), None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tmp9 = tl.broadcast_to(tmp8, [XBLOCK, RBLOCK]) tmp11 = tl.sum(tmp9, 1)[:, None] tl.store(out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp11, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg1_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax_1[grid(256)](arg0_1, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax__softmax_mul_neg_2[grid(256)](buf0, buf1, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf0 del buf1 buf3 = empty_strided_cuda((), (), torch.float32) triton_per_fused_mean_sum_3[grid(1)](buf2, buf3, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del buf2 return buf3, class SoftEntropyNew(nn.Module): def __init__(self): super(SoftEntropyNew, self).__init__() self.logsoftmax = nn.LogSoftmax(dim=1) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]	LunarShen/SECRET	SoftEntropy	false	2,598	[ "MIT" ]	0f652e63ce760ece8690cbad013f0d9bdb341e84	https://github.com/LunarShen/SECRET/tree/0f652e63ce760ece8690cbad013f0d9bdb341e84
UPChannelRPN	import torch import torch.nn.functional as F import torch.nn as nn def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class RPN(nn.Module): def __init__(self): super(RPN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelRPN(RPN): def __init__(self, anchor_num=5, feature_in=256): super(UPChannelRPN, self).__init__() cls_output = 2 * anchor_num loc_output = 4 * anchor_num self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, z_f, x_f): cls_kernel = self.template_cls_conv(z_f) loc_kernel = self.template_loc_conv(z_f) cls_feature = self.search_cls_conv(x_f) loc_feature = self.search_loc_conv(x_f) cls = xcorr_fast(cls_feature, cls_kernel) loc = self.loc_adjust(xcorr_fast(loc_feature, loc_kernel)) return cls, loc def get_inputs(): return [torch.rand([4, 256, 64, 64]), torch.rand([4, 256, 64, 64])] def get_init_inputs(): return [[], {}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional as F import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_view_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 2560 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 3844 % 256 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_poi_fused_convolution_view_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 5120 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 80 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 20 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12 ) = args args.clear() assert_size_stride(primals_1, (2560, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_2, (2560,), (1,)) assert_size_stride(primals_3, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_4, (5120, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_5, (5120,), (1,)) assert_size_stride(primals_6, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_9, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_10, (256,), (1,)) assert_size_stride(primals_11, (20, 20, 1, 1), (20, 1, 1, 1)) assert_size_stride(primals_12, (20,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 2560, 62, 62), (9840640, 3844, 62, 1)) buf1 = extern_kernels.convolution(primals_3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 5120, 62, 62), (19681280, 3844, 62, 1)) buf2 = extern_kernels.convolution(primals_8, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf3 = extern_kernels.convolution(primals_8, primals_9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf4 = buf0 del buf0 buf5 = reinterpret_tensor(buf4, (40, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf4 get_raw_stream(0) triton_poi_fused_convolution_view_0[grid(39362560)](buf5, primals_2, 39362560, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf6 = buf2 del buf2 triton_poi_fused_convolution_1[grid(3936256)](buf6, primals_7, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_7 buf7 = extern_kernels.convolution(reinterpret_tensor(buf6, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf5, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf7, (1, 40, 1, 1), (40, 1, 1, 1)) buf8 = buf1 del buf1 buf9 = reinterpret_tensor(buf8, (80, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf8 triton_poi_fused_convolution_view_2[grid(78725120)](buf9, primals_5, 78725120, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf10 = buf3 del buf3 triton_poi_fused_convolution_1[grid(3936256)](buf10, primals_10, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_10 buf11 = extern_kernels.convolution(reinterpret_tensor(buf10, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf11, (1, 80, 1, 1), (80, 1, 1, 1)) buf12 = extern_kernels.convolution(reinterpret_tensor(buf11, (4, 20, 1, 1), (20, 1, 1, 1), 0), primals_11, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf12, (4, 20, 1, 1), (20, 1, 1, 1)) buf13 = buf12 del buf12 triton_poi_fused_convolution_3[grid(80)](buf13, primals_12, 80, XBLOCK=128, num_warps=4, num_stages=1) del primals_12 return (reinterpret_tensor(buf7, (4, 10, 1, 1), (10, 1, 1, 1), 0), buf13, primals_1, primals_3, primals_4, primals_6, primals_8, primals_9, primals_11, buf5, reinterpret_tensor(buf6, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), buf9, reinterpret_tensor(buf10, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), reinterpret_tensor(buf11, (4, 20, 1, 1), (20, 1, 1, 1), 0)) def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class RPN(nn.Module): def __init__(self): super(RPN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelRPNNew(RPN): def __init__(self, anchor_num=5, feature_in=256): super(UPChannelRPNNew, self).__init__() cls_output = 2 * anchor_num loc_output = 4 * anchor_num self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, input_0, input_1): primals_1 = self.template_cls_conv.weight primals_2 = self.template_cls_conv.bias primals_4 = self.template_loc_conv.weight primals_5 = self.template_loc_conv.bias primals_6 = self.search_cls_conv.weight primals_7 = self.search_cls_conv.bias primals_9 = self.search_loc_conv.weight primals_10 = self.search_loc_conv.bias primals_11 = self.loc_adjust.weight primals_12 = self.loc_adjust.bias primals_3 = input_0 primals_8 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12]) return output[0], output[1]	IRASatUC/pysot	UPChannelRPN	false	2,599	[ "Apache-2.0" ]	2bbc5c0938b56899e5caead84983e3311f1d1911	https://github.com/IRASatUC/pysot/tree/2bbc5c0938b56899e5caead84983e3311f1d1911
MyLinear	import torch from torch import nn from torch.nn import functional as F class MyLinear(nn.Module): def __init__(self, in_units, units): super().__init__() self.weight = nn.Parameter(torch.randn(in_units, units)) self.bias = nn.Parameter(torch.randn(units)) def forward(self, X): linear = torch.matmul(X, self.weight.data) + self.bias.data return F.relu(linear) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_units': 4, 'units': 4}]	import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_relu_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4), (4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(arg1_1, (64, 4), (4, 1), 0), arg0_1, out=buf0) del arg0_1 del arg1_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_relu_0[grid(256)](buf1, arg2_1, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg2_1 return buf1, class MyLinearNew(nn.Module): def __init__(self, in_units, units): super().__init__() self.weight = nn.Parameter(torch.randn(in_units, units)) self.bias = nn.Parameter(torch.randn(units)) def forward(self, input_0): arg0_1 = self.weight arg2_1 = self.bias arg1_1 = input_0 output = call([arg0_1, arg1_1, arg2_1]) return output[0]	JunoCheon/D2L	MyLinear	false	2,600	[ "MIT" ]	9464709862e55151aec28fc637c5942738bdd72b	https://github.com/JunoCheon/D2L/tree/9464709862e55151aec28fc637c5942738bdd72b

FocalLoss

import torch from torch import nn class FocalLoss(nn.Module): def __init__(self, gamma=0, eps=1e-07): super(FocalLoss, self).__init__() self.gamma = gamma self.eps = eps self.ce = torch.nn.CrossEntropyLoss(reduction='none') def forward(self, input, target): logp = self.ce(input, target) p = torch.exp(-logp) loss = (1 - p) ** self.gamma * logp return loss.mean() def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__log_softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_per_fused__log_softmax_exp_mean_mul_neg_pow_rsub_sum_1(in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex % 16 r1 = rindex // 16 tmp0 = tl.load(in_ptr0 + (r0 + 64 * r1), None) tmp2 = tl.load(in_ptr0 + (16 + r0 + 64 * r1), None) tmp5 = tl.load(in_ptr0 + (32 + r0 + 64 * r1), None) tmp8 = tl.load(in_ptr0 + (48 + r0 + 64 * r1), None) tmp13 = tl.load(in_ptr1 + (r0 + 64 * r1), None) tmp16 = tl.load(in_ptr1 + (16 + r0 + 64 * r1), None) tmp20 = tl.load(in_ptr1 + (32 + r0 + 64 * r1), None) tmp24 = tl.load(in_ptr1 + (48 + r0 + 64 * r1), None) tmp1 = tl_math.exp(tmp0) tmp3 = tl_math.exp(tmp2) tmp4 = tmp1 + tmp3 tmp6 = tl_math.exp(tmp5) tmp7 = tmp4 + tmp6 tmp9 = tl_math.exp(tmp8) tmp10 = tmp7 + tmp9 tmp11 = tl_math.log(tmp10) tmp12 = tmp0 - tmp11 tmp14 = tmp12 * tmp13 tmp15 = tmp2 - tmp11 tmp17 = tmp15 * tmp16 tmp18 = tmp14 + tmp17 tmp19 = tmp5 - tmp11 tmp21 = tmp19 * tmp20 tmp22 = tmp18 + tmp21 tmp23 = tmp8 - tmp11 tmp25 = tmp23 * tmp24 tmp26 = tmp22 + tmp25 tmp27 = -tmp26 tmp28 = -tmp27 tmp29 = tl_math.exp(tmp28) tmp30 = 1.0 tmp30 - tmp29 tmp32 = tmp30 * tmp27 tmp33 = tl.broadcast_to(tmp32, [XBLOCK, RBLOCK]) tmp35 = tl.sum(tmp33, 1)[:, None] tmp36 = 64.0 tmp37 = tmp35 / tmp36 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp37, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__log_softmax_0[grid(256)](arg1_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg1_1 buf2 = empty_strided_cuda((), (), torch.float32) buf3 = buf2 del buf2 triton_per_fused__log_softmax_exp_mean_mul_neg_pow_rsub_sum_1[grid(1)]( buf3, buf0, arg0_1, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del buf0 return buf3, class FocalLossNew(nn.Module): def __init__(self, gamma=0, eps=1e-07): super(FocalLossNew, self).__init__() self.gamma = gamma self.eps = eps self.ce = torch.nn.CrossEntropyLoss(reduction='none') def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Lascarfo/kaggle-landmark-recognition-2020-1st-place

FocalLoss

false

2,501

[ "MIT" ]

0

f9007d81e59ecd1311bdea5586a426b8973a2eb8

https://github.com/Lascarfo/kaggle-landmark-recognition-2020-1st-place/tree/f9007d81e59ecd1311bdea5586a426b8973a2eb8

Attention

import math import torch import torch.nn as nn class Attention(nn.Module): """ Using two types of attention mechanism: "Dot" and "Bahdanau" """ def __init__(self, hidden_size, use_tanh=False, C=10, name='Bahdanau', use_cuda=True): super(Attention, self).__init__() self.use_tanh = use_tanh self.C = C self.name = name if name == 'Bahdanau': self.W_query = nn.Linear(hidden_size, hidden_size) self.W_ref = nn.Conv1d(hidden_size, hidden_size, 1, 1) V = torch.FloatTensor(hidden_size) if use_cuda: V = V self.V = nn.Parameter(V) self.V.data.uniform_(-(1.0 / math.sqrt(hidden_size)), 1.0 / math.sqrt(hidden_size)) def forward(self, query, ref): """ Args: query: [batch_size x hidden_size] ref: [batch_size x seq_len x hidden_size] """ batch_size = ref.size(0) seq_len = ref.size(1) if self.name == 'Bahdanau': ref = ref.permute(0, 2, 1) query = self.W_query(query).unsqueeze(2) ref = self.W_ref(ref) expanded_query = query.repeat(1, 1, seq_len) V = self.V.unsqueeze(0).unsqueeze(0).repeat(batch_size, 1, 1) logits = torch.bmm(V, torch.tanh(expanded_query + ref)).squeeze(1) elif self.name == 'Dot': query = query.unsqueeze(2) logits = torch.bmm(ref, query).squeeze(2) ref = ref.permute(0, 2, 1) else: raise NotImplementedError if self.use_tanh: logits = self.C * torch.tanh(logits) else: logits = logits return ref, logits def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'hidden_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y0 = yindex % 4 y1 = yindex // 4 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * x2 + 16 * y1), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 4 * y3), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_add_convolution_repeat_tanh_1(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x4 = xindex x1 = xindex // 4 % 4 x3 = xindex // 4 tmp0 = tl.load(in_out_ptr0 + x4, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x3, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp3 + tmp2 tmp5 = libdevice.tanh(tmp4) tl.store(in_out_ptr0 + x4, tmp2, xmask) tl.store(out_ptr0 + x4, tmp5, xmask) @triton.jit def triton_poi_fused_repeat_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4, 4, 1), (4, 1, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_3, primals_4, reinterpret_tensor( primals_2, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf0) del primals_2 del primals_3 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_convolution_0[grid(16, 4)](primals_1, buf1, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf2 = extern_kernels.convolution(buf1, primals_5, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4), (16, 4, 1)) buf3 = buf2 del buf2 buf4 = buf1 del buf1 triton_poi_fused_add_convolution_repeat_tanh_1[grid(64)](buf3, primals_6, buf0, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_6 buf5 = reinterpret_tensor(buf0, (4, 1, 4), (4, 16, 1), 0) del buf0 triton_poi_fused_repeat_2[grid(16)](primals_7, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_7 buf6 = empty_strided_cuda((4, 1, 4), (4, 4, 1), torch.float32) extern_kernels.bmm(buf5, buf4, out=buf6) return buf3, reinterpret_tensor(buf6, (4, 4), (4, 1), 0 ), primals_4, primals_5, reinterpret_tensor(primals_1, (4, 4, 4), ( 16, 1, 4), 0), buf4, reinterpret_tensor(buf5, (4, 4, 1), (4, 1, 4), 0) class AttentionNew(nn.Module): """ Using two types of attention mechanism: "Dot" and "Bahdanau" """ def __init__(self, hidden_size, use_tanh=False, C=10, name='Bahdanau', use_cuda=True): super(AttentionNew, self).__init__() self.use_tanh = use_tanh self.C = C self.name = name if name == 'Bahdanau': self.W_query = nn.Linear(hidden_size, hidden_size) self.W_ref = nn.Conv1d(hidden_size, hidden_size, 1, 1) V = torch.FloatTensor(hidden_size) if use_cuda: V = V self.V = nn.Parameter(V) self.V.data.uniform_(-(1.0 / math.sqrt(hidden_size)), 1.0 / math.sqrt(hidden_size)) def forward(self, input_0, input_1): primals_3 = self.V primals_2 = self.W_query.weight primals_6 = self.W_query.bias primals_5 = self.W_ref.weight primals_7 = self.W_ref.bias primals_4 = input_0 primals_1 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0], output[1]

Lance0226/CIS700_Convex_Hull_RL

Attention

false

2,502

[ "MIT" ]

0

3c87e063209d535d75fde719bf17f20dd5e68635

https://github.com/Lance0226/CIS700_Convex_Hull_RL/tree/3c87e063209d535d75fde719bf17f20dd5e68635

BothContextGate

import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class BothContextGate(nn.Module): """Apply the context gate to both contexts""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(BothContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh((1.0 - z) * target + z * source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_rsub_sigmoid_tanh_2(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp4 = tl.load(in_ptr1 + x0, xmask) tmp6 = tl.load(in_ptr2 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp2 = 1.0 tmp3 = tmp2 - tmp1 tmp5 = tmp3 * tmp4 tmp7 = tmp1 * tmp6 tmp8 = tmp5 + tmp7 tmp9 = libdevice.tanh(tmp8) tl.store(out_ptr0 + x0, tmp9, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_6 del primals_7 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf4) del primals_8 del primals_9 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused_add_mul_rsub_sigmoid_tanh_2[grid(16)](buf1, buf4, buf2, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) return buf5, primals_3, buf0, buf1, buf2, buf3, buf4, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class BothContextGateNew(nn.Module): """Apply the context gate to both contexts""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(BothContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]

LeeeeoLiu/OpenNMT-py

BothContextGate

false

2,503

[ "MIT" ]

0

9be3a8951e9181aabe5440e4ea98173b7e749b5c

https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c

GraphEmbedding

import math import torch import torch.nn as nn class GraphEmbedding(nn.Module): def __init__(self, input_size, ebd_size, use_cuda=True, use_sdne=True, add_noise=False, is_training=True): super(GraphEmbedding, self).__init__() self.use_cuda = use_cuda self.use_sdne = use_sdne self.add_noise = add_noise self.is_training = is_training ebd_size_1 = ebd_size * 4 if use_sdne else ebd_size ebd_size_2 = ebd_size * 2 ebd_size_3 = ebd_size self.embedding_1 = nn.Parameter(torch.FloatTensor(input_size, ebd_size_1)) if self.use_sdne: self.embedding_2 = nn.Parameter(torch.FloatTensor(ebd_size_1, ebd_size_2)) self.embedding_3 = nn.Parameter(torch.FloatTensor(ebd_size_2, ebd_size_3)) self.embedding_1.data.uniform_(-(1.0 / math.sqrt(ebd_size_1)), 1.0 / math.sqrt(ebd_size_1)) if self.use_sdne: self.embedding_2.data.uniform_(-(1.0 / math.sqrt(ebd_size_2)), 1.0 / math.sqrt(ebd_size_2)) self.embedding_3.data.uniform_(-(1.0 / math.sqrt(ebd_size_3)), 1.0 / math.sqrt(ebd_size_3)) def forward(self, inputs): """ :param inputs: tensor [batch, 2, seq_len] :return: embedded: tensor [batch, seq_len, embedding_size] Embed each node in the graph to a 128-dimension space """ batch_size = inputs.size(0) seq_len = inputs.size(2) embedding_1 = self.embedding_1.repeat(batch_size, 1, 1) if self.use_sdne: embedding_2 = self.embedding_2.repeat(batch_size, 1, 1) embedding_3 = self.embedding_3.repeat(batch_size, 1, 1) embedded = [] inputs = inputs.unsqueeze(1) for i in range(seq_len): embedding = torch.bmm(inputs[:, :, :, i].float(), embedding_1) if self.use_sdne: embedding = torch.bmm(embedding.float(), embedding_2) embedding = torch.bmm(embedding.float(), embedding_3) embedded.append(embedding) embedded = torch.cat(tuple(embedded), 1) return embedded def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, 'ebd_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_bmm_repeat_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 64 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 512 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 128 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_repeat_3(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 128 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 32 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_4(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_5(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_bmm_6(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_cat_7(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 4 % 4 x0 = xindex % 4 x2 = xindex // 16 x3 = xindex tmp0 = x1 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 1, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (x0 + 4 * x2), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 2, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (x0 + 4 * x2), tmp9 & xmask, eviction_policy= 'evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tmp12 = tl.full([1], 3, tl.int64) tmp13 = tmp0 < tmp12 tmp14 = tmp11 & tmp13 tmp15 = tl.load(in_ptr2 + (x0 + 4 * x2), tmp14 & xmask, eviction_policy ='evict_last', other=0.0) tmp16 = tmp0 >= tmp12 tl.full([1], 4, tl.int64) tmp19 = tl.load(in_ptr3 + (x0 + 4 * x2), tmp16 & xmask, eviction_policy ='evict_last', other=0.0) tmp20 = tl.where(tmp14, tmp15, tmp19) tmp21 = tl.where(tmp9, tmp10, tmp20) tmp22 = tl.where(tmp4, tmp5, tmp21) tl.store(out_ptr0 + x3, tmp22, xmask) def call(args): primals_1, primals_2, primals_3, primals_4 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 16), (16, 1)) assert_size_stride(primals_3, (16, 8), (8, 1)) assert_size_stride(primals_4, (8, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) get_raw_stream(0) triton_poi_fused_bmm_repeat_0[grid(16)](primals_1, buf0, 16, XBLOCK =16, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4, 16), (64, 16, 1), torch.float32) triton_poi_fused_repeat_1[grid(256)](primals_2, buf1, 256, XBLOCK= 128, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf0, buf1, out=buf2) buf3 = empty_strided_cuda((4, 16, 8), (128, 8, 1), torch.float32) triton_poi_fused_repeat_2[grid(512)](primals_3, buf3, 512, XBLOCK= 128, num_warps=4, num_stages=1) del primals_3 buf4 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf2, buf3, out=buf4) buf5 = empty_strided_cuda((4, 8, 4), (32, 4, 1), torch.float32) triton_poi_fused_repeat_3[grid(128)](primals_4, buf5, 128, XBLOCK= 128, num_warps=4, num_stages=1) del primals_4 buf6 = reinterpret_tensor(buf0, (4, 1, 4), (4, 4, 1), 0) del buf0 extern_kernels.bmm(buf4, buf5, out=buf6) buf7 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_4[grid(16)](primals_1, buf7, 16, XBLOCK=16, num_warps=1, num_stages=1) buf8 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf7, buf1, out=buf8) buf9 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf8, buf3, out=buf9) buf10 = reinterpret_tensor(buf7, (4, 1, 4), (4, 4, 1), 0) del buf7 extern_kernels.bmm(buf9, buf5, out=buf10) buf11 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_5[grid(16)](primals_1, buf11, 16, XBLOCK=16, num_warps=1, num_stages=1) buf12 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf11, buf1, out=buf12) buf13 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf12, buf3, out=buf13) buf14 = reinterpret_tensor(buf11, (4, 1, 4), (4, 4, 1), 0) del buf11 extern_kernels.bmm(buf13, buf5, out=buf14) buf15 = empty_strided_cuda((4, 1, 4), (4, 16, 1), torch.float32) triton_poi_fused_bmm_6[grid(16)](primals_1, buf15, 16, XBLOCK=16, num_warps=1, num_stages=1) buf16 = empty_strided_cuda((4, 1, 16), (16, 16, 1), torch.float32) extern_kernels.bmm(buf15, buf1, out=buf16) del buf1 buf17 = empty_strided_cuda((4, 1, 8), (8, 8, 1), torch.float32) extern_kernels.bmm(buf16, buf3, out=buf17) buf18 = reinterpret_tensor(buf15, (4, 1, 4), (4, 4, 1), 0) del buf15 extern_kernels.bmm(buf17, buf5, out=buf18) buf19 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_cat_7[grid(64)](buf6, buf10, buf14, buf18, buf19, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf10 del buf14 del buf18 del buf6 return buf19, reinterpret_tensor(buf17, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf5, (4, 4, 8), (32, 1, 4), 0 ), reinterpret_tensor(buf16, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(buf3, (4, 8, 16), (128, 1, 8), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 3 ), reinterpret_tensor(buf13, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf12, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 2 ), reinterpret_tensor(buf9, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf8, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 1 ), reinterpret_tensor(buf4, (4, 8, 1), (8, 1, 8), 0 ), reinterpret_tensor(buf2, (4, 16, 1), (16, 1, 16), 0 ), reinterpret_tensor(primals_1, (4, 4, 1), (16, 4, 16), 0) class GraphEmbeddingNew(nn.Module): def __init__(self, input_size, ebd_size, use_cuda=True, use_sdne=True, add_noise=False, is_training=True): super(GraphEmbeddingNew, self).__init__() self.use_cuda = use_cuda self.use_sdne = use_sdne self.add_noise = add_noise self.is_training = is_training ebd_size_1 = ebd_size * 4 if use_sdne else ebd_size ebd_size_2 = ebd_size * 2 ebd_size_3 = ebd_size self.embedding_1 = nn.Parameter(torch.FloatTensor(input_size, ebd_size_1)) if self.use_sdne: self.embedding_2 = nn.Parameter(torch.FloatTensor(ebd_size_1, ebd_size_2)) self.embedding_3 = nn.Parameter(torch.FloatTensor(ebd_size_2, ebd_size_3)) self.embedding_1.data.uniform_(-(1.0 / math.sqrt(ebd_size_1)), 1.0 / math.sqrt(ebd_size_1)) if self.use_sdne: self.embedding_2.data.uniform_(-(1.0 / math.sqrt(ebd_size_2)), 1.0 / math.sqrt(ebd_size_2)) self.embedding_3.data.uniform_(-(1.0 / math.sqrt(ebd_size_3)), 1.0 / math.sqrt(ebd_size_3)) def forward(self, input_0): primals_2 = self.embedding_1 primals_3 = self.embedding_2 primals_4 = self.embedding_3 primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]

Lance0226/CIS700_Convex_Hull_RL

GraphEmbedding

false

2,504

[ "MIT" ]

0

3c87e063209d535d75fde719bf17f20dd5e68635

https://github.com/Lance0226/CIS700_Convex_Hull_RL/tree/3c87e063209d535d75fde719bf17f20dd5e68635

GeM

import torch from torch import nn from torch.nn import functional as F from torch.nn.parameter import Parameter def gem(x, p=3, eps=1e-06): return F.avg_pool2d(x.clamp(min=eps).pow(p), (x.size(-2), x.size(-1))).pow( 1.0 / p) class GeM(nn.Module): def __init__(self, p=3, eps=1e-06, p_trainable=True): super(GeM, self).__init__() if p_trainable: self.p = Parameter(torch.ones(1) * p) else: self.p = p self.eps = eps def forward(self, x): return gem(x, p=self.p, eps=self.eps) def __repr__(self): return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(self. p.data.tolist()[0]) + ', ' + 'eps=' + str(self.eps) + ')' def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn from torch.nn import functional as F from torch.nn.parameter import Parameter assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp3 = tl.load(in_ptr1 + 0) tmp4 = tl.broadcast_to(tmp3, [XBLOCK]) tmp1 = 1e-06 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp5 = libdevice.pow(tmp2, tmp4) tl.store(out_ptr0 + x0, tmp5, xmask) @triton.jit def triton_poi_fused_avg_pool2d_mul_pow_reciprocal_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 16 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (1 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_ptr0 + (2 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp5 = tl.load(in_ptr0 + (3 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp7 = tl.load(in_ptr0 + (4 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp9 = tl.load(in_ptr0 + (5 + 16 * x0), xmask, eviction_policy='evict_last' ) tmp11 = tl.load(in_ptr0 + (6 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp13 = tl.load(in_ptr0 + (7 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp15 = tl.load(in_ptr0 + (8 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp17 = tl.load(in_ptr0 + (9 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp19 = tl.load(in_ptr0 + (10 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp21 = tl.load(in_ptr0 + (11 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp23 = tl.load(in_ptr0 + (12 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp25 = tl.load(in_ptr0 + (13 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp27 = tl.load(in_ptr0 + (14 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp29 = tl.load(in_ptr0 + (15 + 16 * x0), xmask, eviction_policy= 'evict_last') tmp33 = tl.load(in_ptr1 + 0) tmp34 = tl.broadcast_to(tmp33, [XBLOCK]) tmp2 = tmp1 + tmp0 tmp4 = tmp3 + tmp2 tmp6 = tmp5 + tmp4 tmp8 = tmp7 + tmp6 tmp10 = tmp9 + tmp8 tmp12 = tmp11 + tmp10 tmp14 = tmp13 + tmp12 tmp16 = tmp15 + tmp14 tmp18 = tmp17 + tmp16 tmp20 = tmp19 + tmp18 tmp22 = tmp21 + tmp20 tmp24 = tmp23 + tmp22 tmp26 = tmp25 + tmp24 tmp28 = tmp27 + tmp26 tmp30 = tmp29 + tmp28 tmp31 = 0.0625 tmp32 = tmp30 * tmp31 tmp35 = tl.full([1], 1, tl.int32) tmp36 = tmp35 / tmp34 tmp37 = 1.0 tmp38 = tmp36 * tmp37 tmp39 = libdevice.pow(tmp32, tmp38) tl.store(out_ptr0 + x0, tmp32, xmask) tl.store(out_ptr1 + x0, tmp39, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (1,), (1,)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_pow_0[grid(256)](primals_2, primals_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) buf2 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused_avg_pool2d_mul_pow_reciprocal_1[grid(16)](buf0, primals_1, buf1, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) return buf2, primals_1, primals_2, buf0, buf1, buf2 def gem(x, p=3, eps=1e-06): return F.avg_pool2d(x.clamp(min=eps).pow(p), (x.size(-2), x.size(-1))).pow( 1.0 / p) class GeMNew(nn.Module): def __init__(self, p=3, eps=1e-06, p_trainable=True): super(GeMNew, self).__init__() if p_trainable: self.p = Parameter(torch.ones(1) * p) else: self.p = p self.eps = eps def __repr__(self): return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(self. p.data.tolist()[0]) + ', ' + 'eps=' + str(self.eps) + ')' def forward(self, input_0): primals_1 = self.p primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]

Lascarfo/kaggle-landmark-recognition-2020-1st-place

GeM

false

2,505

[ "MIT" ]

0

f9007d81e59ecd1311bdea5586a426b8973a2eb8

https://github.com/Lascarfo/kaggle-landmark-recognition-2020-1st-place/tree/f9007d81e59ecd1311bdea5586a426b8973a2eb8

FocalLossBinary

import torch import torch.nn.functional import torch.jit import torch.nn.functional as F from functools import partial from torch.nn.modules.loss import _Loss def reduced_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', threshold: 'float'=0.5, gamma: 'float'=2.0, reduction='mean'): """ Compute reduced focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" | "mean" | "sum" | "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. Note: :attr:`size_average` and :attr:`reduce` are in the process of being deprecated, and in the meantime, specifying either of those two args will override :attr:`reduction`. "batchwise_mean" computes mean loss per sample in batch. Default: "mean" See https://arxiv.org/abs/1903.01347 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) focal_reduction = ((1.0 - pt) / threshold).pow(gamma) focal_reduction[pt < threshold] = 1 loss = -focal_reduction * logpt if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss def sigmoid_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', gamma: 'float'=2.0, alpha: 'float'=0.25, reduction: 'str'='mean'): """ Compute binary focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" | "mean" | "sum" | "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. See https://github.com/open-mmlab/mmdetection/blob/master/mmdet/core/loss/losses.py # noqa: E501 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) loss = -(1 - pt).pow(gamma) * logpt if alpha is not None: loss = loss * (alpha * targets + (1 - alpha) * (1 - targets)) if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss class FocalLossBinary(_Loss): def __init__(self, ignore: 'int'=None, reduced: 'bool'=False, gamma: 'float'=2.0, alpha: 'float'=0.25, threshold: 'float'=0.5, reduction: 'str'='mean'): """ Compute focal loss for binary classification problem. """ super().__init__() self.ignore = ignore if reduced: self.loss_fn = partial(reduced_focal_loss, gamma=gamma, threshold=threshold, reduction=reduction) else: self.loss_fn = partial(sigmoid_focal_loss, gamma=gamma, alpha= alpha, reduction=reduction) def forward(self, logits, targets): """ Args: logits: [bs; ...] targets: [bs; ...] """ targets = targets.view(-1) logits = logits.view(-1) if self.ignore is not None: not_ignored = targets != self.ignore logits = logits[not_ignored] targets = targets[not_ignored] loss = self.loss_fn(logits, targets) return loss def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice, math as tl_math import torch.nn.functional import torch.jit import torch.nn.functional as F from functools import partial from torch.nn.modules.loss import _Loss assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_binary_cross_entropy_with_logits_exp_mean_mul_neg_pow_rsub_0( in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp3 = tl.load(in_ptr1 + r0, None) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tmp4 = tmp2 * tmp3 tmp5 = 0.0 tmp6 = triton_helpers.minimum(tmp5, tmp3) tmp7 = tl_math.abs(tmp3) tmp8 = -tmp7 tmp9 = tl_math.exp(tmp8) tmp10 = libdevice.log1p(tmp9) tmp11 = tmp6 - tmp10 tmp12 = tmp4 - tmp11 tmp13 = -tmp12 tmp14 = tl_math.exp(tmp13) tmp15 = tmp1 - tmp14 tmp16 = tmp15 * tmp15 tmp17 = -tmp16 tmp18 = tmp17 * tmp13 tmp19 = 0.25 tmp20 = tmp0 * tmp19 tmp21 = 0.75 tmp22 = tmp2 * tmp21 tmp23 = tmp20 + tmp22 tmp24 = tmp18 * tmp23 tmp25 = tl.broadcast_to(tmp24, [RBLOCK]) tmp27 = triton_helpers.promote_to_tensor(tl.sum(tmp25, 0)) tmp28 = 256.0 tmp29 = tmp27 / tmp28 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp29, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_binary_cross_entropy_with_logits_exp_mean_mul_neg_pow_rsub_0[ grid(1)](buf1, arg0_1, arg1_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf1, def reduced_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', threshold: 'float'=0.5, gamma: 'float'=2.0, reduction='mean'): """ Compute reduced focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" | "mean" | "sum" | "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. Note: :attr:`size_average` and :attr:`reduce` are in the process of being deprecated, and in the meantime, specifying either of those two args will override :attr:`reduction`. "batchwise_mean" computes mean loss per sample in batch. Default: "mean" See https://arxiv.org/abs/1903.01347 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) focal_reduction = ((1.0 - pt) / threshold).pow(gamma) focal_reduction[pt < threshold] = 1 loss = -focal_reduction * logpt if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss def sigmoid_focal_loss(outputs: 'torch.Tensor', targets: 'torch.Tensor', gamma: 'float'=2.0, alpha: 'float'=0.25, reduction: 'str'='mean'): """ Compute binary focal loss between target and output logits. Source https://github.com/BloodAxe/pytorch-toolbelt See :class:`~pytorch_toolbelt.losses` for details. Args: outputs: Tensor of arbitrary shape targets: Tensor of the same shape as input reduction (string, optional): Specifies the reduction to apply to the output: "none" | "mean" | "sum" | "batchwise_mean". "none": no reduction will be applied, "mean": the sum of the output will be divided by the number of elements in the output, "sum": the output will be summed. See https://github.com/open-mmlab/mmdetection/blob/master/mmdet/core/loss/losses.py # noqa: E501 """ targets = targets.type(outputs.type()) logpt = -F.binary_cross_entropy_with_logits(outputs, targets, reduction ='none') pt = torch.exp(logpt) loss = -(1 - pt).pow(gamma) * logpt if alpha is not None: loss = loss * (alpha * targets + (1 - alpha) * (1 - targets)) if reduction == 'mean': loss = loss.mean() if reduction == 'sum': loss = loss.sum() if reduction == 'batchwise_mean': loss = loss.sum(0) return loss class FocalLossBinaryNew(_Loss): def __init__(self, ignore: 'int'=None, reduced: 'bool'=False, gamma: 'float'=2.0, alpha: 'float'=0.25, threshold: 'float'=0.5, reduction: 'str'='mean'): """ Compute focal loss for binary classification problem. """ super().__init__() self.ignore = ignore if reduced: self.loss_fn = partial(reduced_focal_loss, gamma=gamma, threshold=threshold, reduction=reduction) else: self.loss_fn = partial(sigmoid_focal_loss, gamma=gamma, alpha= alpha, reduction=reduction) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

LeAlex27/nnUNet

FocalLossBinary

false

2,506

[ "Apache-2.0" ]

0

9b6912f80904af9eaa4db41cd7e5c7f20058cdde

https://github.com/LeAlex27/nnUNet/tree/9b6912f80904af9eaa4db41cd7e5c7f20058cdde

SourceContextGate

import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class SourceContextGate(nn.Module): """Apply the context gate only to the source context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(SourceContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh(target + z * source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_sigmoid_tanh_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp5 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp4 = tl.sigmoid(tmp3) tmp6 = tmp4 * tmp5 tmp7 = tmp2 + tmp6 tmp8 = libdevice.tanh(tmp7) tl.store(in_out_ptr0 + x2, tmp8, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_6 del primals_7 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8 ), 0), out=buf4) del primals_8 buf5 = buf4 del buf4 triton_poi_fused_add_mul_sigmoid_tanh_2[grid(16)](buf5, primals_9, buf1, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_9 return buf5, primals_3, buf0, buf1, buf2, buf3, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class SourceContextGateNew(nn.Module): """Apply the context gate only to the source context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(SourceContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]

LeeeeoLiu/OpenNMT-py

SourceContextGate

false

2,507

[ "MIT" ]

0

9be3a8951e9181aabe5440e4ea98173b7e749b5c

https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c

TargetContextGate

import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class TargetContextGate(nn.Module): """Apply the context gate only to the target context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(TargetContextGate, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, prev_emb, dec_state, attn_state): z, source, target = self.context_gate(prev_emb, dec_state, attn_state) return self.tanh(z * target + source) def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) @triton.jit def triton_poi_fused_add_mul_sigmoid_tanh_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp2 = tl.load(in_ptr1 + x2, xmask) tmp4 = tl.load(in_out_ptr0 + x2, xmask) tmp5 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.sigmoid(tmp0) tmp3 = tmp1 * tmp2 tmp6 = tmp4 + tmp5 tmp7 = tmp3 + tmp6 tmp8 = libdevice.tanh(tmp7) tl.store(in_out_ptr0 + x2, tmp8, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf2) del primals_6 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_1[grid(32)](primals_1, primals_2, buf3, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf3, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf4) del primals_8 del primals_9 buf5 = buf2 del buf2 triton_poi_fused_add_mul_sigmoid_tanh_2[grid(16)](buf5, buf1, buf4, primals_7, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_7 return buf5, primals_3, buf0, buf1, buf3, buf4, buf5 class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target class TargetContextGateNew(nn.Module): """Apply the context gate only to the target context""" def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(TargetContextGateNew, self).__init__() self.context_gate = ContextGate(embeddings_size, decoder_size, attention_size, output_size) self.tanh = nn.Tanh() def forward(self, input_0, input_1, input_2): primals_4 = self.context_gate.gate.weight primals_5 = self.context_gate.gate.bias primals_1 = self.context_gate.source_proj.weight primals_7 = self.context_gate.source_proj.bias primals_8 = self.context_gate.target_proj.weight primals_9 = self.context_gate.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]

LeeeeoLiu/OpenNMT-py

TargetContextGate

false

2,508

[ "MIT" ]

0

9be3a8951e9181aabe5440e4ea98173b7e749b5c

https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c

Foo

import torch import torch.nn.functional import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd class Foo(torch.nn.Module): def __init__(self, size): super(Foo, self).__init__() self.n = torch.nn.Parameter(torch.ones(size)) self.m = torch.nn.Parameter(torch.ones(size)) def forward(self, input): return self.n * input + self.m def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'size': 4}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_mul_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask) tmp3 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 * tmp1 tmp4 = tmp2 + tmp3 tl.store(out_ptr0 + x2, tmp4, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4,), (1,)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_mul_0[grid(256)](primals_1, primals_2, primals_3, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_1 del primals_3 return buf0, primals_2 class FooNew(torch.nn.Module): def __init__(self, size): super(FooNew, self).__init__() self.n = torch.nn.Parameter(torch.ones(size)) self.m = torch.nn.Parameter(torch.ones(size)) def forward(self, input_0): primals_1 = self.n primals_3 = self.m primals_2 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

Liuhongzhi2018/Person_ReID

Foo

false

2,509

[ "MIT" ]

0

51c576ed5b4ed960801669d6d59c0a77405b369d

https://github.com/Liuhongzhi2018/Person_ReID/tree/51c576ed5b4ed960801669d6d59c0a77405b369d

ScaledDotProductAtten

import torch import numpy as np from torch import nn class ScaledDotProductAtten(nn.Module): """ Scaled dot-product attention mechainsm 公式： $ Attention(Q, K, V) = softmax(rac{Q K^T}{\\sqrt{d_k}})*V $ ![](https://raw.githubusercontent.com/LinXueyuanStdio/scRNN-seq/master/art/2.png) """ def __init__(self, encode_size, atten_dropout=0.1): super(ScaledDotProductAtten, self).__init__() encode_size = 2 * encode_size self.scale = encode_size ** -0.5 self.dropout = nn.Dropout(atten_dropout) self.softmax = nn.Softmax(dim=2) def forward(self, query, key, value, atten_mask=None): """ 前向传播. Args: Q: Queries，[B, L_q, D_q] K: Keys，[B, L_k, D_k] V: Values，[B, L_v, D_v]，一般来说就是k scale: 缩放因子，一个浮点标量 attn_mask: Masking，[B, L_q, L_k] Returns: 上下文张量和attetention张量 """ atten = torch.bmm(query, key.transpose(1, 2)) * self.scale if atten_mask: atten.masked_fill_(atten_mask, -np.inf) atten = self.softmax(atten) atten = self.dropout(atten) context = torch.bmm(atten, value) return context, atten def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4]) ] def get_init_inputs(): return [[], {'encode_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tmp4 = tmp3 * tmp1 tmp6 = tmp5 * tmp1 tmp7 = triton_helpers.maximum(tmp4, tmp6) tmp9 = tmp8 * tmp1 tmp10 = triton_helpers.maximum(tmp7, tmp9) tmp12 = tmp11 * tmp1 tmp13 = triton_helpers.maximum(tmp10, tmp12) tmp14 = tmp2 - tmp13 tmp15 = 0.3535533905932738 tmp16 = tmp14 * tmp15 tmp17 = tl_math.exp(tmp16) tl.store(out_ptr0 + x2, tmp17, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4), (16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(arg1_1, reinterpret_tensor(arg0_1, (4, 4, 4), ( 16, 1, 4), 0), out=buf0) del arg0_1 del arg1_1 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(64)](buf0, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = buf0 del buf0 triton_poi_fused__softmax_1[grid(64)](buf1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) buf3 = buf1 del buf1 extern_kernels.bmm(buf2, arg2_1, out=buf3) del arg2_1 return buf3, buf2 class ScaledDotProductAttenNew(nn.Module): """ Scaled dot-product attention mechainsm 公式： $ Attention(Q, K, V) = softmax(rac{Q K^T}{\\sqrt{d_k}})*V $ ![](https://raw.githubusercontent.com/LinXueyuanStdio/scRNN-seq/master/art/2.png) """ def __init__(self, encode_size, atten_dropout=0.1): super(ScaledDotProductAttenNew, self).__init__() encode_size = 2 * encode_size self.scale = encode_size ** -0.5 self.dropout = nn.Dropout(atten_dropout) self.softmax = nn.Softmax(dim=2) def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0], output[1]

LinXueyuanStdio/scRNN-seq

ScaledDotProductAtten

false

2,510

[ "Apache-2.0" ]

0

87e11a56acb18a86fa4fb309d33a1bc02bf38b39

https://github.com/LinXueyuanStdio/scRNN-seq/tree/87e11a56acb18a86fa4fb309d33a1bc02bf38b39

FunctionalRelu6

import torch class FunctionalRelu6(torch.nn.Module): def forward(self, x): return torch.nn.functional.relu6(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_hardtanh_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.0 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = 6.0 tmp4 = triton_helpers.minimum(tmp2, tmp3) tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_hardtanh_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class FunctionalRelu6New(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

FunctionalRelu6

false

2,511

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TokenEmbedding

import torch import torch.nn as nn class TokenEmbedding(nn.Module): def __init__(self, c_in, d_model): super(TokenEmbedding, self).__init__() padding = 1 if torch.__version__ >= '1.5.0' else 2 self.tokenConv = nn.Conv1d(in_channels=c_in, out_channels=d_model, kernel_size=3, padding=padding, padding_mode='circular') for m in self.modules(): if isinstance(m, nn.Conv1d): nn.init.kaiming_normal_(m.weight, mode='fan_in', nonlinearity='leaky_relu') def forward(self, x): x = self.tokenConv(x.permute(0, 2, 1)).transpose(1, 2) return x def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'c_in': 4, 'd_model': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_copy_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 24 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel y0 = yindex % 6 x2 = xindex y1 = yindex // 6 tmp0 = y0 tmp1 = tl.full([1, 1], 5, tl.int64) tmp2 = tmp0 >= tmp1 tmp3 = tl.broadcast_to(-4 + y0, [XBLOCK, YBLOCK]) tmp4 = tl.full([1, 1], 1, tl.int64) tmp5 = tmp3 < tmp4 tmp6 = tmp5 & tmp2 tmp7 = tl.broadcast_to(y0, [XBLOCK, YBLOCK]) tmp8 = tmp7 >= tmp4 tmp9 = tmp7 < tmp1 tmp10 = tmp8 & tmp9 tmp11 = tmp10 & tmp6 tmp12 = tl.load(in_ptr0 + (-4 + x2 + 4 * y0 + 16 * y1), tmp11 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp13 = float('nan') tmp14 = tl.where(tmp10, tmp12, tmp13) tmp15 = tl.full(tmp14.shape, 0.0, tmp14.dtype) tmp16 = tl.where(tmp6, tmp14, tmp15) tmp17 = tmp3 >= tmp4 tmp18 = tmp3 < tmp1 tmp19 = tmp17 & tmp18 tmp20 = tmp19 & tmp2 tmp21 = tl.load(in_ptr0 + (-20 + x2 + 4 * y0 + 16 * y1), tmp20 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp22 = tl.where(tmp19, tmp21, tmp13) tmp23 = tl.where(tmp5, tmp16, tmp22) tmp24 = tl.full(tmp23.shape, 0.0, tmp23.dtype) tmp25 = tl.where(tmp2, tmp23, tmp24) tmp26 = tmp0 < tmp4 tmp27 = tl.broadcast_to(4 + y0, [XBLOCK, YBLOCK]) tmp28 = tmp27 >= tmp4 tmp29 = tmp27 < tmp1 tmp30 = tmp28 & tmp29 tmp31 = tmp30 & tmp26 tmp32 = tl.load(in_ptr0 + (12 + x2 + 4 * y0 + 16 * y1), tmp31 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp33 = tl.where(tmp30, tmp32, tmp13) tmp34 = tl.full(tmp33.shape, 0.0, tmp33.dtype) tmp35 = tl.where(tmp26, tmp33, tmp34) tmp36 = tmp0 >= tmp4 tmp37 = tmp0 < tmp1 tmp38 = tmp36 & tmp37 tmp39 = tl.load(in_ptr0 + (-4 + x2 + 4 * y0 + 16 * y1), tmp38 & xmask & ymask, eviction_policy='evict_last', other=0.0) tmp40 = tl.where(tmp38, tmp39, tmp13) tmp41 = tl.where(tmp26, tmp35, tmp40) tmp42 = tl.where(tmp2, tmp25, tmp41) tl.store(out_ptr0 + (y0 + 6 * x2 + 24 * y1), tmp42, xmask & ymask) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 4 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4, 3), (12, 3, 1)) assert_size_stride(primals_3, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf1 = empty_strided_cuda((4, 4, 6), (24, 6, 1), torch.float32) get_raw_stream(0) triton_poi_fused_copy_0[grid(24, 4)](primals_1, buf1, 24, 4, XBLOCK =4, YBLOCK=32, num_warps=4, num_stages=1) del primals_1 buf2 = extern_kernels.convolution(buf1, primals_2, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4), (16, 4, 1)) buf3 = buf2 del buf2 triton_poi_fused_convolution_1[grid(64)](buf3, primals_3, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_3 return reinterpret_tensor(buf3, (4, 4, 4), (16, 1, 4), 0), primals_2, buf1 class TokenEmbeddingNew(nn.Module): def __init__(self, c_in, d_model): super(TokenEmbeddingNew, self).__init__() padding = 1 if torch.__version__ >= '1.5.0' else 2 self.tokenConv = nn.Conv1d(in_channels=c_in, out_channels=d_model, kernel_size=3, padding=padding, padding_mode='circular') for m in self.modules(): if isinstance(m, nn.Conv1d): nn.init.kaiming_normal_(m.weight, mode='fan_in', nonlinearity='leaky_relu') def forward(self, input_0): primals_2 = self.tokenConv.weight primals_3 = self.tokenConv.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

Linan2018/Informer2020

TokenEmbedding

false

2,512

[ "Apache-2.0" ]

0

30e63a7d3ed9310b917b05c4d60b340d2dd0517a

https://github.com/Linan2018/Informer2020/tree/30e63a7d3ed9310b917b05c4d60b340d2dd0517a

Div

import torch class Div(torch.nn.Module): def __init__(self): super(Div, self).__init__() def forward(self, x, y): return x / y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class DivNew(torch.nn.Module): def __init__(self): super(DivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

Div

false

2,513

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TemporalEmbedding

import math import torch import torch.nn as nn class FixedEmbedding(nn.Module): def __init__(self, c_in, d_model): super(FixedEmbedding, self).__init__() w = torch.zeros(c_in, d_model).float() w.require_grad = False position = torch.arange(0, c_in).float().unsqueeze(1) div_term = (torch.arange(0, d_model, 2).float() * -(math.log( 10000.0) / d_model)).exp() w[:, 0::2] = torch.sin(position * div_term) w[:, 1::2] = torch.cos(position * div_term) self.emb = nn.Embedding(c_in, d_model) self.emb.weight = nn.Parameter(w, requires_grad=False) def forward(self, x): return self.emb(x).detach() class TemporalEmbedding(nn.Module): def __init__(self, d_model, embed_type='fixed', freq='h'): super(TemporalEmbedding, self).__init__() minute_size = 4 hour_size = 24 weekday_size = 7 day_size = 32 month_size = 13 Embed = FixedEmbedding if embed_type == 'fixed' else nn.Embedding if freq == 't': self.minute_embed = Embed(minute_size, d_model) self.hour_embed = Embed(hour_size, d_model) self.weekday_embed = Embed(weekday_size, d_model) self.day_embed = Embed(day_size, d_model) self.month_embed = Embed(month_size, d_model) def forward(self, x): x = x.long() minute_x = self.minute_embed(x[:, :, 4]) if hasattr(self, 'minute_embed') else 0.0 hour_x = self.hour_embed(x[:, :, 3]) weekday_x = self.weekday_embed(x[:, :, 2]) day_x = self.day_embed(x[:, :, 1]) month_x = self.month_embed(x[:, :, 0]) return hour_x + weekday_x + day_x + month_x + minute_x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'d_model': 4}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_embedding_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 4 % 4 x2 = xindex // 16 x0 = xindex % 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (12 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp8 = tl.load(in_ptr0 + (8 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp17 = tl.load(in_ptr0 + (4 + x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp26 = tl.load(in_ptr0 + (x1 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp1 = tmp0.to(tl.int64) tmp2 = tl.full([XBLOCK], 24, tl.int32) tmp3 = tmp1 + tmp2 tmp4 = tmp1 < 0 tmp5 = tl.where(tmp4, tmp3, tmp1) tl.device_assert((0 <= tmp5) & (tmp5 < 24) | ~xmask, 'index out of bounds: 0 <= tmp5 < 24') tmp7 = tl.load(in_ptr1 + (x0 + 4 * tmp5), xmask) tmp9 = tmp8.to(tl.int64) tmp10 = tl.full([XBLOCK], 7, tl.int32) tmp11 = tmp9 + tmp10 tmp12 = tmp9 < 0 tmp13 = tl.where(tmp12, tmp11, tmp9) tl.device_assert((0 <= tmp13) & (tmp13 < 7) | ~xmask, 'index out of bounds: 0 <= tmp13 < 7') tmp15 = tl.load(in_ptr2 + (x0 + 4 * tmp13), xmask) tmp16 = tmp7 + tmp15 tmp18 = tmp17.to(tl.int64) tmp19 = tl.full([XBLOCK], 32, tl.int32) tmp20 = tmp18 + tmp19 tmp21 = tmp18 < 0 tmp22 = tl.where(tmp21, tmp20, tmp18) tl.device_assert((0 <= tmp22) & (tmp22 < 32) | ~xmask, 'index out of bounds: 0 <= tmp22 < 32') tmp24 = tl.load(in_ptr3 + (x0 + 4 * tmp22), xmask) tmp25 = tmp16 + tmp24 tmp27 = tmp26.to(tl.int64) tmp28 = tl.full([XBLOCK], 13, tl.int32) tmp29 = tmp27 + tmp28 tmp30 = tmp27 < 0 tmp31 = tl.where(tmp30, tmp29, tmp27) tl.device_assert((0 <= tmp31) & (tmp31 < 13) | ~xmask, 'index out of bounds: 0 <= tmp31 < 13') tmp33 = tl.load(in_ptr4 + (x0 + 4 * tmp31), xmask) tmp34 = tmp25 + tmp33 tmp35 = 0.0 tmp36 = tmp34 + tmp35 tl.store(out_ptr0 + x4, tmp36, xmask) def call(args): arg0_1, arg1_1, arg2_1, arg3_1, arg4_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (24, 4), (4, 1)) assert_size_stride(arg2_1, (7, 4), (4, 1)) assert_size_stride(arg3_1, (32, 4), (4, 1)) assert_size_stride(arg4_1, (13, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_embedding_0[grid(256)](arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 del arg2_1 del arg3_1 del arg4_1 return buf0, class FixedEmbedding(nn.Module): def __init__(self, c_in, d_model): super(FixedEmbedding, self).__init__() w = torch.zeros(c_in, d_model).float() w.require_grad = False position = torch.arange(0, c_in).float().unsqueeze(1) div_term = (torch.arange(0, d_model, 2).float() * -(math.log( 10000.0) / d_model)).exp() w[:, 0::2] = torch.sin(position * div_term) w[:, 1::2] = torch.cos(position * div_term) self.emb = nn.Embedding(c_in, d_model) self.emb.weight = nn.Parameter(w, requires_grad=False) def forward(self, x): return self.emb(x).detach() class TemporalEmbeddingNew(nn.Module): def __init__(self, d_model, embed_type='fixed', freq='h'): super(TemporalEmbeddingNew, self).__init__() minute_size = 4 hour_size = 24 weekday_size = 7 day_size = 32 month_size = 13 Embed = FixedEmbedding if embed_type == 'fixed' else nn.Embedding if freq == 't': self.minute_embed = Embed(minute_size, d_model) self.hour_embed = Embed(hour_size, d_model) self.weekday_embed = Embed(weekday_size, d_model) self.day_embed = Embed(day_size, d_model) self.month_embed = Embed(month_size, d_model) def forward(self, input_0): arg1_1 = self.hour_embed.emb.weight arg2_1 = self.weekday_embed.emb.weight arg3_1 = self.day_embed.emb.weight arg4_1 = self.month_embed.emb.weight arg0_1 = input_0 output = call([arg0_1, arg1_1, arg2_1, arg3_1, arg4_1]) return output[0]

Linan2018/Informer2020

TemporalEmbedding

false

2,514

[ "Apache-2.0" ]

0

30e63a7d3ed9310b917b05c4d60b340d2dd0517a

https://github.com/Linan2018/Informer2020/tree/30e63a7d3ed9310b917b05c4d60b340d2dd0517a

LT

import torch class LT(torch.nn.Module): def __init__(self): super(LT, self).__init__() def forward(self, x, y): return x < y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_lt_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 < tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_lt_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class LTNew(torch.nn.Module): def __init__(self): super(LTNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

LT

false

2,515

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

FFN

import torch import torch.utils.data import torchvision.transforms.functional as F import torch.nn as nn import torch.nn.functional as F class FFN(nn.Module): def __init__(self, d_model, d_ffn, dropout=0): super().__init__() self.linear1 = nn.Linear(d_model, d_ffn) self.activation = F.relu self.dropout1 = nn.Dropout(dropout) self.linear2 = nn.Linear(d_ffn, d_model) self.dropout2 = nn.Dropout(dropout) self.norm = nn.LayerNorm(d_model) def forward(self, tgt): tgt2 = self.linear2(self.dropout1(self.activation(self.linear1(tgt)))) tgt = tgt + self.dropout2(tgt2) tgt = self.norm(tgt) return tgt def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'d_model': 4, 'd_ffn': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import torch.utils.data import torchvision.transforms.functional as F import torch.nn as nn import torch.nn.functional as F assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_relu_threshold_backward_0(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) @triton.jit def triton_poi_fused_add_native_layer_norm_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp12 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp9 = tmp7 + tmp8 tmp10 = tmp6 + tmp9 tmp13 = tmp11 + tmp12 tmp14 = tmp10 + tmp13 tmp15 = 4.0 tmp16 = tmp14 / tmp15 tmp17 = tmp2 - tmp16 tmp18 = tmp17 * tmp17 tmp19 = tmp5 - tmp16 tmp20 = tmp19 * tmp19 tmp21 = tmp18 + tmp20 tmp22 = tmp9 - tmp16 tmp23 = tmp22 * tmp22 tmp24 = tmp21 + tmp23 tmp25 = tmp13 - tmp16 tmp26 = tmp25 * tmp25 tmp27 = tmp24 + tmp26 tmp28 = tmp27 / tmp15 tl.store(out_ptr0 + x0, tmp16, xmask) tl.store(out_ptr1 + x0, tmp28, xmask) @triton.jit def triton_poi_fused_add_native_layer_norm_2(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + x2, xmask) tmp3 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr3 + x1, xmask, eviction_policy='evict_last') tmp10 = tl.load(in_ptr4 + x0, xmask, eviction_policy='evict_last') tmp12 = tl.load(in_ptr5 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp6 = 1e-05 tmp7 = tmp5 + tmp6 tmp8 = libdevice.rsqrt(tmp7) tmp9 = tmp4 * tmp8 tmp11 = tmp9 * tmp10 tmp13 = tmp11 + tmp12 tl.store(out_ptr0 + x2, tmp13, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 buf6 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf1, primals_2, buf6, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, reinterpret_tensor(buf1, (64, 4), ( 4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del primals_5 buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf4 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused_add_native_layer_norm_1[grid(64)](primals_3, buf2, buf3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_native_layer_norm_2[grid(256)](primals_3, buf2, buf3, buf4, primals_6, primals_7, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf3 del buf4 del primals_7 return buf5, primals_3, primals_6, reinterpret_tensor(buf1, (64, 4), (4, 1), 0), buf2, primals_4, buf6 class FFNNew(nn.Module): def __init__(self, d_model, d_ffn, dropout=0): super().__init__() self.linear1 = nn.Linear(d_model, d_ffn) self.activation = F.relu self.dropout1 = nn.Dropout(dropout) self.linear2 = nn.Linear(d_ffn, d_model) self.dropout2 = nn.Dropout(dropout) self.norm = nn.LayerNorm(d_model) def forward(self, input_0): primals_1 = self.linear1.weight primals_2 = self.linear1.bias primals_4 = self.linear2.weight primals_5 = self.linear2.bias primals_6 = self.norm.weight primals_7 = self.norm.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]

Anonymous1376/MOTR

FFN

false

2,516

[ "Apache-2.0" ]

0

804cac1a22068af8a8ae127eead8399026d07419

https://github.com/Anonymous1376/MOTR/tree/804cac1a22068af8a8ae127eead8399026d07419

MConnBlock

import torch import torch.nn as nn import torch.nn.functional as F import torch.cuda import torch.distributed class MConn(nn.Module): """ My custom connection module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConn, self).__init__() self.linear1 = nn.Linear(_dim_1, _dim_2) self.linear2 = nn.Linear(_dim_2, _dim_3) if not _linear: self.linearw = nn.Linear(_dim_1, _dim_3) self.USE_RS = True else: self.USE_RS = False if _ln_size is not None: self.layer_norm = nn.LayerNorm(_ln_size) self.USE_LN = True else: self.USE_LN = False def forward(self, _input): _output = self.linear2(F.leaky_relu(F.dropout(self.linear1(_input), p=0.3), inplace=True)) if self.USE_RS: output = F.dropout(self.linearw(_input), p=0.3) return self.layer_norm(_output + output ) if self.USE_LN else _output + output else: return self.layer_norm(_output) if self.USE_LN else _output class MConnBlock(nn.Module): """ My custom connection block module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConnBlock, self).__init__() _mid_ln_size = (_ln_size[0], _dim_2) if _ln_size else None self.MConn1 = MConn(_dim_1, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn6 = MConn(_dim_2, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn7 = MConn(_dim_2, _dim_2, _dim_3, _linear, _ln_size) def forward(self, _input): _output = self.MConn1(_input) _output = self.MConn6(_output) _output = self.MConn7(_output) return _output def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'_dim_1': 4, '_dim_2': 4, '_dim_3': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.functional as F import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_leaky_relu_leaky_relu_backward_0(in_out_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_out_ptr0 + x0, xmask) tmp1 = 0.0 tmp2 = tmp0 > tmp1 tmp3 = 0.01 tmp4 = tmp0 * tmp3 tmp5 = tl.where(tmp2, tmp0, tmp4) tmp6 = tmp5 > tmp1 tl.store(in_out_ptr0 + x0, tmp5, xmask) tl.store(out_ptr0 + x0, tmp6, xmask) @triton.jit def triton_poi_fused_add_1(in_out_ptr0, in_ptr0, in_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tl.store(in_out_ptr0 + x2, tmp4, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13, primals_14, primals_15, primals_16, primals_17, primals_18, primals_19) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 4), (4, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (4, 4), (4, 1)) assert_size_stride(primals_11, (4,), (1,)) assert_size_stride(primals_12, (4, 4), (4, 1)) assert_size_stride(primals_13, (4,), (1,)) assert_size_stride(primals_14, (4, 4), (4, 1)) assert_size_stride(primals_15, (4,), (1,)) assert_size_stride(primals_16, (4, 4), (4, 1)) assert_size_stride(primals_17, (4,), (1,)) assert_size_stride(primals_18, (4, 4), (4, 1)) assert_size_stride(primals_19, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf0) del primals_1 del primals_2 buf1 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf2 = buf1[0] buf3 = buf1[1] del buf1 buf4 = buf2 del buf2 buf35 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf4, buf35, 256, XBLOCK=128, num_warps=4, num_stages=1) buf5 = buf0 del buf0 extern_kernels.mm(reinterpret_tensor(buf4, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf5) buf6 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf6) del primals_6 del primals_7 buf7 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf6, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf8 = buf7[0] buf9 = buf7[1] del buf7 buf10 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused_add_1[grid(256)](buf10, primals_5, buf8, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_5 buf11 = reinterpret_tensor(buf8, (64, 4), (4, 1), 0) del buf8 extern_kernels.addmm(primals_9, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), reinterpret_tensor(primals_8, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf11) del primals_9 buf12 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf11, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf13 = buf12[0] buf14 = buf12[1] del buf12 buf15 = buf13 del buf13 buf34 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf15, buf34, 256, XBLOCK=128, num_warps=4, num_stages=1) buf16 = buf11 del buf11 extern_kernels.mm(reinterpret_tensor(buf15, (64, 4), (4, 1), 0), reinterpret_tensor(primals_10, (4, 4), (1, 4), 0), out=buf16) buf17 = buf6 del buf6 extern_kernels.addmm(primals_13, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), reinterpret_tensor(primals_12, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf17) del primals_13 buf18 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf17, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf19 = buf18[0] buf20 = buf18[1] del buf18 buf21 = reinterpret_tensor(buf16, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf16 triton_poi_fused_add_1[grid(256)](buf21, primals_11, buf19, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_11 buf22 = reinterpret_tensor(buf19, (64, 4), (4, 1), 0) del buf19 extern_kernels.addmm(primals_15, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), reinterpret_tensor(primals_14, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf22) del primals_15 buf23 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf22, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) buf24 = buf23[0] buf25 = buf23[1] del buf23 buf26 = buf24 del buf24 buf33 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_leaky_relu_leaky_relu_backward_0[grid(256)](buf26, buf33, 256, XBLOCK=128, num_warps=4, num_stages=1) buf27 = buf22 del buf22 extern_kernels.mm(reinterpret_tensor(buf26, (64, 4), (4, 1), 0), reinterpret_tensor(primals_16, (4, 4), (1, 4), 0), out=buf27) buf28 = buf17 del buf17 extern_kernels.addmm(primals_19, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), reinterpret_tensor(primals_18, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf28) del primals_19 buf29 = torch.ops.aten.native_dropout.default(reinterpret_tensor( buf28, (4, 4, 4, 4), (64, 16, 4, 1), 0), 0.3, True) del buf28 buf30 = buf29[0] buf31 = buf29[1] del buf29 buf32 = reinterpret_tensor(buf27, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf27 triton_poi_fused_add_1[grid(256)](buf32, primals_17, buf30, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf30 del primals_17 return (buf32, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), buf3, reinterpret_tensor(buf4, (64, 4), (4, 1), 0), buf9, reinterpret_tensor(buf10, (64, 4), (4, 1), 0), buf14, reinterpret_tensor(buf15, (64, 4), (4, 1), 0), buf20, reinterpret_tensor(buf21, (64, 4), (4, 1), 0), buf25, reinterpret_tensor(buf26, (64, 4), (4, 1), 0), buf31, primals_18, primals_16, buf33, primals_14, primals_12, primals_10, buf34, primals_8, primals_4, buf35) class MConn(nn.Module): """ My custom connection module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConn, self).__init__() self.linear1 = nn.Linear(_dim_1, _dim_2) self.linear2 = nn.Linear(_dim_2, _dim_3) if not _linear: self.linearw = nn.Linear(_dim_1, _dim_3) self.USE_RS = True else: self.USE_RS = False if _ln_size is not None: self.layer_norm = nn.LayerNorm(_ln_size) self.USE_LN = True else: self.USE_LN = False def forward(self, _input): _output = self.linear2(F.leaky_relu(F.dropout(self.linear1(_input), p=0.3), inplace=True)) if self.USE_RS: output = F.dropout(self.linearw(_input), p=0.3) return self.layer_norm(_output + output ) if self.USE_LN else _output + output else: return self.layer_norm(_output) if self.USE_LN else _output class MConnBlockNew(nn.Module): """ My custom connection block module """ def __init__(self, _dim_1, _dim_2, _dim_3, _linear=False, _ln_size=None): super(MConnBlockNew, self).__init__() _mid_ln_size = (_ln_size[0], _dim_2) if _ln_size else None self.MConn1 = MConn(_dim_1, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn6 = MConn(_dim_2, _dim_2, _dim_2, _linear, _mid_ln_size) self.MConn7 = MConn(_dim_2, _dim_2, _dim_3, _linear, _ln_size) def forward(self, input_0): primals_1 = self.MConn1.linear1.weight primals_2 = self.MConn1.linear1.bias primals_4 = self.MConn1.linear2.weight primals_5 = self.MConn1.linear2.bias primals_6 = self.MConn1.linearw.weight primals_7 = self.MConn1.linearw.bias primals_8 = self.MConn6.linear1.weight primals_9 = self.MConn6.linear1.bias primals_10 = self.MConn6.linear2.weight primals_11 = self.MConn6.linear2.bias primals_12 = self.MConn6.linearw.weight primals_13 = self.MConn6.linearw.bias primals_14 = self.MConn7.linear1.weight primals_15 = self.MConn7.linear1.bias primals_16 = self.MConn7.linear2.weight primals_17 = self.MConn7.linear2.bias primals_18 = self.MConn7.linearw.weight primals_19 = self.MConn7.linearw.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13, primals_14, primals_15, primals_16, primals_17, primals_18, primals_19]) return output[0]

LeeeeoLiu/OpenNMT-py

MConnBlock

false

2,517

[ "MIT" ]

0

9be3a8951e9181aabe5440e4ea98173b7e749b5c

https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c

IMul

import torch class IMul(torch.nn.Module): def __init__(self): super(IMul, self).__init__() def forward(self, x, y): x *= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IMulNew(torch.nn.Module): def __init__(self): super(IMulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

IMul

false

2,518

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

SoftGeneratorAttention

import torch import torch.nn.functional as F import torch.nn as nn class SoftGeneratorAttention(nn.Module): def __init__(self): nn.Module.__init__(self) def apply_bn(self, x): bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, key, x): attn = torch.mul(key, x).sum(dim=1) attn = F.softmax(attn) return attn def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_sum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 16 x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 64 * x1), xmask) tmp1 = tl.load(in_ptr1 + (x0 + 64 * x1), xmask) tmp3 = tl.load(in_ptr0 + (16 + x0 + 64 * x1), xmask) tmp4 = tl.load(in_ptr1 + (16 + x0 + 64 * x1), xmask) tmp7 = tl.load(in_ptr0 + (32 + x0 + 64 * x1), xmask) tmp8 = tl.load(in_ptr1 + (32 + x0 + 64 * x1), xmask) tmp11 = tl.load(in_ptr0 + (48 + x0 + 64 * x1), xmask) tmp12 = tl.load(in_ptr1 + (48 + x0 + 64 * x1), xmask) tmp2 = tmp0 * tmp1 tmp5 = tmp3 * tmp4 tmp6 = tmp2 + tmp5 tmp9 = tmp7 * tmp8 tmp10 = tmp6 + tmp9 tmp13 = tmp11 * tmp12 tmp14 = tmp10 + tmp13 tl.store(out_ptr0 + x2, tmp14, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 16 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 16 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_sum_0[grid(64)](arg1_1, arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 del arg1_1 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(64)](buf0, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = buf0 del buf0 triton_poi_fused__softmax_2[grid(64)](buf1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf1 return buf2, class SoftGeneratorAttentionNew(nn.Module): def __init__(self): nn.Module.__init__(self) def apply_bn(self, x): bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

LinChen-65/pygcn

SoftGeneratorAttention

false

2,519

[ "MIT" ]

0

0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

FloorDivConst

import torch class FloorDivConst(torch.nn.Module): def __init__(self): super(FloorDivConst, self).__init__() def forward(self, x): return x // 2.0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class FloorDivConstNew(torch.nn.Module): def __init__(self): super(FloorDivConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

FloorDivConst

false

2,520

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

DownBlock

import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class DownBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(DownBlock, self).__init__() self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): l0 = self.down_conv1(x) h0 = self.down_conv2(l0) l1 = self.down_conv3(h0 - x) return l1 + l0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10) = args args.clear() assert_size_stride(primals_1, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 1, 1), (4, 1, 1, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(16)](buf1, primals_2, primals_4, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 4, 4), (64, 16, 4, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_1[grid(256)](buf4, primals_6, primals_7, primals_3, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 1, 1), (4, 1, 1, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_add_convolution_2[grid(16)](buf7, primals_9, primals_10, buf2, buf8, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_9 return (buf8, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, buf1, buf2, buf4, buf5, buf7) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class DownBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(DownBlockNew, self).__init__() self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.down_conv1.conv.weight primals_2 = self.down_conv1.conv.bias primals_4 = self.down_conv1.act.weight primals_5 = self.down_conv2.deconv.weight primals_6 = self.down_conv2.deconv.bias primals_7 = self.down_conv2.act.weight primals_8 = self.down_conv3.conv.weight primals_9 = self.down_conv3.conv.bias primals_10 = self.down_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10]) return output[0]

DengZeshuai/DBPN-Pytorch

DownBlock

false

2,521

[ "MIT" ]

0

a90d241a1c4b07830c6d812ad8389d13e8cf05d1

https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1

EQ

import torch class EQ(torch.nn.Module): def __init__(self): super(EQ, self).__init__() def forward(self, x, y): return x == y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_eq_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 == tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_eq_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class EQNew(torch.nn.Module): def __init__(self): super(EQNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

EQ

false

2,522

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

MaxElementwise

import torch class MaxElementwise(torch.nn.Module): def forward(self, x, y): return torch.max(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_maximum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = triton_helpers.maximum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_maximum_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MaxElementwiseNew(torch.nn.Module): def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

MaxElementwise

false

2,523

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

Clone

import torch class Clone(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): return x.clone() def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tl.store(out_ptr0 + x0, tmp0, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class CloneNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

Clone

false

2,524

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

FloorDivAssign

import torch class FloorDivAssign(torch.nn.Module): def __init__(self): super(FloorDivAssign, self).__init__() def forward(self, x, y): x //= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr1 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class FloorDivAssignNew(torch.nn.Module): def __init__(self): super(FloorDivAssignNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

FloorDivAssign

false

2,525

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TripletSoftmaxLoss

import torch import torch.nn as nn import torch.nn.functional as F class TripletSoftmaxLoss(nn.Module): def __init__(self, margin=0.0, lambda_factor=0.01): super(TripletSoftmaxLoss, self).__init__() self.margin = margin self.loss_fn = nn.CrossEntropyLoss() self.lambda_factor = lambda_factor def forward(self, anchor, positive, negative, outputs, labels): distance_positive = torch.abs(anchor - positive).sum(1) distance_negative = torch.abs(anchor - negative).sum(1) losses = F.relu(distance_positive - distance_negative + self.margin) loss_softmax = self.loss_fn(input=outputs, target=labels) loss_total = self.lambda_factor * losses.sum() + loss_softmax return loss_total, losses.sum(), loss_softmax def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_abs_add_relu_sub_sum_0(in_ptr0, in_ptr1, in_ptr2, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex % 16 r1 = rindex // 16 tmp0 = tl.load(in_ptr0 + (r0 + 64 * r1), None) tmp1 = tl.load(in_ptr1 + (r0 + 64 * r1), None) tmp4 = tl.load(in_ptr0 + (16 + r0 + 64 * r1), None) tmp5 = tl.load(in_ptr1 + (16 + r0 + 64 * r1), None) tmp9 = tl.load(in_ptr0 + (32 + r0 + 64 * r1), None) tmp10 = tl.load(in_ptr1 + (32 + r0 + 64 * r1), None) tmp14 = tl.load(in_ptr0 + (48 + r0 + 64 * r1), None) tmp15 = tl.load(in_ptr1 + (48 + r0 + 64 * r1), None) tmp19 = tl.load(in_ptr2 + (r0 + 64 * r1), None) tmp22 = tl.load(in_ptr2 + (16 + r0 + 64 * r1), None) tmp26 = tl.load(in_ptr2 + (32 + r0 + 64 * r1), None) tmp30 = tl.load(in_ptr2 + (48 + r0 + 64 * r1), None) tmp2 = tmp0 - tmp1 tmp3 = tl_math.abs(tmp2) tmp6 = tmp4 - tmp5 tmp7 = tl_math.abs(tmp6) tmp8 = tmp3 + tmp7 tmp11 = tmp9 - tmp10 tmp12 = tl_math.abs(tmp11) tmp13 = tmp8 + tmp12 tmp16 = tmp14 - tmp15 tmp17 = tl_math.abs(tmp16) tmp18 = tmp13 + tmp17 tmp20 = tmp0 - tmp19 tmp21 = tl_math.abs(tmp20) tmp23 = tmp4 - tmp22 tmp24 = tl_math.abs(tmp23) tmp25 = tmp21 + tmp24 tmp27 = tmp9 - tmp26 tmp28 = tl_math.abs(tmp27) tmp29 = tmp25 + tmp28 tmp31 = tmp14 - tmp30 tmp32 = tl_math.abs(tmp31) tmp33 = tmp29 + tmp32 tmp34 = tmp18 - tmp33 tmp35 = 0.0 tmp36 = tmp34 + tmp35 tmp37 = tl.full([1, 1], 0, tl.int32) tmp38 = triton_helpers.maximum(tmp37, tmp36) tmp39 = tl.broadcast_to(tmp38, [XBLOCK, RBLOCK]) tmp41 = tl.sum(tmp39, 1)[:, None] tl.store(out_ptr1 + tl.full([XBLOCK, 1], 0, tl.int32), tmp41, None) tl.store(out_ptr2 + tl.full([XBLOCK, 1], 0, tl.int32), tmp41, None) @triton.jit def triton_poi_fused__log_softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_per_fused__log_softmax_add_div_mul_neg_sum_2(in_out_ptr0, in_out_ptr1, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r3 = rindex r0 = rindex % 16 r2 = rindex // 64 tmp0 = tl.load(in_ptr0 + r3, None) tmp1 = tl.load(in_ptr0 + (r0 + 64 * r2), None, eviction_policy='evict_last' ) tmp3 = tl.load(in_ptr0 + (16 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (32 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp9 = tl.load(in_ptr0 + (48 + r0 + 64 * r2), None, eviction_policy= 'evict_last') tmp14 = tl.load(in_ptr1 + r3, None) tmp22 = tl.load(in_out_ptr1 + 0) tmp23 = tl.broadcast_to(tmp22, [1]) tmp2 = tl_math.exp(tmp1) tmp4 = tl_math.exp(tmp3) tmp5 = tmp2 + tmp4 tmp7 = tl_math.exp(tmp6) tmp8 = tmp5 + tmp7 tmp10 = tl_math.exp(tmp9) tmp11 = tmp8 + tmp10 tmp12 = tl_math.log(tmp11) tmp13 = tmp0 - tmp12 tmp15 = tmp13 * tmp14 tmp16 = tl.broadcast_to(tmp15, [RBLOCK]) tmp18 = triton_helpers.promote_to_tensor(tl.sum(tmp16, 0)) tmp19 = -tmp18 tmp20 = 0.015625 tmp21 = tmp19 * tmp20 tmp24 = 0.01 tmp25 = tmp23 * tmp24 tmp26 = tmp25 + tmp21 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp21, None) tl.debug_barrier() tl.store(in_out_ptr1 + tl.full([1], 0, tl.int32), tmp26, None) def call(args): arg0_1, arg1_1, arg2_1, arg3_1, arg4_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg3_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg4_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf1 = empty_strided_cuda((), (), torch.float32) buf5 = empty_strided_cuda((), (), torch.float32) get_raw_stream(0) triton_per_fused_abs_add_relu_sub_sum_0[grid(1)](arg0_1, arg1_1, arg2_1, buf1, buf5, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax_1[grid(256)](arg4_1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg4_1 buf3 = empty_strided_cuda((), (), torch.float32) buf4 = buf3 del buf3 buf6 = buf1 del buf1 triton_per_fused__log_softmax_add_div_mul_neg_sum_2[grid(1)](buf4, buf6, buf2, arg3_1, 1, 256, num_warps=2, num_stages=1) del arg3_1 del buf2 return buf6, buf5, buf4 class TripletSoftmaxLossNew(nn.Module): def __init__(self, margin=0.0, lambda_factor=0.01): super(TripletSoftmaxLossNew, self).__init__() self.margin = margin self.loss_fn = nn.CrossEntropyLoss() self.lambda_factor = lambda_factor def forward(self, input_0, input_1, input_2, input_3, input_4): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 arg3_1 = input_3 arg4_1 = input_4 output = call([arg0_1, arg1_1, arg2_1, arg3_1, arg4_1]) return output[0], output[1], output[2]

Lm0079/MetricLearningIdentification

TripletSoftmaxLoss

false

2,526

[ "MIT" ]

0

3c2c0512fe2fbbb6aacb958106d5f6a03baedc35

https://github.com/Lm0079/MetricLearningIdentification/tree/3c2c0512fe2fbbb6aacb958106d5f6a03baedc35

FloorDiv

import torch class FloorDiv(torch.nn.Module): def __init__(self): super(FloorDiv, self).__init__() def forward(self, x, y): return x // y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class FloorDivNew(torch.nn.Module): def __init__(self): super(FloorDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

FloorDiv

false

2,527

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

SoftGeneratorPoolMLP

import torch import torch.nn.functional as F import torch.nn as nn from torch.nn import Linear class SoftGeneratorPoolMLP(nn.Module): def __init__(self, nin, nhid1, nhid2, nout=1, bias=True): nn.Module.__init__(self) self.bias = bias self.linear1 = Linear(nin, nhid1, bias=self.bias) self.linear2 = Linear(nhid1, nhid2, bias=self.bias) self.linear3 = Linear(nhid2, nin, bias=self.bias) """ def apply_bn(self, x): # Batch normalization of 3D tensor x bn_module = nn.BatchNorm1d(x.size()).cuda() return bn_module(x) """ def forward(self, x): x = torch.mean(x, dim=0).unsqueeze(0) x = F.relu(self.linear1(x)) x = F.relu(self.linear2(x)) x = self.linear3(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'nin': 4, 'nhid1': 4, 'nhid2': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn from torch.nn import Linear assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mean_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr0 + (64 + x0), xmask) tmp3 = tl.load(in_ptr0 + (128 + x0), xmask) tmp5 = tl.load(in_ptr0 + (192 + x0), xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tl.store(out_ptr0 + x0, tmp8, xmask) @triton.jit def triton_poi_fused_relu_threshold_backward_1(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mean_0[grid(64)](primals_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_1 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf0, (16, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = reinterpret_tensor(buf1, (1, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 buf7 = empty_strided_cuda((1, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(64)](buf2, primals_3, buf7, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_3 buf3 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf2, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf3) buf4 = reinterpret_tensor(buf3, (1, 4, 4, 4), (64, 16, 4, 1), 0) del buf3 buf6 = empty_strided_cuda((1, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(64)](buf4, primals_5, buf6, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_5 buf5 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, reinterpret_tensor(buf4, (16, 4), ( 4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf5) del primals_7 return reinterpret_tensor(buf5, (1, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(buf0, (16, 4), (4, 1), 0), reinterpret_tensor( buf2, (16, 4), (4, 1), 0), reinterpret_tensor(buf4, (16, 4), (4, 1), 0 ), primals_6, buf6, primals_4, buf7 class SoftGeneratorPoolMLPNew(nn.Module): def __init__(self, nin, nhid1, nhid2, nout=1, bias=True): nn.Module.__init__(self) self.bias = bias self.linear1 = Linear(nin, nhid1, bias=self.bias) self.linear2 = Linear(nhid1, nhid2, bias=self.bias) self.linear3 = Linear(nhid2, nin, bias=self.bias) """ def apply_bn(self, x): # Batch normalization of 3D tensor x bn_module = nn.BatchNorm1d(x.size()).cuda() return bn_module(x) """ def forward(self, input_0): primals_2 = self.linear1.weight primals_3 = self.linear1.bias primals_4 = self.linear2.weight primals_5 = self.linear2.bias primals_6 = self.linear3.weight primals_7 = self.linear3.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]

LinChen-65/pygcn

SoftGeneratorPoolMLP

false

2,528

[ "MIT" ]

0

0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

IDiv

import torch class IDiv(torch.nn.Module): def __init__(self): super(IDiv, self).__init__() def forward(self, x, y): x /= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IDivNew(torch.nn.Module): def __init__(self): super(IDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

IDiv

false

2,529

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

IAdd

import torch class IAdd(torch.nn.Module): def __init__(self): super(IAdd, self).__init__() def forward(self, x, y): x += y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_add_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class IAddNew(torch.nn.Module): def __init__(self): super(IAddNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

IAdd

false

2,530

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TensorClamp

import torch class TensorClamp(torch.nn.Module): def forward(self, x): return x.clamp(-0.1, 0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = -0.1 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = 0.1 tmp4 = triton_helpers.minimum(tmp2, tmp3) tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

TensorClamp

false

2,531

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

MaxPool1D

import torch class MaxPool1D(torch.nn.Module): def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False): super().__init__() self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode def forward(self, x): return torch.nn.functional.max_pool1d(x, self.kernel_size, stride= self.stride, padding=self.padding, ceil_mode=self.ceil_mode) def get_inputs(): return [torch.rand([4, 4])] def get_init_inputs(): return [[], {'kernel_size': 4}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_max_pool2d_with_indices_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last') tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tl.store(out_ptr0 + x0, tmp6, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 1), (1, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused_max_pool2d_with_indices_0[grid(4)](arg0_1, buf0, 4, XBLOCK=4, num_warps=1, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 1), (1, 1), 0), class MaxPool1DNew(torch.nn.Module): def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False): super().__init__() self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

MaxPool1D

false

2,532

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TensorClampMin

import torch class TensorClampMin(torch.nn.Module): def forward(self, x): return x.clamp_min(-0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_min_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = -0.1 tmp2 = triton_helpers.maximum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_min_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampMinNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

TensorClampMin

false

2,533

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

Pow

import torch class Pow(torch.nn.Module): def __init__(self): super(Pow, self).__init__() def forward(self, x, y): return x ** y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.pow(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class PowNew(torch.nn.Module): def __init__(self): super(PowNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

Pow

false

2,534

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

GT

import torch class GT(torch.nn.Module): def __init__(self): super(GT, self).__init__() def forward(self, x, y): return x > y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_gt_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 > tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_gt_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class GTNew(torch.nn.Module): def __init__(self): super(GTNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

GT

false

2,535

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RpowFloat

import torch class RpowFloat(torch.nn.Module): def __init__(self): super(RpowFloat, self).__init__() def forward(self, x): return 2.0 ** x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = libdevice.exp2(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RpowFloatNew(torch.nn.Module): def __init__(self): super(RpowFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RpowFloat

false

2,536

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

ModConst

import torch class ModConst(torch.nn.Module): def __init__(self): super(ModConst, self).__init__() def forward(self, x): return x % 2.0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_remainder_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 2.0 tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr0 + x0, tmp10, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class ModConstNew(torch.nn.Module): def __init__(self): super(ModConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

ModConst

false

2,537

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

MinElementwise

import torch class MinElementwise(torch.nn.Module): def forward(self, x, y): return torch.min(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_minimum_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = triton_helpers.minimum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_minimum_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MinElementwiseNew(torch.nn.Module): def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

MinElementwise

false

2,538

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RDivFloat

import torch class RDivFloat(torch.nn.Module): def __init__(self): super(RDivFloat, self).__init__() def forward(self, x): return 100.0 / x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_reciprocal_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.full([1], 1, tl.int32) tmp2 = tmp1 / tmp0 tmp3 = 100.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_reciprocal_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RDivFloatNew(torch.nn.Module): def __init__(self): super(RDivFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RDivFloat

false

2,539

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TensorSigmoid

import torch class TensorSigmoid(torch.nn.Module): def __init__(self): super(TensorSigmoid, self).__init__() def forward(self, x): return x.sigmoid() def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sigmoid_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sigmoid_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorSigmoidNew(torch.nn.Module): def __init__(self): super(TensorSigmoidNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

TensorSigmoid

false

2,540

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RpowInt

import torch class RpowInt(torch.nn.Module): def __init__(self): super(RpowInt, self).__init__() def forward(self, x): return 2 ** x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = libdevice.exp2(tmp0) tl.store(out_ptr0 + x0, tmp1, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RpowIntNew(torch.nn.Module): def __init__(self): super(RpowIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RpowInt

false

2,541

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

FunctionalConv3d

import torch class FunctionalConv3d(torch.nn.Module): def __init__(self, *args, **kwargs): super().__init__() self.conv = torch.nn.Conv3d(*args, **kwargs) def forward(self, x): x = torch.nn.functional.conv3d(x, self.conv.weight, self.conv.bias, self.conv.stride, self.conv.padding, self.conv.dilation, self. conv.groups) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4, 'kernel_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_out_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4, 4), (256, 64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(reinterpret_tensor(primals_3, (1, 4, 4, 4, 4), (256, 64, 16, 4, 1), 0), primals_1, stride=(1, 1, 1), padding=(0, 0, 0), dilation=(1, 1, 1), transposed=False, output_padding=(0, 0, 0), groups=1, bias=None) assert_size_stride(buf0, (1, 4, 1, 1, 1), (4, 1, 1, 1, 1)) buf1 = reinterpret_tensor(buf0, (1, 4, 1, 1, 1), (4, 1, 4, 4, 4), 0) del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(4)](buf1, primals_2, 4, XBLOCK= 4, num_warps=1, num_stages=1) del primals_2 return reinterpret_tensor(buf1, (4, 1, 1, 1), (1, 1, 1, 1), 0 ), primals_1, reinterpret_tensor(primals_3, (1, 4, 4, 4, 4), (256, 64, 16, 4, 1), 0) class FunctionalConv3dNew(torch.nn.Module): def __init__(self, *args, **kwargs): super().__init__() self.conv = torch.nn.Conv3d(*args, **kwargs) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

Ilyabasharov/torch2trt

FunctionalConv3d

false

2,542

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

PositionwiseFeedForward

import torch from torch import nn import torch.nn.functional as F class PositionwiseFeedForward(nn.Module): """ a　two layer feed forward""" def __init__(self, model_dim=512, ffn_dim=2048, dropout=0.1): super(PositionwiseFeedForward, self).__init__() self.w1 = nn.Conv1d(model_dim, ffn_dim, 1) self.w2 = nn.Conv1d(ffn_dim, model_dim, 1) self.layer_norm = nn.LayerNorm(model_dim) self.dropout = nn.Dropout(dropout) def forward(self, x): residual = x output = x.transpose(1, 2) output = self.w2(F.relu(self.w1(output))) output = self.dropout(output.transpose(1, 2)) output = self.layer_norm(residual + output) return output def get_inputs(): return [torch.rand([4, 512, 512])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 512 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y0 = yindex % 512 y1 = yindex // 512 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 512 * x2 + 262144 * y1), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 512 * y3), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_relu_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 512 % 2048 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x3, tmp4, None) @triton.jit def triton_poi_fused_convolution_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 512 % 512 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_red_fused_add_native_layer_norm_3(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr, RBLOCK: tl. constexpr): rnumel = 128 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rbase = tl.arange(0, RBLOCK)[None, :] x4 = xindex x0 = xindex % 4 x1 = xindex // 4 % 512 x2 = xindex // 2048 tmp4_mean = tl.zeros([XBLOCK, RBLOCK], tl.float32) tmp4_m2 = tl.zeros([XBLOCK, RBLOCK], tl.float32) tmp4_weight = tl.zeros([XBLOCK, RBLOCK], tl.float32) for roffset in range(0, rnumel, RBLOCK): rindex = roffset + rbase rmask = rindex < rnumel r3 = rindex tmp0 = tl.load(in_ptr0 + (r3 + 128 * x4), rmask, eviction_policy= 'evict_first', other=0.0) tmp1 = tl.load(in_ptr1 + (x1 + 512 * r3 + 65536 * x0 + 262144 * x2), rmask, eviction_policy='evict_last', other=0.0) tmp2 = tmp0 + tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp4_mean_next, tmp4_m2_next, tmp4_weight_next = (triton_helpers. welford_reduce(tmp3, tmp4_mean, tmp4_m2, tmp4_weight, roffset == 0) ) tmp4_mean = tl.where(rmask, tmp4_mean_next, tmp4_mean) tmp4_m2 = tl.where(rmask, tmp4_m2_next, tmp4_m2) tmp4_weight = tl.where(rmask, tmp4_weight_next, tmp4_weight) tmp4_tmp, tmp5_tmp, tmp6_tmp = triton_helpers.welford(tmp4_mean, tmp4_m2, tmp4_weight, 1) tmp4 = tmp4_tmp[:, None] tmp5 = tmp5_tmp[:, None] tmp6 = tmp6_tmp[:, None] tl.store(out_ptr0 + x4, tmp4, None) tl.store(out_ptr1 + x4, tmp5, None) tl.store(out_ptr2 + x4, tmp6, None) @triton.jit def triton_per_fused_add_native_layer_norm_4(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 4 * x0), None) tmp1 = tl.load(in_ptr1 + (r1 + 4 * x0), None) tmp2 = tl.load(in_ptr2 + (r1 + 4 * x0), None) tmp3 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp4 = tl.broadcast_to(tmp1, [XBLOCK, RBLOCK]) tmp5 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp7, tmp8, tmp9 = triton_helpers.welford(tmp3, tmp4, tmp5, 1) tmp10 = tmp7[:, None] tmp11 = tmp8[:, None] tmp9[:, None] tmp13 = 512.0 tmp14 = tmp11 / tmp13 tmp15 = 1e-05 tmp16 = tmp14 + tmp15 tmp17 = libdevice.rsqrt(tmp16) tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp17, None) tl.store(out_ptr0 + x0, tmp10, None) @triton.jit def triton_poi_fused_add_native_layer_norm_5(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 512 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 512 y1 = yindex // 512 tmp0 = tl.load(in_ptr0 + (x2 + 512 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + (y0 + 512 * x2 + 262144 * y1), xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + y3, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr3 + y3, None, eviction_policy='evict_last') tmp7 = tl.load(in_ptr4 + x2, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr5 + x2, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp6 = tmp4 * tmp5 tmp8 = tmp6 * tmp7 tmp10 = tmp8 + tmp9 tl.store(out_ptr0 + (x2 + 512 * y3), tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7) = args args.clear() assert_size_stride(primals_1, (4, 512, 512), (262144, 512, 1)) assert_size_stride(primals_2, (2048, 512, 1), (512, 1, 1)) assert_size_stride(primals_3, (2048,), (1,)) assert_size_stride(primals_4, (512, 2048, 1), (2048, 1, 1)) assert_size_stride(primals_5, (512,), (1,)) assert_size_stride(primals_6, (512,), (1,)) assert_size_stride(primals_7, (512,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 512, 512), (262144, 512, 1), torch. float32) get_raw_stream(0) triton_poi_fused_convolution_0[grid(2048, 512)](primals_1, buf0, 2048, 512, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf1, (4, 2048, 512), (1048576, 512, 1)) buf2 = buf1 del buf1 triton_poi_fused_convolution_relu_1[grid(4194304)](buf2, primals_3, 4194304, XBLOCK=1024, num_warps=4, num_stages=1) del primals_3 buf3 = extern_kernels.convolution(buf2, primals_4, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf3, (4, 512, 512), (262144, 512, 1)) buf4 = buf3 del buf3 triton_poi_fused_convolution_2[grid(1048576)](buf4, primals_5, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 buf5 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) buf6 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) buf7 = empty_strided_cuda((4, 512, 1, 4), (2048, 4, 8192, 1), torch .float32) triton_red_fused_add_native_layer_norm_3[grid(8192)](primals_1, buf4, buf5, buf6, buf7, 8192, 128, XBLOCK=64, RBLOCK=8, num_warps=4, num_stages=1) buf8 = empty_strided_cuda((4, 512, 1), (512, 1, 1), torch.float32) buf9 = empty_strided_cuda((4, 512, 1), (512, 1, 2048), torch.float32) buf11 = reinterpret_tensor(buf9, (4, 512, 1), (512, 1, 1), 0) del buf9 triton_per_fused_add_native_layer_norm_4[grid(2048)](buf11, buf5, buf6, buf7, buf8, 2048, 4, XBLOCK=128, num_warps=4, num_stages=1) del buf5 del buf6 del buf7 buf12 = buf0 del buf0 triton_poi_fused_add_native_layer_norm_5[grid(2048, 512)](primals_1, buf4, buf8, buf11, primals_6, primals_7, buf12, 2048, 512, XBLOCK=64, YBLOCK=64, num_warps=8, num_stages=1) del primals_7 return (buf12, primals_1, primals_2, primals_4, primals_6, buf2, buf4, buf8, buf11) class PositionwiseFeedForwardNew(nn.Module): """ a　two layer feed forward""" def __init__(self, model_dim=512, ffn_dim=2048, dropout=0.1): super(PositionwiseFeedForwardNew, self).__init__() self.w1 = nn.Conv1d(model_dim, ffn_dim, 1) self.w2 = nn.Conv1d(ffn_dim, model_dim, 1) self.layer_norm = nn.LayerNorm(model_dim) self.dropout = nn.Dropout(dropout) def forward(self, input_0): primals_2 = self.w1.weight primals_3 = self.w1.bias primals_4 = self.w2.weight primals_5 = self.w2.bias primals_6 = self.layer_norm.weight primals_7 = self.layer_norm.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]

LinXueyuanStdio/scRNN-seq

PositionwiseFeedForward

false

2,543

[ "Apache-2.0" ]

0

87e11a56acb18a86fa4fb309d33a1bc02bf38b39

https://github.com/LinXueyuanStdio/scRNN-seq/tree/87e11a56acb18a86fa4fb309d33a1bc02bf38b39

RSubInt

import torch class RSubInt(torch.nn.Module): def __init__(self): super(RSubInt, self).__init__() def forward(self, x): return 1 - x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_rsub_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_rsub_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RSubIntNew(torch.nn.Module): def __init__(self): super(RSubIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RSubInt

false

2,544

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

ISub

import torch class ISub(torch.nn.Module): def __init__(self): super(ISub, self).__init__() def forward(self, x, y): x -= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr1 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class ISubNew(torch.nn.Module): def __init__(self): super(ISubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

ISub

false

2,545

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

Sub

import torch class Sub(torch.nn.Module): def __init__(self): super(Sub, self).__init__() def forward(self, x, y): return x - y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class SubNew(torch.nn.Module): def __init__(self): super(SubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

Sub

false

2,546

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TensorClampMax

import torch class TensorClampMax(torch.nn.Module): def forward(self, x): return x.clamp_max(0.1) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_clamp_max_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.1 tmp2 = triton_helpers.minimum(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_max_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TensorClampMaxNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

TensorClampMax

false

2,547

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RAddFloat

import torch class RAddFloat(torch.nn.Module): def __init__(self): super(RAddFloat, self).__init__() def forward(self, x): return 1.0 + x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RAddFloatNew(torch.nn.Module): def __init__(self): super(RAddFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RAddFloat

false

2,548

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RMulInt

import torch class RMulInt(torch.nn.Module): def __init__(self): super(RMulInt, self).__init__() def forward(self, x): return 10 * x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 10.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RMulIntNew(torch.nn.Module): def __init__(self): super(RMulIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RMulInt

false

2,549

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

ModAssign

import torch class ModAssign(torch.nn.Module): def __init__(self): super(ModAssign, self).__init__() def forward(self, x, y): x %= y return x def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_remainder_0(in_ptr0, in_ptr1, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr1 + x0, tmp10, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, arg1_1, arg0_1, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg1_1 return arg0_1, class ModAssignNew(torch.nn.Module): def __init__(self): super(ModAssignNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

ModAssign

false

2,550

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RDivInt

import torch class RDivInt(torch.nn.Module): def __init__(self): super(RDivInt, self).__init__() def forward(self, x): return 100 / x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_reciprocal_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.full([1], 1, tl.int32) tmp2 = tmp1 / tmp0 tmp3 = 100.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_reciprocal_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RDivIntNew(torch.nn.Module): def __init__(self): super(RDivIntNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RDivInt

false

2,551

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

GeM

import torch import torch.nn as nn import torch.nn.functional as F import torch.nn.functional from torch.nn import Parameter from torch.nn.parameter import Parameter import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd class GeM(nn.Module): def __init__(self, p=3.0, eps=1e-06, freeze_p=True): super(GeM, self).__init__() self.p = p if freeze_p else Parameter(torch.ones(1) * p) self.eps = eps def forward(self, x): return F.adaptive_avg_pool2d(x.clamp(min=self.eps).pow(self.p), (1, 1) ).pow(1.0 / self.p) def __repr__(self): if isinstance(self.p, float): p = self.p else: p = self.p.data.tolist()[0] return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(p ) + ', ' + 'eps=' + str(self.eps) + ')' def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn import torch.nn.functional from torch.nn import Parameter from torch.nn.parameter import Parameter import torch.nn.parallel import torch.utils.data import torch.optim import torch.utils.data.distributed import torch.autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_per_fused_clamp_mean_pow_0(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 16 RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 16 * x0), xmask, other=0.0) tmp1 = 1e-06 tmp2 = triton_helpers.maximum(tmp0, tmp1) tmp3 = tmp2 * tmp2 tmp4 = tmp3 * tmp2 tmp5 = tl.broadcast_to(tmp4, [XBLOCK, RBLOCK]) tmp7 = tl.where(xmask, tmp5, 0) tmp8 = tl.sum(tmp7, 1)[:, None] tmp9 = 16.0 tmp10 = tmp8 / tmp9 tmp11 = 0.3333333333333333 tmp12 = libdevice.pow(tmp10, tmp11) tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp12, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 16, 16), torch.float32) buf1 = reinterpret_tensor(buf0, (4, 4, 1, 1), (4, 1, 1, 1), 0) del buf0 get_raw_stream(0) triton_per_fused_clamp_mean_pow_0[grid(16)](buf1, arg0_1, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 return buf1, class GeMNew(nn.Module): def __init__(self, p=3.0, eps=1e-06, freeze_p=True): super(GeMNew, self).__init__() self.p = p if freeze_p else Parameter(torch.ones(1) * p) self.eps = eps def __repr__(self): if isinstance(self.p, float): p = self.p else: p = self.p.data.tolist()[0] return self.__class__.__name__ + '(' + 'p=' + '{:.4f}'.format(p ) + ', ' + 'eps=' + str(self.eps) + ')' def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Liuhongzhi2018/Person_ReID

GeM

false

2,552

[ "MIT" ]

0

51c576ed5b4ed960801669d6d59c0a77405b369d

https://github.com/Liuhongzhi2018/Person_ReID/tree/51c576ed5b4ed960801669d6d59c0a77405b369d

RMulFloat

import torch class RMulFloat(torch.nn.Module): def __init__(self): super(RMulFloat, self).__init__() def forward(self, x): return 10.0 * x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 10.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RMulFloatNew(torch.nn.Module): def __init__(self): super(RMulFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RMulFloat

false

2,553

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

NotEqual

import torch class NotEqual(torch.nn.Module): def __init__(self): super(NotEqual, self).__init__() def forward(self, x, y): return x != y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class NotEqualNew(torch.nn.Module): def __init__(self): super(NotEqualNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

NotEqual

false

2,554

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

D_DownBlock

import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class D_DownBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, num_stages=1, bias=True, activation='prelu', norm=None): super(D_DownBlock, self).__init__() self.conv = ConvBlock(num_filter * num_stages, num_filter, 1, 1, 0, activation, norm=None) self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): x = self.conv(x) l0 = self.down_conv1(x) h0 = self.down_conv2(l0) l1 = self.down_conv3(h0 - x) return l1 + l0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_1(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp8, xmask) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_3(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x2, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x2, tmp2, xmask) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13) = args args.clear() assert_size_stride(primals_1, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) assert_size_stride(primals_11, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_12, (4,), (1,)) assert_size_stride(primals_13, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 4, 4), (64, 16, 4, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(256)](buf1, primals_2, primals_4, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 1, 1), (4, 1, 1, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_1[grid(16)](buf4, primals_6, primals_7, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 4, 4), (64, 16, 4, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_2[grid(256)](buf7, primals_9, primals_10, buf2, buf8, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_9 buf9 = extern_kernels.convolution(buf8, primals_11, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf9, (4, 4, 1, 1), (4, 1, 1, 1)) buf10 = buf9 del buf9 buf11 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused__prelu_kernel_add_convolution_3[grid(16)](buf10, primals_12, primals_13, buf5, buf11, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_12 return (buf11, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, primals_11, primals_13, buf1, buf2, buf4, buf5, buf7, buf8, buf10) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class D_DownBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, num_stages=1, bias=True, activation='prelu', norm=None): super(D_DownBlockNew, self).__init__() self.conv = ConvBlock(num_filter * num_stages, num_filter, 1, 1, 0, activation, norm=None) self.down_conv1 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv2 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.down_conv3 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.conv.conv.weight primals_2 = self.conv.conv.bias primals_4 = self.conv.act.weight primals_5 = self.down_conv1.conv.weight primals_6 = self.down_conv1.conv.bias primals_7 = self.down_conv1.act.weight primals_8 = self.down_conv2.deconv.weight primals_9 = self.down_conv2.deconv.bias primals_10 = self.down_conv2.act.weight primals_11 = self.down_conv3.conv.weight primals_12 = self.down_conv3.conv.bias primals_13 = self.down_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12, primals_13]) return output[0]

DengZeshuai/DBPN-Pytorch

D_DownBlock

false

2,555

[ "MIT" ]

0

a90d241a1c4b07830c6d812ad8389d13e8cf05d1

https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1

NotEqualConst

import torch class NotEqualConst(torch.nn.Module): def __init__(self): super(NotEqualConst, self).__init__() def forward(self, x): return x != 13.62 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 13.62 tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class NotEqualConstNew(torch.nn.Module): def __init__(self): super(NotEqualConstNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

NotEqualConst

false

2,556

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchMod

import torch class TorchMod(torch.nn.Module): def __init__(self): super(TorchMod, self).__init__() def forward(self, x, y): return torch.fmod(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_fmod_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.fmod(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_fmod_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchModNew(torch.nn.Module): def __init__(self): super(TorchModNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchMod

false

2,557

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchFloorDiv

import torch class TorchFloorDiv(torch.nn.Module): def __init__(self): super(TorchFloorDiv, self).__init__() def forward(self, x, y): return torch.floor_divide(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_floor_divide_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tmp3 = libdevice.floor(tmp2) tl.store(out_ptr0 + x0, tmp3, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_floor_divide_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchFloorDivNew(torch.nn.Module): def __init__(self): super(TorchFloorDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchFloorDiv

false

2,558

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchSub

import torch class TorchSub(torch.nn.Module): def __init__(self): super(TorchSub, self).__init__() def forward(self, x, y): return torch.sub(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_sub_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 - tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_sub_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchSubNew(torch.nn.Module): def __init__(self): super(TorchSubNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchSub

false

2,559

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

RSubFloat

import torch class RSubFloat(torch.nn.Module): def __init__(self): super(RSubFloat, self).__init__() def forward(self, x): return 1.0 - x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_rsub_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp1 - tmp0 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_rsub_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class RSubFloatNew(torch.nn.Module): def __init__(self): super(RSubFloatNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Ilyabasharov/torch2trt

RSubFloat

false

2,560

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchMul

import torch class TorchMul(torch.nn.Module): def __init__(self): super(TorchMul, self).__init__() def forward(self, x, y): return torch.mul(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchMulNew(torch.nn.Module): def __init__(self): super(TorchMulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchMul

false

2,561

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchNotEqual

import torch class TorchNotEqual(torch.nn.Module): def __init__(self): super(TorchNotEqual, self).__init__() def forward(self, x, y): return torch.ne(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_ne_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 != tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) get_raw_stream(0) triton_poi_fused_ne_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK= 128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchNotEqualNew(torch.nn.Module): def __init__(self): super(TorchNotEqualNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchNotEqual

false

2,562

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

Upsampler

import math import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class Upsampler(torch.nn.Module): def __init__(self, scale, n_feat, bn=False, act='prelu', bias=True): super(Upsampler, self).__init__() modules = [] for _ in range(int(math.log(scale, 2))): modules.append(ConvBlock(n_feat, 4 * n_feat, 3, 1, 1, bias, activation=None, norm=None)) modules.append(torch.nn.PixelShuffle(2)) if bn: modules.append(torch.nn.BatchNorm2d(n_feat)) self.up = torch.nn.Sequential(*modules) self.activation = act if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): out = self.up(x) if self.activation is not None: out = self.act(out) return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'scale': 1.0, 'n_feat': 4}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import math from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp3 = tl.load(in_ptr1 + 0) tmp4 = tl.broadcast_to(tmp3, [XBLOCK]) tmp1 = 0.0 tmp2 = tmp0 > tmp1 tmp5 = tmp4 * tmp0 tmp6 = tl.where(tmp2, tmp0, tmp5) tl.store(out_ptr0 + x0, tmp6, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_0[grid(256)](primals_1, primals_2, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 return buf0, primals_1 class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class UpsamplerNew(torch.nn.Module): def __init__(self, scale, n_feat, bn=False, act='prelu', bias=True): super(UpsamplerNew, self).__init__() modules = [] for _ in range(int(math.log(scale, 2))): modules.append(ConvBlock(n_feat, 4 * n_feat, 3, 1, 1, bias, activation=None, norm=None)) modules.append(torch.nn.PixelShuffle(2)) if bn: modules.append(torch.nn.BatchNorm2d(n_feat)) self.up = torch.nn.Sequential(*modules) self.activation = act if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, input_0): primals_2 = self.act.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0]

DengZeshuai/DBPN-Pytorch

Upsampler

false

2,563

[ "MIT" ]

0

a90d241a1c4b07830c6d812ad8389d13e8cf05d1

https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1

TorchPow

import torch class TorchPow(torch.nn.Module): def __init__(self): super(TorchPow, self).__init__() def forward(self, x, y): return torch.pow(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_pow_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = libdevice.pow(tmp0, tmp1) tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_pow_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchPowNew(torch.nn.Module): def __init__(self): super(TorchPowNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchPow

false

2,564

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

Mod

import torch class Mod(torch.nn.Module): def __init__(self): super(Mod, self).__init__() def forward(self, x, y): return x % y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_remainder_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 % tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = tmp2 != tmp3 tmp5 = libdevice.signbit(tmp2) if tmp2.dtype is tl.float32 else tmp2 < 0 tmp6 = libdevice.signbit(tmp1) if tmp1.dtype is tl.float32 else tmp1 < 0 tmp7 = tmp5 != tmp6 tmp8 = tmp4 & tmp7 tmp9 = tmp2 + tmp1 tmp10 = tl.where(tmp8, tmp9, tmp2) tl.store(out_ptr0 + x0, tmp10, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_remainder_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class ModNew(torch.nn.Module): def __init__(self): super(ModNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

Mod

false

2,565

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

ContextGate

import torch import torch.nn as nn import torch.cuda import torch.distributed class ContextGate(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGate, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, prev_emb, dec_state, attn_state): input_tensor = torch.cat((prev_emb, dec_state, attn_state), dim=1) z = self.sig(self.gate(input_tensor)) proj_source = self.source_proj(attn_state) proj_target = self.target_proj(torch.cat((prev_emb, dec_state), dim=1)) return z, proj_source, proj_target def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'embeddings_size': 4, 'decoder_size': 4, 'attention_size': 4, 'output_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.distributed assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_cat_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 12 x1 = xindex // 12 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tmp7 = tl.full([1], 8, tl.int64) tmp8 = tmp0 < tmp7 tmp9 = tmp6 & tmp8 tmp10 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp9 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp0 >= tmp7 tl.full([1], 12, tl.int64) tmp14 = tl.load(in_ptr2 + (4 * x1 + (-8 + x0)), tmp11 & xmask, eviction_policy='evict_last', other=0.0) tmp15 = tl.where(tmp9, tmp10, tmp14) tmp16 = tl.where(tmp4, tmp5, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_sigmoid_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.sigmoid(tmp2) tl.store(in_out_ptr0 + x2, tmp3, xmask) @triton.jit def triton_poi_fused_cat_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (4 * x1 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp9 = tl.load(in_ptr1 + (4 * x1 + (-4 + x0)), tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x2, tmp10, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 12), (12, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4), (4, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 8), (8, 1)) assert_size_stride(primals_9, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 12), (12, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(48)](primals_1, primals_2, primals_3, buf0, 48, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_4, (12, 4), (1, 12), 0), out=buf1) del primals_4 buf2 = buf1 del buf1 triton_poi_fused_sigmoid_1[grid(16)](buf2, primals_5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_5 buf3 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_7, primals_3, reinterpret_tensor( primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf3) del primals_6 del primals_7 buf4 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_2[grid(32)](primals_1, primals_2, buf4, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_9, buf4, reinterpret_tensor(primals_8, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf5) del primals_8 del primals_9 return buf2, buf3, buf5, primals_3, buf0, buf2, buf4 class ContextGateNew(nn.Module): """ Context gate is a decoder module that takes as input the previous word embedding, the current decoder state and the attention state, and produces a gate. The gate can be used to select the input from the target side context (decoder state), from the source context (attention state) or both. """ def __init__(self, embeddings_size, decoder_size, attention_size, output_size): super(ContextGateNew, self).__init__() input_size = embeddings_size + decoder_size + attention_size self.gate = nn.Linear(input_size, output_size, bias=True) self.sig = nn.Sigmoid() self.source_proj = nn.Linear(attention_size, output_size) self.target_proj = nn.Linear(embeddings_size + decoder_size, output_size) def forward(self, input_0, input_1, input_2): primals_4 = self.gate.weight primals_5 = self.gate.bias primals_1 = self.source_proj.weight primals_7 = self.source_proj.bias primals_8 = self.target_proj.weight primals_9 = self.target_proj.bias primals_2 = input_0 primals_3 = input_1 primals_6 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0], output[1], output[2]

LeeeeoLiu/OpenNMT-py

ContextGate

false

2,566

[ "MIT" ]

0

9be3a8951e9181aabe5440e4ea98173b7e749b5c

https://github.com/LeeeeoLiu/OpenNMT-py/tree/9be3a8951e9181aabe5440e4ea98173b7e749b5c

PixelShuffle

import torch import torch.nn as nn import torch.nn.parallel class PixelShuffle(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, x): ry = self.ry rx = self.rx [B, C, H, W] = list(x.shape) x = x.reshape(B, C // (ry * rx), ry, rx, H, W) x = x.permute(0, 1, 4, 2, 5, 3) x = x.reshape(B, C // (ry * rx), H * ry, W * rx) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.parallel assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 128 xnumel = 2 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x4 = xindex y0 = yindex % 4 y1 = yindex // 4 % 2 y2 = yindex // 8 % 4 y3 = yindex // 32 y5 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * y2 + 16 * x4 + 32 * y1 + 64 * y3), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x4 + 2 * y5), tmp0, xmask & ymask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 1, 4, 2, 4, 2), (64, 64, 16, 8, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(128, 2)](arg0_1, buf0, 128, 2, XBLOCK =2, YBLOCK=64, num_warps=4, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 1, 8, 8), (64, 64, 8, 1), 0), class PixelShuffleNew(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

LonglifeHyun/GANda_text-to-image

PixelShuffle

false

2,567

[ "MIT" ]

0

095ded617e4df7d7ff7f4954381dde77db6d6883

https://github.com/LonglifeHyun/GANda_text-to-image/tree/095ded617e4df7d7ff7f4954381dde77db6d6883

Mul

import torch class Mul(torch.nn.Module): def __init__(self): super(Mul, self).__init__() def forward(self, x, y): return x * y def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(256)](arg0_1, arg1_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class MulNew(torch.nn.Module): def __init__(self): super(MulNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

Mul

false

2,568

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

PixelUnshuffle

import torch import torch.nn as nn import torch.nn.parallel class PixelUnshuffle(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, x): ry = self.ry rx = self.rx [B, C, H, W] = list(x.shape) x = x.reshape(B, C, H // ry, ry, W // rx, rx) x = x.permute(0, 1, 3, 5, 2, 4) x = x.reshape(B, C * (ry * rx), H // ry, W // rx) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.nn.parallel assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_clone_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 64 xnumel = 4 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x3 = xindex % 2 x4 = xindex // 2 y0 = yindex % 2 y1 = yindex // 2 % 2 y2 = yindex // 4 x6 = xindex y5 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 2 * x3 + 4 * y1 + 8 * x4 + 16 * y2), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x6 + 4 * y5), tmp0, xmask & ymask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 2, 2, 2, 2), (64, 16, 8, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(64, 4)](arg0_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 16, 2, 2), (64, 4, 2, 1), 0), class PixelUnshuffleNew(nn.Module): def __init__(self, ry=2, rx=2): super().__init__() self.ry = ry self.rx = rx def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

LonglifeHyun/GANda_text-to-image

PixelUnshuffle

false

2,569

[ "MIT" ]

0

095ded617e4df7d7ff7f4954381dde77db6d6883

https://github.com/LonglifeHyun/GANda_text-to-image/tree/095ded617e4df7d7ff7f4954381dde77db6d6883

TorchDiv

import torch class TorchDiv(torch.nn.Module): def __init__(self): super(TorchDiv, self).__init__() def forward(self, x, y): return torch.div(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_div_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 / tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchDivNew(torch.nn.Module): def __init__(self): super(TorchDivNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchDiv

false

2,570

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

TorchAdd

import torch class TorchAdd(torch.nn.Module): def __init__(self): super(TorchAdd, self).__init__() def forward(self, x, y): return torch.add(x, y) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_0(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask) tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_0[grid(256)](arg1_1, arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchAddNew(torch.nn.Module): def __init__(self): super(TorchAddNew, self).__init__() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Ilyabasharov/torch2trt

TorchAdd

false

2,571

[ "MIT" ]

0

76bf298b3da408509665e23e2494922b131afb10

https://github.com/Ilyabasharov/torch2trt/tree/76bf298b3da408509665e23e2494922b131afb10

UpBlock

import torch from torchvision.transforms import * class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class UpBlock(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(UpBlock, self).__init__() self.up_conv1 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv2 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv3 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, x): h0 = self.up_conv1(x) l0 = self.up_conv2(h0) h1 = self.up_conv3(l0 - x) return h1 + h0 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_filter': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torchvision.transforms import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__prelu_kernel_convolution_0(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 256 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp8, None) @triton.jit def triton_poi_fused__prelu_kernel_convolution_sub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 - tmp9 tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__prelu_kernel_add_convolution_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 256 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 0) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr2 + x3, None) tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp7 = tmp6 * tmp2 tmp8 = tl.where(tmp4, tmp2, tmp7) tmp10 = tmp8 + tmp9 tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp10, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10) = args args.clear() assert_size_stride(primals_1, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (1,), (1,)) assert_size_stride(primals_5, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (1,), (1,)) assert_size_stride(primals_8, (4, 4, 8, 8), (256, 64, 8, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 16, 16), (1024, 256, 16, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) get_raw_stream(0) triton_poi_fused__prelu_kernel_convolution_0[grid(4096)](buf1, primals_2, primals_4, buf2, 4096, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf3 = extern_kernels.convolution(buf2, primals_5, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 4, 4), (64, 16, 4, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__prelu_kernel_convolution_sub_1[grid(256)](buf4, primals_6, primals_7, primals_3, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(4, 4), padding=(2, 2), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 16, 16), (1024, 256, 16, 1)) buf7 = buf6 del buf6 buf8 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) triton_poi_fused__prelu_kernel_add_convolution_2[grid(4096)](buf7, primals_9, primals_10, buf2, buf8, 4096, XBLOCK=256, num_warps= 4, num_stages=1) del primals_9 return (buf8, primals_1, primals_3, primals_4, primals_5, primals_7, primals_8, primals_10, buf1, buf2, buf4, buf5, buf7) class ConvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=3, stride=1, padding=1, bias=True, activation='prelu', norm=None): super(ConvBlock, self).__init__() self.conv = torch.nn.Conv2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.conv(x)) else: out = self.conv(x) if self.activation is not None: return self.act(out) else: return out class DeconvBlock(torch.nn.Module): def __init__(self, input_size, output_size, kernel_size=4, stride=2, padding=1, bias=True, activation='prelu', norm=None): super(DeconvBlock, self).__init__() self.deconv = torch.nn.ConvTranspose2d(input_size, output_size, kernel_size, stride, padding, bias=bias) self.norm = norm if self.norm == 'batch': self.bn = torch.nn.BatchNorm2d(output_size) elif self.norm == 'instance': self.bn = torch.nn.InstanceNorm2d(output_size) self.activation = activation if self.activation == 'relu': self.act = torch.nn.ReLU(True) elif self.activation == 'prelu': self.act = torch.nn.PReLU() elif self.activation == 'lrelu': self.act = torch.nn.LeakyReLU(0.2, True) elif self.activation == 'tanh': self.act = torch.nn.Tanh() elif self.activation == 'sigmoid': self.act = torch.nn.Sigmoid() def forward(self, x): if self.norm is not None: out = self.bn(self.deconv(x)) else: out = self.deconv(x) if self.activation is not None: return self.act(out) else: return out class UpBlockNew(torch.nn.Module): def __init__(self, num_filter, kernel_size=8, stride=4, padding=2, bias =True, activation='prelu', norm=None): super(UpBlockNew, self).__init__() self.up_conv1 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv2 = ConvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) self.up_conv3 = DeconvBlock(num_filter, num_filter, kernel_size, stride, padding, activation, norm=None) def forward(self, input_0): primals_1 = self.up_conv1.deconv.weight primals_2 = self.up_conv1.deconv.bias primals_4 = self.up_conv1.act.weight primals_5 = self.up_conv2.conv.weight primals_6 = self.up_conv2.conv.bias primals_7 = self.up_conv2.act.weight primals_8 = self.up_conv3.deconv.weight primals_9 = self.up_conv3.deconv.bias primals_10 = self.up_conv3.act.weight primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10]) return output[0]

DengZeshuai/DBPN-Pytorch

UpBlock

false

2,572

[ "MIT" ]

0

a90d241a1c4b07830c6d812ad8389d13e8cf05d1

https://github.com/DengZeshuai/DBPN-Pytorch/tree/a90d241a1c4b07830c6d812ad8389d13e8cf05d1

AtenSoftmaxRepalce

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AtenSoftmaxRepalce(nn.Module): def __init__(self, dim=-1): super(AtenSoftmaxRepalce, self).__init__() self.softmax = torch.nn.Softmax(dim) def forward(self, x): return self.softmax(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf0 return buf1, class AtenSoftmaxRepalceNew(nn.Module): def __init__(self, dim=-1): super(AtenSoftmaxRepalceNew, self).__init__() self.softmax = torch.nn.Softmax(dim) def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

JudeDavis1/intel-extension-for-pytorch

AtenSoftmaxRepalce

false

2,573

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

UPChannelBAN

import torch import torch.nn.functional as F import torch.nn as nn def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class BAN(nn.Module): """ BAN基础构造函数 """ def __init__(self): super(BAN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelBAN(BAN): def __init__(self, feature_in=256, cls_out_channels=2): super(UPChannelBAN, self).__init__() cls_output = cls_out_channels loc_output = 4 self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, z_f, x_f): cls_kernel = self.template_cls_conv(z_f) loc_kernel = self.template_loc_conv(z_f) cls_feature = self.search_cls_conv(x_f) loc_feature = self.search_loc_conv(x_f) cls = xcorr_fast(cls_feature, cls_kernel) loc = self.loc_adjust(xcorr_fast(loc_feature, loc_kernel)) return cls, loc def get_inputs(): return [torch.rand([4, 256, 64, 64]), torch.rand([4, 256, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional as F import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_view_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 512 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 3844 % 256 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_poi_fused_convolution_view_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 1024 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12 ) = args args.clear() assert_size_stride(primals_1, (512, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_2, (512,), (1,)) assert_size_stride(primals_3, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_4, (1024, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_5, (1024,), (1,)) assert_size_stride(primals_6, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_9, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_10, (256,), (1,)) assert_size_stride(primals_11, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_12, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 512, 62, 62), (1968128, 3844, 62, 1)) buf1 = extern_kernels.convolution(primals_3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 1024, 62, 62), (3936256, 3844, 62, 1)) buf2 = extern_kernels.convolution(primals_8, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf3 = extern_kernels.convolution(primals_8, primals_9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf4 = buf0 del buf0 buf5 = reinterpret_tensor(buf4, (8, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf4 get_raw_stream(0) triton_poi_fused_convolution_view_0[grid(7872512)](buf5, primals_2, 7872512, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf6 = buf2 del buf2 triton_poi_fused_convolution_1[grid(3936256)](buf6, primals_7, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_7 buf7 = extern_kernels.convolution(reinterpret_tensor(buf6, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf5, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf7, (1, 8, 1, 1), (8, 1, 1, 1)) buf8 = buf1 del buf1 buf9 = reinterpret_tensor(buf8, (16, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf8 triton_poi_fused_convolution_view_2[grid(15745024)](buf9, primals_5, 15745024, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf10 = buf3 del buf3 triton_poi_fused_convolution_1[grid(3936256)](buf10, primals_10, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_10 buf11 = extern_kernels.convolution(reinterpret_tensor(buf10, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf11, (1, 16, 1, 1), (16, 1, 1, 1)) buf12 = extern_kernels.convolution(reinterpret_tensor(buf11, (4, 4, 1, 1), (4, 1, 1, 1), 0), primals_11, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf12, (4, 4, 1, 1), (4, 1, 1, 1)) buf13 = buf12 del buf12 triton_poi_fused_convolution_3[grid(16)](buf13, primals_12, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_12 return (reinterpret_tensor(buf7, (4, 2, 1, 1), (2, 1, 1, 1), 0), buf13, primals_1, primals_3, primals_4, primals_6, primals_8, primals_9, primals_11, buf5, reinterpret_tensor(buf6, (1, 1024, 62, 62), ( 3936256, 3844, 62, 1), 0), buf9, reinterpret_tensor(buf10, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), reinterpret_tensor(buf11, (4, 4, 1, 1), (4, 1, 1, 1), 0)) def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class BAN(nn.Module): """ BAN基础构造函数 """ def __init__(self): super(BAN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelBANNew(BAN): def __init__(self, feature_in=256, cls_out_channels=2): super(UPChannelBANNew, self).__init__() cls_output = cls_out_channels loc_output = 4 self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, input_0, input_1): primals_1 = self.template_cls_conv.weight primals_2 = self.template_cls_conv.bias primals_4 = self.template_loc_conv.weight primals_5 = self.template_loc_conv.bias primals_6 = self.search_cls_conv.weight primals_7 = self.search_cls_conv.bias primals_9 = self.search_loc_conv.weight primals_10 = self.search_loc_conv.bias primals_11 = self.loc_adjust.weight primals_12 = self.loc_adjust.bias primals_3 = input_0 primals_8 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12]) return output[0], output[1]

IRLSCU/siamban

UPChannelBAN

false

2,574

[ "Apache-2.0" ]

0

abb12d028e93aaee74efc5042a5bb305c7805053

https://github.com/IRLSCU/siamban/tree/abb12d028e93aaee74efc5042a5bb305c7805053

inplace_softmax

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class inplace_softmax(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): x1 = x + 1 x2 = nn.Softmax(dim=-1)(x1) return x2 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_add_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp1 = 1.0 tmp2 = tmp0 + tmp1 tmp4 = tmp3 + tmp1 tmp6 = tmp5 + tmp1 tmp7 = triton_helpers.maximum(tmp4, tmp6) tmp9 = tmp8 + tmp1 tmp10 = triton_helpers.maximum(tmp7, tmp9) tmp12 = tmp11 + tmp1 tmp13 = triton_helpers.maximum(tmp10, tmp12) tmp14 = tmp2 - tmp13 tmp15 = tl_math.exp(tmp14) tl.store(out_ptr0 + x2, tmp15, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x2, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_add_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf0 return buf1, class inplace_softmaxNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

JudeDavis1/intel-extension-for-pytorch

inplace_softmax

false

2,575

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

CharbonnierLoss

import functools import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def reduce_loss(loss, reduction): """Reduce loss as specified. Args: loss (Tensor): Elementwise loss tensor. reduction (str): Options are 'none', 'mean' and 'sum'. Returns: Tensor: Reduced loss tensor. """ reduction_enum = F._Reduction.get_enum(reduction) if reduction_enum == 0: return loss elif reduction_enum == 1: return loss.mean() else: return loss.sum() def weight_reduce_loss(loss, weight=None, reduction='mean'): """Apply element-wise weight and reduce loss. Args: loss (Tensor): Element-wise loss. weight (Tensor): Element-wise weights. Default: None. reduction (str): Same as built-in losses of PyTorch. Options are 'none', 'mean' and 'sum'. Default: 'mean'. Returns: Tensor: Loss values. """ if weight is not None: assert weight.dim() == loss.dim() assert weight.size(1) == 1 or weight.size(1) == loss.size(1) loss = loss * weight if weight is None or reduction == 'sum': loss = reduce_loss(loss, reduction) elif reduction == 'mean': if weight.size(1) > 1: weight = weight.sum() else: weight = weight.sum() * loss.size(1) loss = loss.sum() / weight return loss def weighted_loss(loss_func): """Create a weighted version of a given loss function. To use this decorator, the loss function must have the signature like `loss_func(pred, target, **kwargs)`. The function only needs to compute element-wise loss without any reduction. This decorator will add weight and reduction arguments to the function. The decorated function will have the signature like `loss_func(pred, target, weight=None, reduction='mean', **kwargs)`. :Example: >>> import torch >>> @weighted_loss >>> def l1_loss(pred, target): >>> return (pred - target).abs() >>> pred = torch.Tensor([0, 2, 3]) >>> target = torch.Tensor([1, 1, 1]) >>> weight = torch.Tensor([1, 0, 1]) >>> l1_loss(pred, target) tensor(1.3333) >>> l1_loss(pred, target, weight) tensor(1.5000) >>> l1_loss(pred, target, reduction='none') tensor([1., 1., 2.]) >>> l1_loss(pred, target, weight, reduction='sum') tensor(3.) """ @functools.wraps(loss_func) def wrapper(pred, target, weight=None, reduction='mean', **kwargs): loss = loss_func(pred, target, **kwargs) loss = weight_reduce_loss(loss, weight, reduction) return loss return wrapper @weighted_loss def charbonnier_loss(pred, target, eps=1e-12): return torch.sqrt((pred - target) ** 2 + eps) class CharbonnierLoss(nn.Module): """Charbonnier loss (one variant of Robust L1Loss, a differentiable variant of L1Loss). Described in "Deep Laplacian Pyramid Networks for Fast and Accurate Super-Resolution". Args: loss_weight (float): Loss weight for L1 loss. Default: 1.0. reduction (str): Specifies the reduction to apply to the output. Supported choices are 'none' | 'mean' | 'sum'. Default: 'mean'. eps (float): A value used to control the curvature near zero. Default: 1e-12. """ def __init__(self, loss_weight=1.0, reduction='mean', eps=1e-12): super(CharbonnierLoss, self).__init__() if reduction not in ['none', 'mean', 'sum']: raise ValueError( f'Unsupported reduction mode: {reduction}. Supported ones are: {_reduction_modes}' ) self.loss_weight = loss_weight self.reduction = reduction self.eps = eps def forward(self, pred, target, weight=None, **kwargs): """ Args: pred (Tensor): of shape (N, C, H, W). Predicted tensor. target (Tensor): of shape (N, C, H, W). Ground truth tensor. weight (Tensor, optional): of shape (N, C, H, W). Element-wise weights. Default: None. """ return self.loss_weight * charbonnier_loss(pred, target, weight, eps=self.eps, reduction=self.reduction) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import functools from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_mean_mul_pow_sqrt_sub_0(in_out_ptr0, in_ptr0, in_ptr1, xnumel, rnumel): XBLOCK: tl.constexpr = 1 RBLOCK: tl.constexpr = 256 xoffset = tl.program_id(0) * XBLOCK tl.full([1], xoffset, tl.int32) tl.full([RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[:] tl.full([RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr1 + r0, None) tmp2 = tmp0 - tmp1 tmp3 = tmp2 * tmp2 tmp4 = 1e-12 tmp5 = tmp3 + tmp4 tmp6 = libdevice.sqrt(tmp5) tmp7 = tl.broadcast_to(tmp6, [RBLOCK]) tmp9 = triton_helpers.promote_to_tensor(tl.sum(tmp7, 0)) tmp10 = 256.0 tmp11 = tmp9 / tmp10 tmp12 = 1.0 tmp13 = tmp11 * tmp12 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp13, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_mean_mul_pow_sqrt_sub_0[grid(1)](buf1, arg0_1, arg1_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf1, def reduce_loss(loss, reduction): """Reduce loss as specified. Args: loss (Tensor): Elementwise loss tensor. reduction (str): Options are 'none', 'mean' and 'sum'. Returns: Tensor: Reduced loss tensor. """ reduction_enum = F._Reduction.get_enum(reduction) if reduction_enum == 0: return loss elif reduction_enum == 1: return loss.mean() else: return loss.sum() def weight_reduce_loss(loss, weight=None, reduction='mean'): """Apply element-wise weight and reduce loss. Args: loss (Tensor): Element-wise loss. weight (Tensor): Element-wise weights. Default: None. reduction (str): Same as built-in losses of PyTorch. Options are 'none', 'mean' and 'sum'. Default: 'mean'. Returns: Tensor: Loss values. """ if weight is not None: assert weight.dim() == loss.dim() assert weight.size(1) == 1 or weight.size(1) == loss.size(1) loss = loss * weight if weight is None or reduction == 'sum': loss = reduce_loss(loss, reduction) elif reduction == 'mean': if weight.size(1) > 1: weight = weight.sum() else: weight = weight.sum() * loss.size(1) loss = loss.sum() / weight return loss def weighted_loss(loss_func): """Create a weighted version of a given loss function. To use this decorator, the loss function must have the signature like `loss_func(pred, target, **kwargs)`. The function only needs to compute element-wise loss without any reduction. This decorator will add weight and reduction arguments to the function. The decorated function will have the signature like `loss_func(pred, target, weight=None, reduction='mean', **kwargs)`. :Example: >>> import torch >>> @weighted_loss >>> def l1_loss(pred, target): >>> return (pred - target).abs() >>> pred = torch.Tensor([0, 2, 3]) >>> target = torch.Tensor([1, 1, 1]) >>> weight = torch.Tensor([1, 0, 1]) >>> l1_loss(pred, target) tensor(1.3333) >>> l1_loss(pred, target, weight) tensor(1.5000) >>> l1_loss(pred, target, reduction='none') tensor([1., 1., 2.]) >>> l1_loss(pred, target, weight, reduction='sum') tensor(3.) """ @functools.wraps(loss_func) def wrapper(pred, target, weight=None, reduction='mean', **kwargs): loss = loss_func(pred, target, **kwargs) loss = weight_reduce_loss(loss, weight, reduction) return loss return wrapper @weighted_loss def charbonnier_loss(pred, target, eps=1e-12): return torch.sqrt((pred - target) ** 2 + eps) class CharbonnierLossNew(nn.Module): """Charbonnier loss (one variant of Robust L1Loss, a differentiable variant of L1Loss). Described in "Deep Laplacian Pyramid Networks for Fast and Accurate Super-Resolution". Args: loss_weight (float): Loss weight for L1 loss. Default: 1.0. reduction (str): Specifies the reduction to apply to the output. Supported choices are 'none' | 'mean' | 'sum'. Default: 'mean'. eps (float): A value used to control the curvature near zero. Default: 1e-12. """ def __init__(self, loss_weight=1.0, reduction='mean', eps=1e-12): super(CharbonnierLossNew, self).__init__() if reduction not in ['none', 'mean', 'sum']: raise ValueError( f'Unsupported reduction mode: {reduction}. Supported ones are: {_reduction_modes}' ) self.loss_weight = loss_weight self.reduction = reduction self.eps = eps def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

Lotayou/BasicSR

CharbonnierLoss

false

2,576

[ "Apache-2.0", "MIT" ]

0

6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

MHAScoresCalculation

import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class MHAScoresCalculation(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(MHAScoresCalculation, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, mat1, mat2, bias): mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) scores = qk + bias return self.softmax(scores) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 4, 4, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_add_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp12 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = triton_helpers.maximum(tmp2, tmp5) tmp9 = tmp7 + tmp8 tmp10 = triton_helpers.maximum(tmp6, tmp9) tmp13 = tmp11 + tmp12 tmp14 = triton_helpers.maximum(tmp10, tmp13) tmp15 = tmp2 - tmp14 tmp16 = tl_math.exp(tmp15) tmp17 = tmp5 - tmp14 tmp18 = tl_math.exp(tmp17) tmp19 = tmp16 + tmp18 tmp20 = tmp9 - tmp14 tmp21 = tl_math.exp(tmp20) tmp22 = tmp19 + tmp21 tmp23 = tmp13 - tmp14 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tl.store(out_ptr0 + x0, tmp14, xmask) tl.store(out_ptr1 + x0, tmp25, xmask) @triton.jit def triton_poi_fused__softmax_add_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x2, xmask) tmp3 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp5 = tl_math.exp(tmp4) tmp7 = tmp5 / tmp6 tl.store(in_out_ptr0 + x2, tmp7, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_add_1[grid(64)](buf1, arg2_1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_add_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class MHAScoresCalculationNew(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(MHAScoresCalculationNew, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]

JudeDavis1/intel-extension-for-pytorch

MHAScoresCalculation

false

2,577

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

AddLayerNorm_v1

import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AddLayerNorm_v1(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm_v1, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, x, y, z): x = x + y + z return self.layernorm(x) def get_inputs(): return [torch.rand([4, 4, 32, 32]), torch.rand([4, 4, 32, 32]), torch. rand([4, 4, 32, 32])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_native_layer_norm_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, out_ptr2, out_ptr3, xnumel, rnumel, XBLOCK: tl.constexpr ): xnumel = 512 RBLOCK: tl.constexpr = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 32 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 32 * x0), xmask, other=0.0) tmp3 = tl.load(in_ptr2 + (r1 + 32 * x0), xmask, other=0.0) tmp28 = tl.load(in_ptr3 + r1, None, eviction_policy='evict_last') tmp30 = tl.load(in_ptr4 + r1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = tl.broadcast_to(tmp4, [XBLOCK, RBLOCK]) tl.where(xmask, tmp5, 0) tmp8 = tl.broadcast_to(tmp5, [XBLOCK, RBLOCK]) tmp10 = tl.where(xmask, tmp8, 0) tmp11 = tl.sum(tmp10, 1)[:, None] tmp12 = tl.full([XBLOCK, 1], 32, tl.int32) tmp13 = tmp12.to(tl.float32) tmp14 = tmp11 / tmp13 tmp15 = tmp5 - tmp14 tmp16 = tmp15 * tmp15 tmp17 = tl.broadcast_to(tmp16, [XBLOCK, RBLOCK]) tmp19 = tl.where(xmask, tmp17, 0) tmp20 = tl.sum(tmp19, 1)[:, None] tmp21 = tmp4 - tmp14 tmp22 = 32.0 tmp23 = tmp20 / tmp22 tmp24 = 1e-05 tmp25 = tmp23 + tmp24 tmp26 = libdevice.rsqrt(tmp25) tmp27 = tmp21 * tmp26 tmp29 = tmp27 * tmp28 tmp31 = tmp29 + tmp30 tl.store(out_ptr2 + (r1 + 32 * x0), tmp27, xmask) tl.store(out_ptr3 + (r1 + 32 * x0), tmp31, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_2, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_3, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_4, (32,), (1,)) assert_size_stride(primals_5, (32,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf3 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) buf4 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) get_raw_stream(0) triton_per_fused_add_native_layer_norm_0[grid(512)](primals_1, primals_2, primals_3, primals_4, primals_5, buf3, buf4, 512, 32, XBLOCK=32, num_warps=8, num_stages=1) del primals_1 del primals_2 del primals_3 del primals_4 del primals_5 return buf4, buf3 class AddLayerNorm_v1New(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm_v1New, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, input_0, input_1, input_2): primals_4 = self.layernorm.weight primals_5 = self.layernorm.bias primals_1 = input_0 primals_2 = input_1 primals_3 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]

JudeDavis1/intel-extension-for-pytorch

AddLayerNorm_v1

false

2,578

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

DistilMHAScoresCalculation_v2

import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class DistilMHAScoresCalculation_v2(nn.Module): def __init__(self, dim_per_head): super(DistilMHAScoresCalculation_v2, self).__init__() self.dim_per_head = dim_per_head def forward(self, mat1, mat2, mask): mask_shape = [mat1.shape[0], 1, 1, mat1.shape[3]] mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) mask = (mask == 0).view(mask_shape).expand_as(qk) qk = qk.masked_fill(mask, -float('inf')) return nn.functional.softmax(qk, dim=-1) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 1, 1, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_masked_fill_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + 4 * x2, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (1 + 4 * x2), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp13 = tl.load(in_ptr1 + (2 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp18 = tl.load(in_ptr1 + (3 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp6 == tmp1 tmp9 = tl.where(tmp7, tmp4, tmp8) tmp10 = triton_helpers.maximum(tmp5, tmp9) tmp12 = tmp11 == tmp1 tmp14 = tl.where(tmp12, tmp4, tmp13) tmp15 = triton_helpers.maximum(tmp10, tmp14) tmp17 = tmp16 == tmp1 tmp19 = tl.where(tmp17, tmp4, tmp18) tmp20 = triton_helpers.maximum(tmp15, tmp19) tmp21 = tmp5 - tmp20 tmp22 = tl_math.exp(tmp21) tmp23 = tmp9 - tmp20 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tmp26 = tmp14 - tmp20 tmp27 = tl_math.exp(tmp26) tmp28 = tmp25 + tmp27 tmp29 = tmp19 - tmp20 tmp30 = tl_math.exp(tmp29) tmp31 = tmp28 + tmp30 tl.store(out_ptr0 + x2, tmp20, xmask) tl.store(out_ptr1 + x2, tmp31, xmask) @triton.jit def triton_poi_fused__softmax_masked_fill_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex // 64 x3 = xindex x4 = xindex // 4 tmp0 = tl.load(in_ptr0 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_out_ptr0 + x3, xmask) tmp6 = tl.load(in_ptr1 + x4, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp5 - tmp6 tmp8 = tl_math.exp(tmp7) tmp10 = tmp8 / tmp9 tl.store(in_out_ptr0 + x3, tmp10, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 1, 1, 4), (4, 4, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_masked_fill_1[grid(64)](arg2_1, buf1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_masked_fill_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class DistilMHAScoresCalculation_v2New(nn.Module): def __init__(self, dim_per_head): super(DistilMHAScoresCalculation_v2New, self).__init__() self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]

JudeDavis1/intel-extension-for-pytorch

DistilMHAScoresCalculation_v2

false

2,579

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

DistilMHAScoresCalculation_v1

import math import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class DistilMHAScoresCalculation_v1(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(DistilMHAScoresCalculation_v1, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, mat1, mat2, mask): mask_shape = [mat1.shape[0], 1, 1, mat1.shape[3]] mat1 = mat1 / math.sqrt(self.dim_per_head) qk = torch.matmul(mat1, mat2.transpose(2, 3)) mask = (mask == 0).view(mask_shape).expand_as(qk) qk.masked_fill_(mask, -float('inf')) return self.softmax(qk) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [4, 1, 1, 4])] def get_init_inputs(): return [[], {'dim_per_head': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_div_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused__softmax_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + 4 * x2, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr1 + (1 + 4 * x2), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp13 = tl.load(in_ptr1 + (2 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp18 = tl.load(in_ptr1 + (3 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp6 == tmp1 tmp9 = tl.where(tmp7, tmp4, tmp8) tmp10 = triton_helpers.maximum(tmp5, tmp9) tmp12 = tmp11 == tmp1 tmp14 = tl.where(tmp12, tmp4, tmp13) tmp15 = triton_helpers.maximum(tmp10, tmp14) tmp17 = tmp16 == tmp1 tmp19 = tl.where(tmp17, tmp4, tmp18) tmp20 = triton_helpers.maximum(tmp15, tmp19) tmp21 = tmp5 - tmp20 tmp22 = tl_math.exp(tmp21) tmp23 = tmp9 - tmp20 tmp24 = tl_math.exp(tmp23) tmp25 = tmp22 + tmp24 tmp26 = tmp14 - tmp20 tmp27 = tl_math.exp(tmp26) tmp28 = tmp25 + tmp27 tmp29 = tmp19 - tmp20 tmp30 = tl_math.exp(tmp29) tmp31 = tmp28 + tmp30 tl.store(out_ptr0 + x2, tmp20, xmask) tl.store(out_ptr1 + x2, tmp31, xmask) @triton.jit def triton_poi_fused__softmax_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x2 = xindex // 64 x3 = xindex x4 = xindex // 4 tmp0 = tl.load(in_ptr0 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp3 = tl.load(in_out_ptr0 + x3, xmask) tmp6 = tl.load(in_ptr1 + x4, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp1 = 0.0 tmp2 = tmp0 == tmp1 tmp4 = float('-inf') tmp5 = tl.where(tmp2, tmp4, tmp3) tmp7 = tmp5 - tmp6 tmp8 = tl_math.exp(tmp7) tmp10 = tmp8 / tmp9 tl.store(in_out_ptr0 + x3, tmp10, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4, 1, 1, 4), (4, 4, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 buf1 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg1_1, (16, 4, 4), (16, 1, 4), 0), out=buf1 ) del arg1_1 del buf0 buf2 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_1[grid(64)](arg2_1, buf1, buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_2[grid(256)](buf4, arg2_1, buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg2_1 del buf2 del buf3 return buf4, class DistilMHAScoresCalculation_v1New(nn.Module): def __init__(self, dim_per_head, softmax_dim=-1): super(DistilMHAScoresCalculation_v1New, self).__init__() self.softmax = nn.Softmax(dim=softmax_dim) self.dim_per_head = dim_per_head def forward(self, input_0, input_1, input_2): arg0_1 = input_0 arg1_1 = input_1 arg2_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]

JudeDavis1/intel-extension-for-pytorch

DistilMHAScoresCalculation_v1

false

2,580

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

ConvTranspose2d

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class ConvTranspose2d(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, stride=1, padding=0, output_padding=0, groups=1, bias=True, dilation=1): super(ConvTranspose2d, self).__init__() self.conv_transpose2d = nn.ConvTranspose2d(in_channels, out_channels, kernel_size, stride, padding, output_padding, groups, bias, dilation) def forward(self, x): x = self.conv_transpose2d(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4, 'kernel_size': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 784 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 49 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 7, 7), (196, 49, 7, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(784)](buf1, primals_2, 784, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 return buf1, primals_1, primals_3 class ConvTranspose2dNew(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, stride=1, padding=0, output_padding=0, groups=1, bias=True, dilation=1): super(ConvTranspose2dNew, self).__init__() self.conv_transpose2d = nn.ConvTranspose2d(in_channels, out_channels, kernel_size, stride, padding, output_padding, groups, bias, dilation) def forward(self, input_0): primals_1 = self.conv_transpose2d.weight primals_2 = self.conv_transpose2d.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

JudeDavis1/intel-extension-for-pytorch

ConvTranspose2d

false

2,581

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

LinearAdd

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class LinearAdd(nn.Module): def __init__(self, in_channels, out_channels, **kwargs): super(LinearAdd, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, **kwargs) self.linear1 = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, x): x1 = x.clone() return torch.add(self.linear(x), self.linear1(x1)) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_0(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp4 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tl.store(in_out_ptr0 + x2, tmp6, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf0) del primals_2 buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_0[grid(256)](buf2, primals_3, buf1, primals_5, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf1 del primals_3 del primals_5 return buf2, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0) class LinearAddNew(nn.Module): def __init__(self, in_channels, out_channels, **kwargs): super(LinearAddNew, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, **kwargs) self.linear1 = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, input_0): primals_2 = self.linear.weight primals_3 = self.linear.bias primals_4 = self.linear1.weight primals_5 = self.linear1.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]

JudeDavis1/intel-extension-for-pytorch

LinearAdd

false

2,582

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

hsigmoid

import torch import torch.onnx import torch import torch.nn as nn import torch.nn.functional as F class hsigmoid(nn.Module): def forward(self, x): out = F.relu6(x + 3, inplace=True) / 6 return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.onnx import torch import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_div_hardtanh_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 3.0 tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = triton_helpers.maximum(tmp2, tmp3) tmp5 = 6.0 tmp6 = triton_helpers.minimum(tmp4, tmp5) tmp7 = 0.16666666666666666 tmp8 = tmp6 * tmp7 tl.store(out_ptr0 + x0, tmp8, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_div_hardtanh_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class hsigmoidNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

LukasKratochvila/pytorch-ssd

hsigmoid

false

2,583

[ "MIT" ]

0

de6ed2be6ce0b03634d4cbf41622cfe5c87d077c

https://github.com/LukasKratochvila/pytorch-ssd/tree/de6ed2be6ce0b03634d4cbf41622cfe5c87d077c

LinearSwish

import torch import torch.nn as nn import torch.cuda import torch.nn.functional as F import torch.backends.cudnn import torch.backends.mkl class LinearSwish(nn.Module): def __init__(self, in_channels, out_channels, **kwargs): super(LinearSwish, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, x): linear_res = self.linear(x) return F.silu(linear_res) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_silu_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf0) del primals_1 del primals_2 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_silu_0[grid(256)](buf0, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) return buf1, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), buf0 class LinearSwishNew(nn.Module): def __init__(self, in_channels, out_channels, **kwargs): super(LinearSwishNew, self).__init__() seed = 2018 torch.manual_seed(seed) self.linear = nn.Linear(in_channels, out_channels, **kwargs) def forward(self, input_0): primals_1 = self.linear.weight primals_2 = self.linear.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

JudeDavis1/intel-extension-for-pytorch

LinearSwish

false

2,584

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

EqualLinear

from torch.autograd import Function import math import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None | str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch.autograd import Function import math from torch import nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4,), (1,)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(16)](primals_2, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_2 buf1 = empty_strided_cuda((4,), (1,), torch.float32) triton_poi_fused_mul_1[grid(4)](primals_1, buf1, 4, XBLOCK=4, num_warps=1, num_stages=1) del primals_1 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(buf1, reinterpret_tensor(primals_3, (64, 4), ( 4, 1), 0), reinterpret_tensor(buf0, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del buf0 del buf1 return reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0) def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinearNew(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None | str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinearNew, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) def forward(self, input_0): primals_2 = self.weight primals_1 = self.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

Lotayou/BasicSR

EqualLinear

false

2,585

[ "Apache-2.0", "MIT" ]

0

6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

AddLayerNorm

import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class AddLayerNorm(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNorm, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, x, y): x = torch.add(x, y) return self.layernorm(x) def get_inputs(): return [torch.rand([4, 4, 32, 32]), torch.rand([4, 4, 32, 32])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime.triton_helpers import libdevice import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_add_native_layer_norm_0(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr2, out_ptr3, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 512 RBLOCK: tl.constexpr = 32 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 32 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 32 * x0), xmask, other=0.0) tmp26 = tl.load(in_ptr2 + r1, None, eviction_policy='evict_last') tmp28 = tl.load(in_ptr3 + r1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tl.where(xmask, tmp3, 0) tmp6 = tl.broadcast_to(tmp3, [XBLOCK, RBLOCK]) tmp8 = tl.where(xmask, tmp6, 0) tmp9 = tl.sum(tmp8, 1)[:, None] tmp10 = tl.full([XBLOCK, 1], 32, tl.int32) tmp11 = tmp10.to(tl.float32) tmp12 = tmp9 / tmp11 tmp13 = tmp3 - tmp12 tmp14 = tmp13 * tmp13 tmp15 = tl.broadcast_to(tmp14, [XBLOCK, RBLOCK]) tmp17 = tl.where(xmask, tmp15, 0) tmp18 = tl.sum(tmp17, 1)[:, None] tmp19 = tmp2 - tmp12 tmp20 = 32.0 tmp21 = tmp18 / tmp20 tmp22 = 1e-05 tmp23 = tmp21 + tmp22 tmp24 = libdevice.rsqrt(tmp23) tmp25 = tmp19 * tmp24 tmp27 = tmp25 * tmp26 tmp29 = tmp27 + tmp28 tl.store(out_ptr2 + (r1 + 32 * x0), tmp25, xmask) tl.store(out_ptr3 + (r1 + 32 * x0), tmp29, xmask) def call(args): primals_1, primals_2, primals_3, primals_4 = args args.clear() assert_size_stride(primals_1, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_2, (4, 4, 32, 32), (4096, 1024, 32, 1)) assert_size_stride(primals_3, (32,), (1,)) assert_size_stride(primals_4, (32,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf3 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) buf4 = empty_strided_cuda((4, 4, 32, 32), (4096, 1024, 32, 1), torch.float32) get_raw_stream(0) triton_per_fused_add_native_layer_norm_0[grid(512)](primals_2, primals_1, primals_3, primals_4, buf3, buf4, 512, 32, XBLOCK=8, num_warps=2, num_stages=1) del primals_1 del primals_2 del primals_3 del primals_4 return buf4, buf3 class AddLayerNormNew(torch.nn.Module): def __init__(self, dim=32): super(AddLayerNormNew, self).__init__() self.layernorm = torch.nn.LayerNorm(dim) def forward(self, input_0, input_1): primals_3 = self.layernorm.weight primals_4 = self.layernorm.bias primals_1 = input_0 primals_2 = input_1 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]

JudeDavis1/intel-extension-for-pytorch

AddLayerNorm

false

2,586

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

Module

from torch.nn import Module import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Module(torch.nn.Module): def __init__(self): super(Module, self).__init__() self.conv = torch.nn.Conv2d(1, 10, 5, 1) def forward(self, x): y = self.conv(x) return y def get_inputs(): return [torch.rand([4, 1, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 144000 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 3600 % 10 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (10, 1, 5, 5), (25, 25, 5, 1)) assert_size_stride(primals_2, (10,), (1,)) assert_size_stride(primals_3, (4, 1, 64, 64), (4096, 4096, 64, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 10, 60, 60), (36000, 3600, 60, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(144000)](buf1, primals_2, 144000, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 return buf1, primals_1, primals_3 class ModuleNew(torch.nn.Module): def __init__(self): super(ModuleNew, self).__init__() self.conv = torch.nn.Conv2d(1, 10, 5, 1) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]

JudeDavis1/intel-extension-for-pytorch

Module

false

2,587

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

Bottleneck_v1

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Bottleneck_v1(nn.Module): def __init__(self): super(Bottleneck_v1, self).__init__() self.conv1 = nn.Conv2d(64, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.downsample = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, x): y1 = self.conv1(x).relu_() y2 = self.conv2(y1).relu_() y3 = self.conv3(y2) y3 += self.downsample(x) return y3.relu_() def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_relu_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 64 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, None) @triton.jit def triton_poi_fused_add_convolution_relu_3(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl. constexpr): xnumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 4096 y1 = yindex // 4096 tmp0 = tl.load(in_ptr0 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr3 + x2, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp7 = tl.full([1, 1], 0, tl.int32) tmp8 = triton_helpers.maximum(tmp7, tmp6) tl.store(out_ptr0 + (y0 + 4096 * x2 + 1048576 * y1), tmp8, xmask) @triton.jit def triton_poi_fused_threshold_backward_4(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 256 y1 = yindex // 256 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), None, eviction_policy= 'evict_last') tmp1 = 0.0 tmp2 = tmp0 <= tmp1 tl.store(out_ptr0 + (y0 + 256 * x2 + 1048576 * y1), tmp2, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (64, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_2, (64,), (1,)) assert_size_stride(primals_3, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_4, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) assert_size_stride(primals_6, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_9, (256,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) get_raw_stream(0) triton_poi_fused_0[grid(256, 4096)](primals_3, buf0, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_3 buf1 = empty_strided_cuda((64, 64, 3, 3), (576, 1, 192, 64), torch. float32) triton_poi_fused_1[grid(4096, 9)](primals_4, buf1, 4096, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_4 buf2 = extern_kernels.convolution(buf0, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf3 = buf2 del buf2 triton_poi_fused_convolution_relu_2[grid(1048576)](buf3, primals_2, 1048576, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf4 = extern_kernels.convolution(buf3, buf1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_2[grid(1048576)](buf5, primals_5, 1048576, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf6 = extern_kernels.convolution(buf5, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf7 = extern_kernels.convolution(buf0, primals_8, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf7, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf8 = empty_strided_cuda((4, 256, 64, 64), (1048576, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_relu_3[grid(16384, 256)](buf6, primals_7, buf7, primals_9, buf8, 16384, 256, XBLOCK=32, YBLOCK =32, num_warps=4, num_stages=1) del buf6 del buf7 del primals_7 del primals_9 buf9 = empty_strided_cuda((4, 256, 64, 64), (1048576, 1, 16384, 256 ), torch.bool) triton_poi_fused_threshold_backward_4[grid(1024, 4096)](buf8, buf9, 1024, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) return buf8, primals_1, buf0, buf1, primals_6, primals_8, buf3, buf5, buf9 class Bottleneck_v1New(nn.Module): def __init__(self): super(Bottleneck_v1New, self).__init__() self.conv1 = nn.Conv2d(64, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.downsample = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, input_0): primals_1 = self.conv1.weight primals_2 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_6 = self.conv3.weight primals_7 = self.conv3.bias primals_8 = self.downsample.weight primals_9 = self.downsample.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]

JudeDavis1/intel-extension-for-pytorch

Bottleneck_v1

false

2,588

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

DivLoss

import torch from torch import nn from torch.optim.lr_scheduler import * class DivLoss(nn.Module): def __init__(self): super(DivLoss, self).__init__() def forward(self, scores): mu = scores.mean(0) std = ((scores - mu) ** 2).mean(0, keepdim=True).clamp(min=1e-12).sqrt( ) loss_std = -std.sum() return loss_std def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice from torch import nn from torch.optim.lr_scheduler import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_clamp_mean_neg_pow_sqrt_sub_sum_0(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr0 + (64 + r0), None) tmp3 = tl.load(in_ptr0 + (128 + r0), None) tmp5 = tl.load(in_ptr0 + (192 + r0), None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tmp9 = tmp0 - tmp8 tmp10 = tmp9 * tmp9 tmp11 = tmp1 - tmp8 tmp12 = tmp11 * tmp11 tmp13 = tmp10 + tmp12 tmp14 = tmp3 - tmp8 tmp15 = tmp14 * tmp14 tmp16 = tmp13 + tmp15 tmp17 = tmp5 - tmp8 tmp18 = tmp17 * tmp17 tmp19 = tmp16 + tmp18 tmp20 = tmp19 / tmp7 tmp21 = 1e-12 tmp22 = triton_helpers.maximum(tmp20, tmp21) tmp23 = libdevice.sqrt(tmp22) tmp24 = tl.broadcast_to(tmp23, [XBLOCK, RBLOCK]) tmp26 = tl.sum(tmp24, 1)[:, None] tmp27 = -tmp26 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp27, None) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_clamp_mean_neg_pow_sqrt_sub_sum_0[grid(1)](buf1, arg0_1, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 return buf1, class DivLossNew(nn.Module): def __init__(self): super(DivLossNew, self).__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

Luxios22/IDM

DivLoss

false

2,589

[ "MIT" ]

0

8d51103b7c252e6304e2a361976e16ed4b523944

https://github.com/Luxios22/IDM/tree/8d51103b7c252e6304e2a361976e16ed4b523944

SimpleNet

import torch import torch.cuda import torch.backends.cudnn import torch.backends.mkl class SimpleNet(torch.nn.Module): def __init__(self): super(SimpleNet, self).__init__() self.conv = torch.nn.Conv2d(64, 128, (3, 3), stride=(2, 2), padding =(1, 1), bias=False) def forward(self, x): x1 = self.conv(x) y = torch.flatten(x1, start_dim=1) return y def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_view_2(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x0 = xindex % 131072 x1 = xindex // 131072 x2 = xindex tmp0 = tl.load(in_ptr0 + (128 * (x0 % 1024) + 131072 * x1 + x0 // 1024), None, eviction_policy='evict_last') tl.store(out_ptr0 + x2, tmp0, None) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (128, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_2, (4, 64, 64, 64), (262144, 4096, 64, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((128, 64, 3, 3), (576, 1, 192, 64), torch .float32) get_raw_stream(0) triton_poi_fused_0[grid(8192, 9)](primals_1, buf0, 8192, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_1 buf1 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) triton_poi_fused_1[grid(256, 4096)](primals_2, buf1, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, buf0, stride=(2, 2), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 128, 32, 32), (131072, 1, 4096, 128)) buf3 = empty_strided_cuda((4, 131072), (131072, 1), torch.float32) triton_poi_fused_view_2[grid(524288)](buf2, buf3, 524288, XBLOCK= 1024, num_warps=4, num_stages=1) del buf2 return buf3, buf0, buf1 class SimpleNetNew(torch.nn.Module): def __init__(self): super(SimpleNetNew, self).__init__() self.conv = torch.nn.Conv2d(64, 128, (3, 3), stride=(2, 2), padding =(1, 1), bias=False) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]

JudeDavis1/intel-extension-for-pytorch

SimpleNet

false

2,590

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

Swish

import torch import torch.nn import torch.nn as nn class Swish(nn.Module): """Applies the element-wise function: .. math:: \\text{Swish}(x) = x * \\text{Sigmoid}(\\alpha * x) for constant value alpha. Citation: Searching for Activation Functions, Ramachandran et al., 2017, https://arxiv.org/abs/1710.05941. Shape: - Input: :math:`(N, *)` where `*` means, any number of additional dimensions - Output: :math:`(N, *)`, same shape as the input Examples:: >>> m = Act['swish']() >>> input = torch.randn(2) >>> output = m(input) """ def __init__(self, alpha=1.0): super().__init__() self.alpha = alpha def forward(self, input: 'torch.Tensor') ->torch.Tensor: return input * torch.sigmoid(self.alpha * input) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_mul_sigmoid_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tmp3 = tl.sigmoid(tmp2) tmp4 = tmp0 * tmp3 tl.store(out_ptr0 + x0, tmp4, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_sigmoid_0[grid(256)](arg0_1, buf0, 256, XBLOCK =256, num_warps=4, num_stages=1) del arg0_1 return buf0, class SwishNew(nn.Module): """Applies the element-wise function: .. math:: \\text{Swish}(x) = x * \\text{Sigmoid}(\\alpha * x) for constant value alpha. Citation: Searching for Activation Functions, Ramachandran et al., 2017, https://arxiv.org/abs/1710.05941. Shape: - Input: :math:`(N, *)` where `*` means, any number of additional dimensions - Output: :math:`(N, *)`, same shape as the input Examples:: >>> m = Act['swish']() >>> input = torch.randn(2) >>> output = m(input) """ def __init__(self, alpha=1.0): super().__init__() self.alpha = alpha def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

LucasFidon/MONAI

Swish

false

2,591

[ "Apache-2.0" ]

0

a7ef9d567775dd7a222f93bab08191c0e3532c92

https://github.com/LucasFidon/MONAI/tree/a7ef9d567775dd7a222f93bab08191c0e3532c92

DiceLoss

import collections import torch import warnings from typing import Optional from typing import Union from typing import Any from typing import Callable from typing import Tuple import torch.nn from torch.nn.modules.loss import _Loss from enum import Enum import collections.abc def issequenceiterable(obj: 'Any') ->bool: """ Determine if the object is an iterable sequence and is not a string. """ if torch.is_tensor(obj): return int(obj.dim()) > 0 return isinstance(obj, collections.abc.Iterable) and not isinstance(obj, str) def ensure_tuple(vals: 'Any') ->Tuple[Any, ...]: """ Returns a tuple of `vals`. """ if not issequenceiterable(vals): vals = vals, return tuple(vals) def ensure_tuple_size(tup: 'Any', dim: 'int', pad_val: 'Any'=0) ->Tuple[Any, ...]: """ Returns a copy of `tup` with `dim` values by either shortened or padded with `pad_val` as necessary. """ tup = ensure_tuple(tup) + (pad_val,) * dim return tuple(tup[:dim]) def one_hot(labels: 'torch.Tensor', num_classes: 'int', dtype: 'torch.dtype'=torch.float, dim: 'int'=1) ->torch.Tensor: """ For a tensor `labels` of dimensions B1[spatial_dims], return a tensor of dimensions `BN[spatial_dims]` for `num_classes` N number of classes. Example: For every value v = labels[b,1,h,w], the value in the result at [b,v,h,w] will be 1 and all others 0. Note that this will include the background label, thus a binary mask should be treated as having 2 classes. """ assert labels.dim() > 0, 'labels should have dim of 1 or more.' if labels.ndim < dim + 1: shape = ensure_tuple_size(labels.shape, dim + 1, 1) labels = labels.reshape(*shape) sh = list(labels.shape) assert sh[dim ] == 1, 'labels should have a channel with length equals to one.' sh[dim] = num_classes o = torch.zeros(size=sh, dtype=dtype, device=labels.device) labels = o.scatter_(dim=dim, index=labels.long(), value=1) return labels class LossReduction(Enum): """ See also: - :py:class:`monai.losses.dice.DiceLoss` - :py:class:`monai.losses.dice.GeneralizedDiceLoss` - :py:class:`monai.losses.focal_loss.FocalLoss` - :py:class:`monai.losses.tversky.TverskyLoss` """ NONE = 'none' MEAN = 'mean' SUM = 'sum' class DiceLoss(_Loss): """ Compute average Dice loss between two tensors. It can support both multi-classes and multi-labels tasks. Input logits `input` (BNHW[D] where N is number of classes) is compared with ground truth `target` (BNHW[D]). Axis N of `input` is expected to have logit predictions for each class rather than being image channels, while the same axis of `target` can be 1 or N (one-hot format). The `smooth_nr` and `smooth_dr` parameters are values added to the intersection and union components of the inter-over-union calculation to smooth results respectively, these values should be small. The `include_background` class attribute can be set to False for an instance of DiceLoss to exclude the first category (channel index 0) which is by convention assumed to be background. If the non-background segmentations are small compared to the total image size they can get overwhelmed by the signal from the background so excluding it in such cases helps convergence. Milletari, F. et. al. (2016) V-Net: Fully Convolutional Neural Networks forVolumetric Medical Image Segmentation, 3DV, 2016. """ def __init__(self, include_background: 'bool'=True, to_onehot_y: 'bool' =False, sigmoid: 'bool'=False, softmax: 'bool'=False, other_act: 'Optional[Callable]'=None, squared_pred: 'bool'=False, jaccard: 'bool'=False, reduction: 'Union[LossReduction, str]'=LossReduction. MEAN, smooth_nr: 'float'=1e-05, smooth_dr: 'float'=1e-05, batch: 'bool'=False) ->None: """ Args: include_background: if False channel index 0 (background category) is excluded from the calculation. to_onehot_y: whether to convert `y` into the one-hot format. Defaults to False. sigmoid: if True, apply a sigmoid function to the prediction. softmax: if True, apply a softmax function to the prediction. other_act: if don't want to use `sigmoid` or `softmax`, use other callable function to execute other activation layers, Defaults to ``None``. for example: `other_act = torch.tanh`. squared_pred: use squared versions of targets and predictions in the denominator or not. jaccard: compute Jaccard Index (soft IoU) instead of dice or not. reduction: {``"none"``, ``"mean"``, ``"sum"``} Specifies the reduction to apply to the output. Defaults to ``"mean"``. - ``"none"``: no reduction will be applied. - ``"mean"``: the sum of the output will be divided by the number of elements in the output. - ``"sum"``: the output will be summed. smooth_nr: a small constant added to the numerator to avoid zero. smooth_dr: a small constant added to the denominator to avoid nan. batch: whether to sum the intersection and union areas over the batch dimension before the dividing. Defaults to False, a Dice loss value is computed independently from each item in the batch before any `reduction`. Raises: TypeError: When ``other_act`` is not an ``Optional[Callable]``. ValueError: When more than 1 of [``sigmoid=True``, ``softmax=True``, ``other_act is not None``]. Incompatible values. """ super().__init__(reduction=LossReduction(reduction).value) if other_act is not None and not callable(other_act): raise TypeError( f'other_act must be None or callable but is {type(other_act).__name__}.' ) if int(sigmoid) + int(softmax) + int(other_act is not None) > 1: raise ValueError( 'Incompatible values: more than 1 of [sigmoid=True, softmax=True, other_act is not None].' ) self.include_background = include_background self.to_onehot_y = to_onehot_y self.sigmoid = sigmoid self.softmax = softmax self.other_act = other_act self.squared_pred = squared_pred self.jaccard = jaccard self.smooth_nr = float(smooth_nr) self.smooth_dr = float(smooth_dr) self.batch = batch def forward(self, input: 'torch.Tensor', target: 'torch.Tensor' ) ->torch.Tensor: """ Args: input: the shape should be BNH[WD]. target: the shape should be BNH[WD]. Raises: ValueError: When ``self.reduction`` is not one of ["mean", "sum", "none"]. """ if self.sigmoid: input = torch.sigmoid(input) n_pred_ch = input.shape[1] if self.softmax: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `softmax=True` ignored.') else: input = torch.softmax(input, 1) if self.other_act is not None: input = self.other_act(input) if self.to_onehot_y: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `to_onehot_y=True` ignored.') else: target = one_hot(target, num_classes=n_pred_ch) if not self.include_background: if n_pred_ch == 1: warnings.warn( 'single channel prediction, `include_background=False` ignored.' ) else: target = target[:, 1:] input = input[:, 1:] assert target.shape == input.shape, f'ground truth has differing shape ({target.shape}) from input ({input.shape})' reduce_axis = list(range(2, len(input.shape))) if self.batch: reduce_axis = [0] + reduce_axis intersection = torch.sum(target * input, dim=reduce_axis) if self.squared_pred: target = torch.pow(target, 2) input = torch.pow(input, 2) ground_o = torch.sum(target, dim=reduce_axis) pred_o = torch.sum(input, dim=reduce_axis) denominator = ground_o + pred_o if self.jaccard: denominator = 2.0 * (denominator - intersection) f: 'torch.Tensor' = 1.0 - (2.0 * intersection + self.smooth_nr) / ( denominator + self.smooth_dr) if self.reduction == LossReduction.MEAN.value: f = torch.mean(f) elif self.reduction == LossReduction.SUM.value: f = torch.sum(f) elif self.reduction == LossReduction.NONE.value: pass else: raise ValueError( f'Unsupported reduction: {self.reduction}, available options are ["mean", "sum", "none"].' ) return f def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import collections from typing import Optional from typing import Union from typing import Any from typing import Callable from typing import Tuple import torch.nn from torch.nn.modules.loss import _Loss from enum import Enum import collections.abc assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_per_fused_mul_sum_0(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 16 RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 16 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 16 * x0), xmask, other=0.0) tmp2 = tmp0 * tmp1 tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp5 = tl.where(xmask, tmp3, 0) tmp6 = tl.sum(tmp5, 1)[:, None] tmp7 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp9 = tl.where(xmask, tmp7, 0) tmp10 = tl.sum(tmp9, 1)[:, None] tmp11 = tl.broadcast_to(tmp1, [XBLOCK, RBLOCK]) tmp13 = tl.where(xmask, tmp11, 0) tmp14 = tl.sum(tmp13, 1)[:, None] tl.store(out_ptr0 + x0, tmp6, xmask) tl.store(out_ptr1 + x0, tmp10, xmask) tl.store(out_ptr2 + x0, tmp14, xmask) @triton.jit def triton_per_fused_add_div_mean_mul_rsub_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 16 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp5 = tl.load(in_ptr1 + r0, None) tmp6 = tl.load(in_ptr2 + r0, None) tmp1 = 2.0 tmp2 = tmp0 * tmp1 tmp3 = 1e-05 tmp4 = tmp2 + tmp3 tmp7 = tmp5 + tmp6 tmp8 = tmp7 + tmp3 tmp9 = tmp4 / tmp8 tmp10 = 1.0 tmp11 = tmp10 - tmp9 tmp12 = tl.broadcast_to(tmp11, [XBLOCK, RBLOCK]) tmp14 = tl.sum(tmp12, 1)[:, None] tmp15 = 16.0 tmp16 = tmp14 / tmp15 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp16, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_per_fused_mul_sum_0[grid(16)](arg1_1, arg0_1, buf0, buf1, buf2, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 del arg1_1 buf3 = empty_strided_cuda((), (), torch.float32) buf4 = buf3 del buf3 triton_per_fused_add_div_mean_mul_rsub_1[grid(1)](buf4, buf0, buf1, buf2, 1, 16, XBLOCK=1, num_warps=2, num_stages=1) del buf0 del buf1 del buf2 return buf4, def issequenceiterable(obj: 'Any') ->bool: """ Determine if the object is an iterable sequence and is not a string. """ if torch.is_tensor(obj): return int(obj.dim()) > 0 return isinstance(obj, collections.abc.Iterable) and not isinstance(obj, str) def ensure_tuple(vals: 'Any') ->Tuple[Any, ...]: """ Returns a tuple of `vals`. """ if not issequenceiterable(vals): vals = vals, return tuple(vals) def ensure_tuple_size(tup: 'Any', dim: 'int', pad_val: 'Any'=0) ->Tuple[Any, ...]: """ Returns a copy of `tup` with `dim` values by either shortened or padded with `pad_val` as necessary. """ tup = ensure_tuple(tup) + (pad_val,) * dim return tuple(tup[:dim]) def one_hot(labels: 'torch.Tensor', num_classes: 'int', dtype: 'torch.dtype'=torch.float, dim: 'int'=1) ->torch.Tensor: """ For a tensor `labels` of dimensions B1[spatial_dims], return a tensor of dimensions `BN[spatial_dims]` for `num_classes` N number of classes. Example: For every value v = labels[b,1,h,w], the value in the result at [b,v,h,w] will be 1 and all others 0. Note that this will include the background label, thus a binary mask should be treated as having 2 classes. """ assert labels.dim() > 0, 'labels should have dim of 1 or more.' if labels.ndim < dim + 1: shape = ensure_tuple_size(labels.shape, dim + 1, 1) labels = labels.reshape(*shape) sh = list(labels.shape) assert sh[dim ] == 1, 'labels should have a channel with length equals to one.' sh[dim] = num_classes o = torch.zeros(size=sh, dtype=dtype, device=labels.device) labels = o.scatter_(dim=dim, index=labels.long(), value=1) return labels class LossReduction(Enum): """ See also: - :py:class:`monai.losses.dice.DiceLoss` - :py:class:`monai.losses.dice.GeneralizedDiceLoss` - :py:class:`monai.losses.focal_loss.FocalLoss` - :py:class:`monai.losses.tversky.TverskyLoss` """ NONE = 'none' MEAN = 'mean' SUM = 'sum' class DiceLossNew(_Loss): """ Compute average Dice loss between two tensors. It can support both multi-classes and multi-labels tasks. Input logits `input` (BNHW[D] where N is number of classes) is compared with ground truth `target` (BNHW[D]). Axis N of `input` is expected to have logit predictions for each class rather than being image channels, while the same axis of `target` can be 1 or N (one-hot format). The `smooth_nr` and `smooth_dr` parameters are values added to the intersection and union components of the inter-over-union calculation to smooth results respectively, these values should be small. The `include_background` class attribute can be set to False for an instance of DiceLoss to exclude the first category (channel index 0) which is by convention assumed to be background. If the non-background segmentations are small compared to the total image size they can get overwhelmed by the signal from the background so excluding it in such cases helps convergence. Milletari, F. et. al. (2016) V-Net: Fully Convolutional Neural Networks forVolumetric Medical Image Segmentation, 3DV, 2016. """ def __init__(self, include_background: 'bool'=True, to_onehot_y: 'bool' =False, sigmoid: 'bool'=False, softmax: 'bool'=False, other_act: 'Optional[Callable]'=None, squared_pred: 'bool'=False, jaccard: 'bool'=False, reduction: 'Union[LossReduction, str]'=LossReduction. MEAN, smooth_nr: 'float'=1e-05, smooth_dr: 'float'=1e-05, batch: 'bool'=False) ->None: """ Args: include_background: if False channel index 0 (background category) is excluded from the calculation. to_onehot_y: whether to convert `y` into the one-hot format. Defaults to False. sigmoid: if True, apply a sigmoid function to the prediction. softmax: if True, apply a softmax function to the prediction. other_act: if don't want to use `sigmoid` or `softmax`, use other callable function to execute other activation layers, Defaults to ``None``. for example: `other_act = torch.tanh`. squared_pred: use squared versions of targets and predictions in the denominator or not. jaccard: compute Jaccard Index (soft IoU) instead of dice or not. reduction: {``"none"``, ``"mean"``, ``"sum"``} Specifies the reduction to apply to the output. Defaults to ``"mean"``. - ``"none"``: no reduction will be applied. - ``"mean"``: the sum of the output will be divided by the number of elements in the output. - ``"sum"``: the output will be summed. smooth_nr: a small constant added to the numerator to avoid zero. smooth_dr: a small constant added to the denominator to avoid nan. batch: whether to sum the intersection and union areas over the batch dimension before the dividing. Defaults to False, a Dice loss value is computed independently from each item in the batch before any `reduction`. Raises: TypeError: When ``other_act`` is not an ``Optional[Callable]``. ValueError: When more than 1 of [``sigmoid=True``, ``softmax=True``, ``other_act is not None``]. Incompatible values. """ super().__init__(reduction=LossReduction(reduction).value) if other_act is not None and not callable(other_act): raise TypeError( f'other_act must be None or callable but is {type(other_act).__name__}.' ) if int(sigmoid) + int(softmax) + int(other_act is not None) > 1: raise ValueError( 'Incompatible values: more than 1 of [sigmoid=True, softmax=True, other_act is not None].' ) self.include_background = include_background self.to_onehot_y = to_onehot_y self.sigmoid = sigmoid self.softmax = softmax self.other_act = other_act self.squared_pred = squared_pred self.jaccard = jaccard self.smooth_nr = float(smooth_nr) self.smooth_dr = float(smooth_dr) self.batch = batch def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

LucasFidon/MONAI

DiceLoss

false

2,592

[ "Apache-2.0" ]

0

a7ef9d567775dd7a222f93bab08191c0e3532c92

https://github.com/LucasFidon/MONAI/tree/a7ef9d567775dd7a222f93bab08191c0e3532c92

softmax_with_multiuse_input

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class softmax_with_multiuse_input(torch.nn.Module): def __init__(self): super().__init__() def forward(self, x): x1 = nn.Softmax(dim=-1)(x) x2 = x + x1 return x1, x2 def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x2, tmp9, xmask) @triton.jit def triton_poi_fused__softmax_add_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr1 + x2, xmask) tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tmp10 = tmp9 + tmp8 tl.store(out_ptr0 + x2, tmp8, xmask) tl.store(out_ptr1 + x2, tmp10, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg0_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_add_1[grid(256)](buf0, arg0_1, buf1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 del buf0 return buf1, buf2 class softmax_with_multiuse_inputNew(torch.nn.Module): def __init__(self): super().__init__() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0], output[1]

JudeDavis1/intel-extension-for-pytorch

softmax_with_multiuse_input

false

2,593

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

ToRGB

from torch.autograd import Function import math import torch from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd def make_resample_kernel(k): """Make resampling kernel for UpFirDn. Args: k (list[int]): A list indicating the 1D resample kernel magnitude. Returns: Tensor: 2D resampled kernel. """ k = torch.tensor(k, dtype=torch.float32) if k.ndim == 1: k = k[None, :] * k[:, None] k /= k.sum() return k def upfirdn2d_native(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1): _, channel, in_h, in_w = input.shape input = input.reshape(-1, in_h, in_w, 1) _, in_h, in_w, minor = input.shape kernel_h, kernel_w = kernel.shape out = input.view(-1, in_h, 1, in_w, 1, minor) out = F.pad(out, [0, 0, 0, up_x - 1, 0, 0, 0, up_y - 1]) out = out.view(-1, in_h * up_y, in_w * up_x, minor) out = F.pad(out, [0, 0, max(pad_x0, 0), max(pad_x1, 0), max(pad_y0, 0), max(pad_y1, 0)]) out = out[:, max(-pad_y0, 0):out.shape[1] - max(-pad_y1, 0), max(- pad_x0, 0):out.shape[2] - max(-pad_x1, 0), :] out = out.permute(0, 3, 1, 2) out = out.reshape([-1, 1, in_h * up_y + pad_y0 + pad_y1, in_w * up_x + pad_x0 + pad_x1]) w = torch.flip(kernel, [0, 1]).view(1, 1, kernel_h, kernel_w) out = F.conv2d(out, w) out = out.reshape(-1, minor, in_h * up_y + pad_y0 + pad_y1 - kernel_h + 1, in_w * up_x + pad_x0 + pad_x1 - kernel_w + 1) out = out.permute(0, 2, 3, 1) out = out[:, ::down_y, ::down_x, :] out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 return out.view(-1, channel, out_h, out_w) def upfirdn2d(input, kernel, up=1, down=1, pad=(0, 0)): if input.device.type == 'cpu': out = upfirdn2d_native(input, kernel, up, up, down, down, pad[0], pad[1], pad[0], pad[1]) else: out = UpFirDn2d.apply(input, kernel, (up, up), (down, down), (pad[0 ], pad[1], pad[0], pad[1])) return out def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class UpFirDn2dBackward(Function): @staticmethod def forward(ctx, grad_output, kernel, grad_kernel, up, down, pad, g_pad, in_size, out_size): up_x, up_y = up down_x, down_y = down g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 = g_pad grad_output = grad_output.reshape(-1, out_size[0], out_size[1], 1) grad_input = upfirdn2d_ext.upfirdn2d(grad_output, grad_kernel, down_x, down_y, up_x, up_y, g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1) grad_input = grad_input.view(in_size[0], in_size[1], in_size[2], in_size[3]) ctx.save_for_backward(kernel) pad_x0, pad_x1, pad_y0, pad_y1 = pad ctx.up_x = up_x ctx.up_y = up_y ctx.down_x = down_x ctx.down_y = down_y ctx.pad_x0 = pad_x0 ctx.pad_x1 = pad_x1 ctx.pad_y0 = pad_y0 ctx.pad_y1 = pad_y1 ctx.in_size = in_size ctx.out_size = out_size return grad_input @staticmethod def backward(ctx, gradgrad_input): kernel, = ctx.saved_tensors gradgrad_input = gradgrad_input.reshape(-1, ctx.in_size[2], ctx. in_size[3], 1) gradgrad_out = upfirdn2d_ext.upfirdn2d(gradgrad_input, kernel, ctx. up_x, ctx.up_y, ctx.down_x, ctx.down_y, ctx.pad_x0, ctx.pad_x1, ctx.pad_y0, ctx.pad_y1) gradgrad_out = gradgrad_out.view(ctx.in_size[0], ctx.in_size[1], ctx.out_size[0], ctx.out_size[1]) return gradgrad_out, None, None, None, None, None, None, None, None class UpFirDn2d(Function): @staticmethod def forward(ctx, input, kernel, up, down, pad): up_x, up_y = up down_x, down_y = down pad_x0, pad_x1, pad_y0, pad_y1 = pad kernel_h, kernel_w = kernel.shape _batch, channel, in_h, in_w = input.shape ctx.in_size = input.shape input = input.reshape(-1, in_h, in_w, 1) ctx.save_for_backward(kernel, torch.flip(kernel, [0, 1])) out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 ctx.out_size = out_h, out_w ctx.up = up_x, up_y ctx.down = down_x, down_y ctx.pad = pad_x0, pad_x1, pad_y0, pad_y1 g_pad_x0 = kernel_w - pad_x0 - 1 g_pad_y0 = kernel_h - pad_y0 - 1 g_pad_x1 = in_w * up_x - out_w * down_x + pad_x0 - up_x + 1 g_pad_y1 = in_h * up_y - out_h * down_y + pad_y0 - up_y + 1 ctx.g_pad = g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 out = upfirdn2d_ext.upfirdn2d(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1) out = out.view(-1, channel, out_h, out_w) return out @staticmethod def backward(ctx, grad_output): kernel, grad_kernel = ctx.saved_tensors grad_input = UpFirDn2dBackward.apply(grad_output, kernel, grad_kernel, ctx.up, ctx.down, ctx.pad, ctx.g_pad, ctx.in_size, ctx.out_size) return grad_input, None, None, None, None class UpFirDnUpsample(nn.Module): """Upsample, FIR filter, and downsample (upsampole version). References: 1. https://docs.scipy.org/doc/scipy/reference/generated/scipy.signal.upfirdn.html # noqa: E501 2. http://www.ece.northwestern.edu/local-apps/matlabhelp/toolbox/signal/upfirdn.html # noqa: E501 Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. factor (int): Upsampling scale factor. Default: 2. """ def __init__(self, resample_kernel, factor=2): super(UpFirDnUpsample, self).__init__() self.kernel = make_resample_kernel(resample_kernel) * factor ** 2 self.factor = factor pad = self.kernel.shape[0] - factor self.pad = (pad + 1) // 2 + factor - 1, pad // 2 def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=self.factor, down=1, pad=self.pad) return out def __repr__(self): return f'{self.__class__.__name__}(factor={self.factor})' class UpFirDnSmooth(nn.Module): """Upsample, FIR filter, and downsample (smooth version). Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. upsample_factor (int): Upsampling scale factor. Default: 1. downsample_factor (int): Downsampling scale factor. Default: 1. kernel_size (int): Kernel size: Deafult: 1. """ def __init__(self, resample_kernel, upsample_factor=1, downsample_factor=1, kernel_size=1): super(UpFirDnSmooth, self).__init__() self.upsample_factor = upsample_factor self.downsample_factor = downsample_factor self.kernel = make_resample_kernel(resample_kernel) if upsample_factor > 1: self.kernel = self.kernel * upsample_factor ** 2 if upsample_factor > 1: pad = self.kernel.shape[0] - upsample_factor - (kernel_size - 1) self.pad = (pad + 1) // 2 + upsample_factor - 1, pad // 2 + 1 elif downsample_factor > 1: pad = self.kernel.shape[0] - downsample_factor + (kernel_size - 1) self.pad = (pad + 1) // 2, pad // 2 else: raise NotImplementedError def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=1, down=1, pad=self.pad) return out def __repr__(self): return ( f'{self.__class__.__name__}(upsample_factor={self.upsample_factor}, downsample_factor={self.downsample_factor})' ) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None | str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) class ModulatedConv2d(nn.Module): """Modulated Conv2d used in StyleGAN2. There is no bias in ModulatedConv2d. Args: in_channels (int): Channel number of the input. out_channels (int): Channel number of the output. kernel_size (int): Size of the convolving kernel. num_style_feat (int): Channel number of style features. demodulate (bool): Whether to demodulate in the conv layer. Default: True. sample_mode (str | None): Indicating 'upsample', 'downsample' or None. Default: None. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). eps (float): A value added to the denominator for numerical stability. Default: 1e-8. """ def __init__(self, in_channels, out_channels, kernel_size, num_style_feat, demodulate=True, sample_mode=None, resample_kernel= (1, 3, 3, 1), eps=1e-08): super(ModulatedConv2d, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.kernel_size = kernel_size self.demodulate = demodulate self.sample_mode = sample_mode self.eps = eps if self.sample_mode == 'upsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=2, downsample_factor=1, kernel_size=kernel_size) elif self.sample_mode == 'downsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=1, downsample_factor=2, kernel_size=kernel_size) elif self.sample_mode is None: pass else: raise ValueError( f"Wrong sample mode {self.sample_mode}, supported ones are ['upsample', 'downsample', None]." ) self.scale = 1 / math.sqrt(in_channels * kernel_size ** 2) self.modulation = EqualLinear(num_style_feat, in_channels, bias= True, bias_init_val=1, lr_mul=1, activation=None) self.weight = nn.Parameter(torch.randn(1, out_channels, in_channels, kernel_size, kernel_size)) self.padding = kernel_size // 2 def forward(self, x, style): """Forward function. Args: x (Tensor): Tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). Returns: Tensor: Modulated tensor after convolution. """ b, c, h, w = x.shape style = self.modulation(style).view(b, 1, c, 1, 1) weight = self.scale * self.weight * style if self.demodulate: demod = torch.rsqrt(weight.pow(2).sum([2, 3, 4]) + self.eps) weight = weight * demod.view(b, self.out_channels, 1, 1, 1) weight = weight.view(b * self.out_channels, c, self.kernel_size, self.kernel_size) if self.sample_mode == 'upsample': x = x.view(1, b * c, h, w) weight = weight.view(b, self.out_channels, c, self.kernel_size, self.kernel_size) weight = weight.transpose(1, 2).reshape(b * c, self. out_channels, self.kernel_size, self.kernel_size) out = F.conv_transpose2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) out = self.smooth(out) elif self.sample_mode == 'downsample': x = self.smooth(x) x = x.view(1, b * c, *x.shape[2:4]) out = F.conv2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) else: x = x.view(1, b * c, h, w) out = F.conv2d(x, weight, padding=self.padding, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, kernel_size={self.kernel_size}, demodulate={self.demodulate}, sample_mode={self.sample_mode})' ) class ToRGB(nn.Module): """To RGB from features. Args: in_channels (int): Channel number of input. num_style_feat (int): Channel number of style features. upsample (bool): Whether to upsample. Default: True. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). """ def __init__(self, in_channels, num_style_feat, upsample=True, resample_kernel=(1, 3, 3, 1)): super(ToRGB, self).__init__() if upsample: self.upsample = UpFirDnUpsample(resample_kernel, factor=2) else: self.upsample = None self.modulated_conv = ModulatedConv2d(in_channels, 3, kernel_size=1, num_style_feat=num_style_feat, demodulate=False, sample_mode=None) self.bias = nn.Parameter(torch.zeros(1, 3, 1, 1)) def forward(self, x, style, skip=None): """Forward function. Args: x (Tensor): Feature tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). skip (Tensor): Base/skip tensor. Default: None. Returns: Tensor: RGB images. """ out = self.modulated_conv(x, style) out = out + self.bias if skip is not None: if self.upsample: skip = self.upsample(skip) out = out + skip return out def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'num_style_feat': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch.autograd import Function import math from torch import nn as nn from torch.nn import functional as F from torch.nn import init as init from torchvision.models import vgg as vgg import torch.utils.data from torch.utils import data as data from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 4 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_mul_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 48 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex % 12 x0 = xindex % 4 x2 = xindex // 12 x4 = xindex tmp0 = tl.load(in_ptr0 + x3, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + (x0 + 4 * x2), xmask, eviction_policy='evict_last' ) tmp1 = 0.5 tmp2 = tmp0 * tmp1 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x4, tmp4, xmask) @triton.jit def triton_poi_fused_add_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 192 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 3 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5, primals_6 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (1, 3, 4, 1, 1), (12, 4, 1, 1, 1)) assert_size_stride(primals_6, (1, 3, 1, 1), (3, 1, 1, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(16)](primals_3, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_3 buf1 = empty_strided_cuda((4,), (1,), torch.float32) triton_poi_fused_mul_1[grid(4)](primals_2, buf1, 4, XBLOCK=4, num_warps=1, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(buf1, primals_4, reinterpret_tensor(buf0, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf2) del buf0 del buf1 buf3 = empty_strided_cuda((4, 3, 4, 1, 1), (12, 4, 1, 1, 1), torch. float32) triton_poi_fused_mul_2[grid(48)](primals_5, buf2, buf3, 48, XBLOCK= 64, num_warps=1, num_stages=1) buf4 = extern_kernels.convolution(reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0), reinterpret_tensor(buf3, (12, 4, 1, 1), (4, 1, 0, 0), 0), stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf4, (1, 12, 4, 4), (192, 16, 4, 1)) buf5 = reinterpret_tensor(buf4, (4, 3, 4, 4), (48, 16, 4, 1), 0) del buf4 triton_poi_fused_add_3[grid(192)](buf5, primals_6, 192, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 return buf5, primals_4, primals_5, buf2, reinterpret_tensor(buf3, (12, 4, 1, 1), (4, 1, 1, 1), 0), reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0) def make_resample_kernel(k): """Make resampling kernel for UpFirDn. Args: k (list[int]): A list indicating the 1D resample kernel magnitude. Returns: Tensor: 2D resampled kernel. """ k = torch.tensor(k, dtype=torch.float32) if k.ndim == 1: k = k[None, :] * k[:, None] k /= k.sum() return k def upfirdn2d_native(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1): _, channel, in_h, in_w = input.shape input = input.reshape(-1, in_h, in_w, 1) _, in_h, in_w, minor = input.shape kernel_h, kernel_w = kernel.shape out = input.view(-1, in_h, 1, in_w, 1, minor) out = F.pad(out, [0, 0, 0, up_x - 1, 0, 0, 0, up_y - 1]) out = out.view(-1, in_h * up_y, in_w * up_x, minor) out = F.pad(out, [0, 0, max(pad_x0, 0), max(pad_x1, 0), max(pad_y0, 0), max(pad_y1, 0)]) out = out[:, max(-pad_y0, 0):out.shape[1] - max(-pad_y1, 0), max(- pad_x0, 0):out.shape[2] - max(-pad_x1, 0), :] out = out.permute(0, 3, 1, 2) out = out.reshape([-1, 1, in_h * up_y + pad_y0 + pad_y1, in_w * up_x + pad_x0 + pad_x1]) w = torch.flip(kernel, [0, 1]).view(1, 1, kernel_h, kernel_w) out = F.conv2d(out, w) out = out.reshape(-1, minor, in_h * up_y + pad_y0 + pad_y1 - kernel_h + 1, in_w * up_x + pad_x0 + pad_x1 - kernel_w + 1) out = out.permute(0, 2, 3, 1) out = out[:, ::down_y, ::down_x, :] out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 return out.view(-1, channel, out_h, out_w) def upfirdn2d(input, kernel, up=1, down=1, pad=(0, 0)): if input.device.type == 'cpu': out = upfirdn2d_native(input, kernel, up, up, down, down, pad[0], pad[1], pad[0], pad[1]) else: out = UpFirDn2d.apply(input, kernel, (up, up), (down, down), (pad[0 ], pad[1], pad[0], pad[1])) return out def fused_leaky_relu(input, bias, negative_slope=0.2, scale=2 ** 0.5): return FusedLeakyReLUFunction.apply(input, bias, negative_slope, scale) class UpFirDn2dBackward(Function): @staticmethod def forward(ctx, grad_output, kernel, grad_kernel, up, down, pad, g_pad, in_size, out_size): up_x, up_y = up down_x, down_y = down g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 = g_pad grad_output = grad_output.reshape(-1, out_size[0], out_size[1], 1) grad_input = upfirdn2d_ext.upfirdn2d(grad_output, grad_kernel, down_x, down_y, up_x, up_y, g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1) grad_input = grad_input.view(in_size[0], in_size[1], in_size[2], in_size[3]) ctx.save_for_backward(kernel) pad_x0, pad_x1, pad_y0, pad_y1 = pad ctx.up_x = up_x ctx.up_y = up_y ctx.down_x = down_x ctx.down_y = down_y ctx.pad_x0 = pad_x0 ctx.pad_x1 = pad_x1 ctx.pad_y0 = pad_y0 ctx.pad_y1 = pad_y1 ctx.in_size = in_size ctx.out_size = out_size return grad_input @staticmethod def backward(ctx, gradgrad_input): kernel, = ctx.saved_tensors gradgrad_input = gradgrad_input.reshape(-1, ctx.in_size[2], ctx. in_size[3], 1) gradgrad_out = upfirdn2d_ext.upfirdn2d(gradgrad_input, kernel, ctx. up_x, ctx.up_y, ctx.down_x, ctx.down_y, ctx.pad_x0, ctx.pad_x1, ctx.pad_y0, ctx.pad_y1) gradgrad_out = gradgrad_out.view(ctx.in_size[0], ctx.in_size[1], ctx.out_size[0], ctx.out_size[1]) return gradgrad_out, None, None, None, None, None, None, None, None class UpFirDn2d(Function): @staticmethod def forward(ctx, input, kernel, up, down, pad): up_x, up_y = up down_x, down_y = down pad_x0, pad_x1, pad_y0, pad_y1 = pad kernel_h, kernel_w = kernel.shape _batch, channel, in_h, in_w = input.shape ctx.in_size = input.shape input = input.reshape(-1, in_h, in_w, 1) ctx.save_for_backward(kernel, torch.flip(kernel, [0, 1])) out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1 out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1 ctx.out_size = out_h, out_w ctx.up = up_x, up_y ctx.down = down_x, down_y ctx.pad = pad_x0, pad_x1, pad_y0, pad_y1 g_pad_x0 = kernel_w - pad_x0 - 1 g_pad_y0 = kernel_h - pad_y0 - 1 g_pad_x1 = in_w * up_x - out_w * down_x + pad_x0 - up_x + 1 g_pad_y1 = in_h * up_y - out_h * down_y + pad_y0 - up_y + 1 ctx.g_pad = g_pad_x0, g_pad_x1, g_pad_y0, g_pad_y1 out = upfirdn2d_ext.upfirdn2d(input, kernel, up_x, up_y, down_x, down_y, pad_x0, pad_x1, pad_y0, pad_y1) out = out.view(-1, channel, out_h, out_w) return out @staticmethod def backward(ctx, grad_output): kernel, grad_kernel = ctx.saved_tensors grad_input = UpFirDn2dBackward.apply(grad_output, kernel, grad_kernel, ctx.up, ctx.down, ctx.pad, ctx.g_pad, ctx.in_size, ctx.out_size) return grad_input, None, None, None, None class UpFirDnUpsample(nn.Module): """Upsample, FIR filter, and downsample (upsampole version). References: 1. https://docs.scipy.org/doc/scipy/reference/generated/scipy.signal.upfirdn.html # noqa: E501 2. http://www.ece.northwestern.edu/local-apps/matlabhelp/toolbox/signal/upfirdn.html # noqa: E501 Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. factor (int): Upsampling scale factor. Default: 2. """ def __init__(self, resample_kernel, factor=2): super(UpFirDnUpsample, self).__init__() self.kernel = make_resample_kernel(resample_kernel) * factor ** 2 self.factor = factor pad = self.kernel.shape[0] - factor self.pad = (pad + 1) // 2 + factor - 1, pad // 2 def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=self.factor, down=1, pad=self.pad) return out def __repr__(self): return f'{self.__class__.__name__}(factor={self.factor})' class UpFirDnSmooth(nn.Module): """Upsample, FIR filter, and downsample (smooth version). Args: resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. upsample_factor (int): Upsampling scale factor. Default: 1. downsample_factor (int): Downsampling scale factor. Default: 1. kernel_size (int): Kernel size: Deafult: 1. """ def __init__(self, resample_kernel, upsample_factor=1, downsample_factor=1, kernel_size=1): super(UpFirDnSmooth, self).__init__() self.upsample_factor = upsample_factor self.downsample_factor = downsample_factor self.kernel = make_resample_kernel(resample_kernel) if upsample_factor > 1: self.kernel = self.kernel * upsample_factor ** 2 if upsample_factor > 1: pad = self.kernel.shape[0] - upsample_factor - (kernel_size - 1) self.pad = (pad + 1) // 2 + upsample_factor - 1, pad // 2 + 1 elif downsample_factor > 1: pad = self.kernel.shape[0] - downsample_factor + (kernel_size - 1) self.pad = (pad + 1) // 2, pad // 2 else: raise NotImplementedError def forward(self, x): out = upfirdn2d(x, self.kernel.type_as(x), up=1, down=1, pad=self.pad) return out def __repr__(self): return ( f'{self.__class__.__name__}(upsample_factor={self.upsample_factor}, downsample_factor={self.downsample_factor})' ) class FusedLeakyReLUFunctionBackward(Function): @staticmethod def forward(ctx, grad_output, out, negative_slope, scale): ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale empty = grad_output.new_empty(0) grad_input = fused_act_ext.fused_bias_act(grad_output, empty, out, 3, 1, negative_slope, scale) dim = [0] if grad_input.ndim > 2: dim += list(range(2, grad_input.ndim)) grad_bias = grad_input.sum(dim).detach() return grad_input, grad_bias @staticmethod def backward(ctx, gradgrad_input, gradgrad_bias): out, = ctx.saved_tensors gradgrad_out = fused_act_ext.fused_bias_act(gradgrad_input, gradgrad_bias, out, 3, 1, ctx.negative_slope, ctx.scale) return gradgrad_out, None, None, None class FusedLeakyReLUFunction(Function): @staticmethod def forward(ctx, input, bias, negative_slope, scale): empty = input.new_empty(0) out = fused_act_ext.fused_bias_act(input, bias, empty, 3, 0, negative_slope, scale) ctx.save_for_backward(out) ctx.negative_slope = negative_slope ctx.scale = scale return out @staticmethod def backward(ctx, grad_output): out, = ctx.saved_tensors grad_input, grad_bias = FusedLeakyReLUFunctionBackward.apply( grad_output, out, ctx.negative_slope, ctx.scale) return grad_input, grad_bias, None, None class EqualLinear(nn.Module): """Equalized Linear as StyleGAN2. Args: in_channels (int): Size of each sample. out_channels (int): Size of each output sample. bias (bool): If set to ``False``, the layer will not learn an additive bias. Default: ``True``. bias_init_val (float): Bias initialized value. Default: 0. lr_mul (float): Learning rate multiplier. Default: 1. activation (None | str): The activation after ``linear`` operation. Supported: 'fused_lrelu', None. Default: None. """ def __init__(self, in_channels, out_channels, bias=True, bias_init_val= 0, lr_mul=1, activation=None): super(EqualLinear, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.lr_mul = lr_mul self.activation = activation if self.activation not in ['fused_lrelu', None]: raise ValueError( f"Wrong activation value in EqualLinear: {activation}Supported ones are: ['fused_lrelu', None]." ) self.scale = 1 / math.sqrt(in_channels) * lr_mul self.weight = nn.Parameter(torch.randn(out_channels, in_channels). div_(lr_mul)) if bias: self.bias = nn.Parameter(torch.zeros(out_channels).fill_( bias_init_val)) else: self.register_parameter('bias', None) def forward(self, x): if self.bias is None: bias = None else: bias = self.bias * self.lr_mul if self.activation == 'fused_lrelu': out = F.linear(x, self.weight * self.scale) out = fused_leaky_relu(out, bias) else: out = F.linear(x, self.weight * self.scale, bias=bias) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, bias={self.bias is not None})' ) class ModulatedConv2d(nn.Module): """Modulated Conv2d used in StyleGAN2. There is no bias in ModulatedConv2d. Args: in_channels (int): Channel number of the input. out_channels (int): Channel number of the output. kernel_size (int): Size of the convolving kernel. num_style_feat (int): Channel number of style features. demodulate (bool): Whether to demodulate in the conv layer. Default: True. sample_mode (str | None): Indicating 'upsample', 'downsample' or None. Default: None. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). eps (float): A value added to the denominator for numerical stability. Default: 1e-8. """ def __init__(self, in_channels, out_channels, kernel_size, num_style_feat, demodulate=True, sample_mode=None, resample_kernel= (1, 3, 3, 1), eps=1e-08): super(ModulatedConv2d, self).__init__() self.in_channels = in_channels self.out_channels = out_channels self.kernel_size = kernel_size self.demodulate = demodulate self.sample_mode = sample_mode self.eps = eps if self.sample_mode == 'upsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=2, downsample_factor=1, kernel_size=kernel_size) elif self.sample_mode == 'downsample': self.smooth = UpFirDnSmooth(resample_kernel, upsample_factor=1, downsample_factor=2, kernel_size=kernel_size) elif self.sample_mode is None: pass else: raise ValueError( f"Wrong sample mode {self.sample_mode}, supported ones are ['upsample', 'downsample', None]." ) self.scale = 1 / math.sqrt(in_channels * kernel_size ** 2) self.modulation = EqualLinear(num_style_feat, in_channels, bias= True, bias_init_val=1, lr_mul=1, activation=None) self.weight = nn.Parameter(torch.randn(1, out_channels, in_channels, kernel_size, kernel_size)) self.padding = kernel_size // 2 def forward(self, x, style): """Forward function. Args: x (Tensor): Tensor with shape (b, c, h, w). style (Tensor): Tensor with shape (b, num_style_feat). Returns: Tensor: Modulated tensor after convolution. """ b, c, h, w = x.shape style = self.modulation(style).view(b, 1, c, 1, 1) weight = self.scale * self.weight * style if self.demodulate: demod = torch.rsqrt(weight.pow(2).sum([2, 3, 4]) + self.eps) weight = weight * demod.view(b, self.out_channels, 1, 1, 1) weight = weight.view(b * self.out_channels, c, self.kernel_size, self.kernel_size) if self.sample_mode == 'upsample': x = x.view(1, b * c, h, w) weight = weight.view(b, self.out_channels, c, self.kernel_size, self.kernel_size) weight = weight.transpose(1, 2).reshape(b * c, self. out_channels, self.kernel_size, self.kernel_size) out = F.conv_transpose2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) out = self.smooth(out) elif self.sample_mode == 'downsample': x = self.smooth(x) x = x.view(1, b * c, *x.shape[2:4]) out = F.conv2d(x, weight, padding=0, stride=2, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) else: x = x.view(1, b * c, h, w) out = F.conv2d(x, weight, padding=self.padding, groups=b) out = out.view(b, self.out_channels, *out.shape[2:4]) return out def __repr__(self): return ( f'{self.__class__.__name__}(in_channels={self.in_channels}, out_channels={self.out_channels}, kernel_size={self.kernel_size}, demodulate={self.demodulate}, sample_mode={self.sample_mode})' ) class ToRGBNew(nn.Module): """To RGB from features. Args: in_channels (int): Channel number of input. num_style_feat (int): Channel number of style features. upsample (bool): Whether to upsample. Default: True. resample_kernel (list[int]): A list indicating the 1D resample kernel magnitude. Default: (1, 3, 3, 1). """ def __init__(self, in_channels, num_style_feat, upsample=True, resample_kernel=(1, 3, 3, 1)): super(ToRGBNew, self).__init__() if upsample: self.upsample = UpFirDnUpsample(resample_kernel, factor=2) else: self.upsample = None self.modulated_conv = ModulatedConv2d(in_channels, 3, kernel_size=1, num_style_feat=num_style_feat, demodulate=False, sample_mode=None) self.bias = nn.Parameter(torch.zeros(1, 3, 1, 1)) def forward(self, input_0, input_1): primals_6 = self.bias primals_5 = self.modulated_conv.weight primals_3 = self.modulated_conv.modulation.weight primals_2 = self.modulated_conv.modulation.bias primals_1 = input_0 primals_4 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6]) return output[0]

Lotayou/BasicSR

ToRGB

false

2,594

[ "Apache-2.0", "MIT" ]

0

6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

https://github.com/Lotayou/BasicSR/tree/6cf9a706dd680d54f7dc26e87318ff79f76c0dbf

hswish

import torch import torch.onnx import torch import torch.nn as nn import torch.nn.functional as F class hswish(nn.Module): def forward(self, x): out = x * F.relu6(x + 3, inplace=True) / 6 return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.onnx import torch import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_add_div_hardtanh_mul_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask) tmp1 = 3.0 tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = triton_helpers.maximum(tmp2, tmp3) tmp5 = 6.0 tmp6 = triton_helpers.minimum(tmp4, tmp5) tmp7 = tmp0 * tmp6 tmp8 = 0.16666666666666666 tmp9 = tmp7 * tmp8 tl.store(out_ptr0 + x0, tmp9, xmask) def call(args): arg0_1, = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_div_hardtanh_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class hswishNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]

LukasKratochvila/pytorch-ssd

hswish

false

2,595

[ "MIT" ]

0

de6ed2be6ce0b03634d4cbf41622cfe5c87d077c

https://github.com/LukasKratochvila/pytorch-ssd/tree/de6ed2be6ce0b03634d4cbf41622cfe5c87d077c

GeneratorGCN

from torch.nn import Module import math import torch import torch.nn.functional as F from torch.nn.parameter import Parameter from torch.nn.modules.module import Module import torch.nn as nn from torch.nn import Parameter from torch.nn import Module class GraphConvolution(Module): """ Simple GCN layer, similar to https://arxiv.org/abs/1609.02907 """ def __init__(self, in_features, out_features, bias=True): super(GraphConvolution, self).__init__() self.in_features = in_features self.out_features = out_features self.weight = Parameter(torch.FloatTensor(in_features, out_features)) if bias: self.bias = Parameter(torch.FloatTensor(out_features)) else: self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self): stdv = 1.0 / math.sqrt(self.weight.size(1)) torch.nn.init.kaiming_uniform_(self.weight) if self.bias is not None: self.bias.data.uniform_(-stdv, stdv) def forward(self, input, adj): support = torch.mm(input, self.weight) output = torch.spmm(adj, support) if self.bias is not None: return output + self.bias else: return output def __repr__(self): return self.__class__.__name__ + ' (' + str(self.in_features ) + ' -> ' + str(self.out_features) + ')' class GeneratorGCN(nn.Module): def __init__(self, nfeat, nhid, nclass, dropout, NN): super(GeneratorGCN, self).__init__() self.gc1 = GraphConvolution(nfeat, nhid) self.gc2 = GraphConvolution(nhid, nhid) self.gc3 = GraphConvolution(nhid, nclass) self.dropout = dropout self.NN = NN def apply_bn(self, x): """ Batch normalization of 3D tensor x """ bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, x, adj): x = F.relu(self.gc1(x, adj)) x = F.relu(self.gc2(x, adj)) x = F.relu(self.gc3(x, adj)) return x def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'nfeat': 4, 'nhid': 4, 'nclass': 4, 'dropout': 0.5, 'NN': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch.nn import Module import math from torch.nn.parameter import Parameter from torch.nn.modules.module import Module import torch.nn as nn from torch.nn import Parameter from torch.nn import Module assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_relu_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, xmask) @triton.jit def triton_poi_fused_add_relu_threshold_backward_1(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 16 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, xmask) tl.store(out_ptr0 + x2, tmp6, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8) = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4,), (1,)) assert_size_stride(primals_5, (4, 4), (4, 1)) assert_size_stride(primals_6, (4,), (1,)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_2, primals_1, out=buf0) del primals_1 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf0, out=buf1) buf2 = buf1 del buf1 get_raw_stream(0) triton_poi_fused_add_relu_0[grid(16)](buf2, primals_4, 16, XBLOCK= 16, num_warps=1, num_stages=1) del primals_4 buf3 = buf0 del buf0 extern_kernels.mm(buf2, primals_5, out=buf3) buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf3, out=buf4) buf5 = buf4 del buf4 triton_poi_fused_add_relu_0[grid(16)](buf5, primals_6, 16, XBLOCK= 16, num_warps=1, num_stages=1) del primals_6 buf6 = buf3 del buf3 extern_kernels.mm(buf5, primals_7, out=buf6) buf7 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_3, buf6, out=buf7) del buf6 buf8 = buf7 del buf7 buf9 = empty_strided_cuda((4, 4), (4, 1), torch.bool) triton_poi_fused_add_relu_threshold_backward_1[grid(16)](buf8, primals_8, buf9, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_8 return buf8, buf2, buf5, buf9, reinterpret_tensor(primals_3, (4, 4), (1, 4), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0 ), reinterpret_tensor(primals_5, (4, 4), (1, 4), 0 ), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0) class GraphConvolution(Module): """ Simple GCN layer, similar to https://arxiv.org/abs/1609.02907 """ def __init__(self, in_features, out_features, bias=True): super(GraphConvolution, self).__init__() self.in_features = in_features self.out_features = out_features self.weight = Parameter(torch.FloatTensor(in_features, out_features)) if bias: self.bias = Parameter(torch.FloatTensor(out_features)) else: self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self): stdv = 1.0 / math.sqrt(self.weight.size(1)) torch.nn.init.kaiming_uniform_(self.weight) if self.bias is not None: self.bias.data.uniform_(-stdv, stdv) def forward(self, input, adj): support = torch.mm(input, self.weight) output = torch.spmm(adj, support) if self.bias is not None: return output + self.bias else: return output def __repr__(self): return self.__class__.__name__ + ' (' + str(self.in_features ) + ' -> ' + str(self.out_features) + ')' class GeneratorGCNNew(nn.Module): def __init__(self, nfeat, nhid, nclass, dropout, NN): super(GeneratorGCNNew, self).__init__() self.gc1 = GraphConvolution(nfeat, nhid) self.gc2 = GraphConvolution(nhid, nhid) self.gc3 = GraphConvolution(nhid, nclass) self.dropout = dropout self.NN = NN def apply_bn(self, x): """ Batch normalization of 3D tensor x """ bn_module = nn.BatchNorm1d(x.size()[1]) return bn_module(x) def forward(self, input_0, input_1): primals_1 = self.gc1.weight primals_4 = self.gc1.bias primals_2 = self.gc2.weight primals_6 = self.gc2.bias primals_3 = self.gc3.weight primals_8 = self.gc3.bias primals_5 = input_0 primals_7 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8]) return output[0]

LinChen-65/pygcn

GeneratorGCN

false

2,596

[ "MIT" ]

0

0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

https://github.com/LinChen-65/pygcn/tree/0a77f56fd6d5cb3edc7affc2ba3455733d7da6eb

Bottleneck_v2

import torch import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl class Bottleneck_v2(nn.Module): def __init__(self): super(Bottleneck_v2, self).__init__() self.conv = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv1 = nn.Conv2d(256, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, x): x = self.conv(x) y1 = self.conv1(x).relu_() y2 = self.conv2(y1).relu_() y3 = self.conv3(y2) y3 += x return y3.relu_() def get_inputs(): return [torch.rand([4, 64, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers import torch.nn as nn import torch.cuda import torch.backends.cudnn import torch.backends.mkl assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] ymask = yindex < ynumel xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), ymask, eviction_policy= 'evict_last') tl.store(out_ptr0 + (y0 + 64 * x2 + 262144 * y1), tmp0, ymask) @triton.jit def triton_poi_fused_1(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 9 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 64 y1 = yindex // 64 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 64 * x2 + 576 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 256 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, None) @triton.jit def triton_poi_fused_convolution_relu_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 64 tmp0 = tl.load(in_out_ptr0 + x2, None) tmp1 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, None) @triton.jit def triton_poi_fused_add_convolution_relu_4(in_ptr0, in_ptr1, in_ptr2, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 256 yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] xmask = xindex < xnumel x2 = xindex y3 = yindex y0 = yindex % 4096 y1 = yindex // 4096 tmp0 = tl.load(in_ptr0 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + (x2 + 256 * y3), xmask, eviction_policy= 'evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = tl.full([1, 1], 0, tl.int32) tmp6 = triton_helpers.maximum(tmp5, tmp4) tl.store(out_ptr0 + (y0 + 4096 * x2 + 1048576 * y1), tmp6, xmask) @triton.jit def triton_poi_fused_threshold_backward_5(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): yoffset = tl.program_id(1) * YBLOCK yindex = yoffset + tl.arange(0, YBLOCK)[None, :] tl.full([XBLOCK, YBLOCK], True, tl.int1) xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, YBLOCK], True, tl.int1) x2 = xindex y3 = yindex y0 = yindex % 256 y1 = yindex // 256 tmp0 = tl.load(in_ptr0 + (x2 + 4096 * y3), None, eviction_policy= 'evict_last') tmp1 = 0.0 tmp2 = tmp0 <= tmp1 tl.store(out_ptr0 + (y0 + 256 * x2 + 1048576 * y1), tmp2, None) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9) = args args.clear() assert_size_stride(primals_1, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_2, (256,), (1,)) assert_size_stride(primals_3, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_4, (64, 256, 1, 1), (256, 1, 1, 1)) assert_size_stride(primals_5, (64,), (1,)) assert_size_stride(primals_6, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_7, (64,), (1,)) assert_size_stride(primals_8, (256, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_9, (256,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 64, 64, 64), (262144, 1, 4096, 64), torch.float32) get_raw_stream(0) triton_poi_fused_0[grid(256, 4096)](primals_3, buf0, 256, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del primals_3 buf1 = empty_strided_cuda((64, 64, 3, 3), (576, 1, 192, 64), torch. float32) triton_poi_fused_1[grid(4096, 9)](primals_6, buf1, 4096, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_6 buf2 = extern_kernels.convolution(buf0, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf3 = buf2 del buf2 triton_poi_fused_convolution_2[grid(4194304)](buf3, primals_2, 4194304, XBLOCK=1024, num_warps=4, num_stages=1) del primals_2 buf4 = extern_kernels.convolution(buf3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_3[grid(1048576)](buf5, primals_5, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 buf6 = extern_kernels.convolution(buf5, buf1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 64, 64, 64), (262144, 1, 4096, 64)) buf7 = buf6 del buf6 triton_poi_fused_convolution_relu_3[grid(1048576)](buf7, primals_7, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_7 buf8 = extern_kernels.convolution(buf7, primals_8, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf8, (4, 256, 64, 64), (1048576, 1, 16384, 256)) buf9 = empty_strided_cuda((4, 256, 64, 64), (1048576, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_relu_4[grid(16384, 256)](buf8, primals_9, buf3, buf9, 16384, 256, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) del buf8 del primals_9 buf10 = empty_strided_cuda((4, 256, 64, 64), (1048576, 1, 16384, 256), torch.bool) triton_poi_fused_threshold_backward_5[grid(1024, 4096)](buf9, buf10, 1024, 4096, XBLOCK=32, YBLOCK=32, num_warps=4, num_stages=1) return (buf9, primals_1, buf0, primals_4, buf1, primals_8, buf3, buf5, buf7, buf10) class Bottleneck_v2New(nn.Module): def __init__(self): super(Bottleneck_v2New, self).__init__() self.conv = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv1 = nn.Conv2d(256, 64, kernel_size=(1, 1), stride=(1, 1), bias=True) self.conv2 = nn.Conv2d(64, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=True) self.conv3 = nn.Conv2d(64, 256, kernel_size=(1, 1), stride=(1, 1), bias=True) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_4 = self.conv1.weight primals_5 = self.conv1.bias primals_6 = self.conv2.weight primals_7 = self.conv2.bias primals_8 = self.conv3.weight primals_9 = self.conv3.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9]) return output[0]

JudeDavis1/intel-extension-for-pytorch

Bottleneck_v2

false

2,597

[ "Apache-2.0" ]

0

364e34cb4917a709f5108c07d4005bf82f3d5067

https://github.com/JudeDavis1/intel-extension-for-pytorch/tree/364e34cb4917a709f5108c07d4005bf82f3d5067

SoftEntropy

import torch import torch.nn.functional as F import torch.nn as nn from torch.nn import * class SoftEntropy(nn.Module): def __init__(self): super(SoftEntropy, self).__init__() self.logsoftmax = nn.LogSoftmax(dim=1) def forward(self, inputs, targets): log_probs = self.logsoftmax(inputs) loss = (-F.softmax(targets, dim=1).detach() * log_probs).mean(0).sum() return loss def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {}]

import torch import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import torch.nn as nn from torch.nn import * assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda @triton.jit def triton_poi_fused__softmax_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr ): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tmp9 = tl_math.exp(tmp8) tl.store(out_ptr0 + x3, tmp9, xmask) @triton.jit def triton_poi_fused__log_softmax_1(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = triton_helpers.maximum(tmp1, tmp2) tmp5 = triton_helpers.maximum(tmp3, tmp4) tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = tmp0 - tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused__log_softmax__softmax_mul_neg_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x0 = xindex % 16 x2 = xindex // 64 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp10 = tl.load(in_ptr1 + x3, xmask) tmp11 = tl.load(in_ptr1 + (x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp13 = tl.load(in_ptr1 + (16 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp16 = tl.load(in_ptr1 + (32 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp19 = tl.load(in_ptr1 + (48 + x0 + 64 * x2), xmask, eviction_policy= 'evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tmp9 = -tmp8 tmp12 = tl_math.exp(tmp11) tmp14 = tl_math.exp(tmp13) tmp15 = tmp12 + tmp14 tmp17 = tl_math.exp(tmp16) tmp18 = tmp15 + tmp17 tmp20 = tl_math.exp(tmp19) tmp21 = tmp18 + tmp20 tmp22 = tl_math.log(tmp21) tmp23 = tmp10 - tmp22 tmp24 = tmp9 * tmp23 tl.store(out_ptr0 + x3, tmp24, xmask) @triton.jit def triton_per_fused_mean_sum_3(in_ptr0, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 64 xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:, None] tl.full([XBLOCK, RBLOCK], True, tl.int1) rindex = tl.arange(0, RBLOCK)[None, :] tl.full([XBLOCK, RBLOCK], True, tl.int1) r0 = rindex tmp0 = tl.load(in_ptr0 + r0, None) tmp1 = tl.load(in_ptr0 + (64 + r0), None) tmp3 = tl.load(in_ptr0 + (128 + r0), None) tmp5 = tl.load(in_ptr0 + (192 + r0), None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / tmp7 tmp9 = tl.broadcast_to(tmp8, [XBLOCK, RBLOCK]) tmp11 = tl.sum(tmp9, 1)[:, None] tl.store(out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp11, None) def call(args): arg0_1, arg1_1 = args args.clear() assert_size_stride(arg0_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(256)](arg1_1, buf0, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg1_1 buf1 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax_1[grid(256)](arg0_1, buf1, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax__softmax_mul_neg_2[grid(256)](buf0, buf1, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf0 del buf1 buf3 = empty_strided_cuda((), (), torch.float32) triton_per_fused_mean_sum_3[grid(1)](buf2, buf3, 1, 64, XBLOCK=1, num_warps=2, num_stages=1) del buf2 return buf3, class SoftEntropyNew(nn.Module): def __init__(self): super(SoftEntropyNew, self).__init__() self.logsoftmax = nn.LogSoftmax(dim=1) def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]

LunarShen/SECRET

SoftEntropy

false

2,598

[ "MIT" ]

0

0f652e63ce760ece8690cbad013f0d9bdb341e84

https://github.com/LunarShen/SECRET/tree/0f652e63ce760ece8690cbad013f0d9bdb341e84

UPChannelRPN

import torch import torch.nn.functional as F import torch.nn as nn def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class RPN(nn.Module): def __init__(self): super(RPN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelRPN(RPN): def __init__(self, anchor_num=5, feature_in=256): super(UPChannelRPN, self).__init__() cls_output = 2 * anchor_num loc_output = 4 * anchor_num self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, z_f, x_f): cls_kernel = self.template_cls_conv(z_f) loc_kernel = self.template_loc_conv(z_f) cls_feature = self.search_cls_conv(x_f) loc_feature = self.search_loc_conv(x_f) cls = xcorr_fast(cls_feature, cls_kernel) loc = self.loc_adjust(xcorr_fast(loc_feature, loc_kernel)) return cls, loc def get_inputs(): return [torch.rand([4, 256, 64, 64]), torch.rand([4, 256, 64, 64])] def get_init_inputs(): return [[], {}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream import torch.nn.functional as F import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_convolution_view_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 2560 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x3 = xindex x1 = xindex // 3844 % 256 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, None) @triton.jit def triton_poi_fused_convolution_view_2(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x4 = xindex x1 = xindex // 3844 % 5120 tmp0 = tl.load(in_out_ptr0 + x4, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x4, tmp2, None) @triton.jit def triton_poi_fused_convolution_3(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 80 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 20 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x2, tmp2, xmask) def call(args): (primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12 ) = args args.clear() assert_size_stride(primals_1, (2560, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_2, (2560,), (1,)) assert_size_stride(primals_3, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_4, (5120, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_5, (5120,), (1,)) assert_size_stride(primals_6, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_7, (256,), (1,)) assert_size_stride(primals_8, (4, 256, 64, 64), (1048576, 4096, 64, 1)) assert_size_stride(primals_9, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_10, (256,), (1,)) assert_size_stride(primals_11, (20, 20, 1, 1), (20, 1, 1, 1)) assert_size_stride(primals_12, (20,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 2560, 62, 62), (9840640, 3844, 62, 1)) buf1 = extern_kernels.convolution(primals_3, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 5120, 62, 62), (19681280, 3844, 62, 1)) buf2 = extern_kernels.convolution(primals_8, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf3 = extern_kernels.convolution(primals_8, primals_9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 256, 62, 62), (984064, 3844, 62, 1)) buf4 = buf0 del buf0 buf5 = reinterpret_tensor(buf4, (40, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf4 get_raw_stream(0) triton_poi_fused_convolution_view_0[grid(39362560)](buf5, primals_2, 39362560, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf6 = buf2 del buf2 triton_poi_fused_convolution_1[grid(3936256)](buf6, primals_7, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_7 buf7 = extern_kernels.convolution(reinterpret_tensor(buf6, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf5, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf7, (1, 40, 1, 1), (40, 1, 1, 1)) buf8 = buf1 del buf1 buf9 = reinterpret_tensor(buf8, (80, 256, 62, 62), (984064, 3844, 62, 1), 0) del buf8 triton_poi_fused_convolution_view_2[grid(78725120)](buf9, primals_5, 78725120, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf10 = buf3 del buf3 triton_poi_fused_convolution_1[grid(3936256)](buf10, primals_10, 3936256, XBLOCK=512, num_warps=8, num_stages=1) del primals_10 buf11 = extern_kernels.convolution(reinterpret_tensor(buf10, (1, 1024, 62, 62), (0, 3844, 62, 1), 0), buf9, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf11, (1, 80, 1, 1), (80, 1, 1, 1)) buf12 = extern_kernels.convolution(reinterpret_tensor(buf11, (4, 20, 1, 1), (20, 1, 1, 1), 0), primals_11, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf12, (4, 20, 1, 1), (20, 1, 1, 1)) buf13 = buf12 del buf12 triton_poi_fused_convolution_3[grid(80)](buf13, primals_12, 80, XBLOCK=128, num_warps=4, num_stages=1) del primals_12 return (reinterpret_tensor(buf7, (4, 10, 1, 1), (10, 1, 1, 1), 0), buf13, primals_1, primals_3, primals_4, primals_6, primals_8, primals_9, primals_11, buf5, reinterpret_tensor(buf6, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), buf9, reinterpret_tensor(buf10, (1, 1024, 62, 62), (3936256, 3844, 62, 1), 0), reinterpret_tensor(buf11, (4, 20, 1, 1), (20, 1, 1, 1), 0)) def xcorr_fast(x, kernel): """group conv2d to calculate cross correlation, fast version """ batch = kernel.size()[0] pk = kernel.view(-1, x.size()[1], kernel.size()[2], kernel.size()[3]) px = x.view(1, -1, x.size()[2], x.size()[3]) po = F.conv2d(px, pk, groups=batch) po = po.view(batch, -1, po.size()[2], po.size()[3]) return po class RPN(nn.Module): def __init__(self): super(RPN, self).__init__() def forward(self, z_f, x_f): raise NotImplementedError class UPChannelRPNNew(RPN): def __init__(self, anchor_num=5, feature_in=256): super(UPChannelRPNNew, self).__init__() cls_output = 2 * anchor_num loc_output = 4 * anchor_num self.template_cls_conv = nn.Conv2d(feature_in, feature_in * cls_output, kernel_size=3) self.template_loc_conv = nn.Conv2d(feature_in, feature_in * loc_output, kernel_size=3) self.search_cls_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.search_loc_conv = nn.Conv2d(feature_in, feature_in, kernel_size=3) self.loc_adjust = nn.Conv2d(loc_output, loc_output, kernel_size=1) def forward(self, input_0, input_1): primals_1 = self.template_cls_conv.weight primals_2 = self.template_cls_conv.bias primals_4 = self.template_loc_conv.weight primals_5 = self.template_loc_conv.bias primals_6 = self.search_cls_conv.weight primals_7 = self.search_cls_conv.bias primals_9 = self.search_loc_conv.weight primals_10 = self.search_loc_conv.bias primals_11 = self.loc_adjust.weight primals_12 = self.loc_adjust.bias primals_3 = input_0 primals_8 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11, primals_12]) return output[0], output[1]

IRASatUC/pysot

UPChannelRPN

false

2,599

[ "Apache-2.0" ]

0

2bbc5c0938b56899e5caead84983e3311f1d1911

https://github.com/IRASatUC/pysot/tree/2bbc5c0938b56899e5caead84983e3311f1d1911

MyLinear

import torch from torch import nn from torch.nn import functional as F class MyLinear(nn.Module): def __init__(self, in_units, units): super().__init__() self.weight = nn.Parameter(torch.randn(in_units, units)) self.bias = nn.Parameter(torch.randn(units)) def forward(self, X): linear = torch.matmul(X, self.weight.data) + self.bias.data return F.relu(linear) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_units': 4, 'units': 4}]

import torch from torch._inductor.select_algorithm import extern_kernels import triton import triton.language as tl from torch._inductor.runtime.triton_heuristics import grid from torch._C import _cuda_getCurrentRawStream as get_raw_stream from torch._inductor.runtime import triton_helpers from torch import nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_add_relu_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x2, tmp4, xmask) def call(args): arg0_1, arg1_1, arg2_1 = args args.clear() assert_size_stride(arg0_1, (4, 4), (4, 1)) assert_size_stride(arg1_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(arg2_1, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(arg1_1, (64, 4), (4, 1), 0), arg0_1, out=buf0) del arg0_1 del arg1_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_relu_0[grid(256)](buf1, arg2_1, 256, XBLOCK= 256, num_warps=4, num_stages=1) del arg2_1 return buf1, class MyLinearNew(nn.Module): def __init__(self, in_units, units): super().__init__() self.weight = nn.Parameter(torch.randn(in_units, units)) self.bias = nn.Parameter(torch.randn(units)) def forward(self, input_0): arg0_1 = self.weight arg2_1 = self.bias arg1_1 = input_0 output = call([arg0_1, arg1_1, arg2_1]) return output[0]

JunoCheon/D2L

MyLinear

false

2,600

[ "MIT" ]

0

9464709862e55151aec28fc637c5942738bdd72b

https://github.com/JunoCheon/D2L/tree/9464709862e55151aec28fc637c5942738bdd72b