Datasets:
Teen-Different
/
Code_Opt_Triton

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RNNModel
import math import torch import numpy as np import torch.nn as nn import torch.nn.functional as F def initialize(dims, connection_prob=1.0, shape=0.1, scale=1.0): w = np.random.gamma(shape, scale, size=dims) w *= np.random.rand(*dims) < connection_prob return np.float32(w) class VanillaRNNCell(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='tanh', ct=False): super(VanillaRNNCell, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.nonlinearity = nonlinearity self.ct = ct self.weight_ih = nn.Parameter(torch.zeros((input_size, hidden_size))) self.weight_hh = nn.Parameter(torch.zeros((hidden_size, hidden_size))) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.reset_parameters() if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def reset_parameters(self): stdv = 1.0 / math.sqrt(self.hidden_size) for weight in self.parameters(): nn.init.uniform_(weight, -stdv, stdv) def forward(self, inp, hidden_in): if not self.ct: hidden_out = self.act(torch.matmul(inp, self.weight_ih) + torch .matmul(hidden_in, self.weight_hh) + self.bias) else: alpha = 0.1 hidden_out = (1 - alpha) * hidden_in + alpha * self.act(torch. matmul(inp, self.weight_ih) + torch.matmul(hidden_in, self. weight_hh) + self.bias) return hidden_out def init_hidden(self, batch_s): return torch.zeros(batch_s, self.hidden_size) class RNNSTSPConfig: def __init__(self, in_size, h_size): self.n_input = in_size self.n_hidden = h_size self.exc_inh_prop = 0.8 self.balance_EI = True self.synapse_config = 'exc_dep_inh_fac' self.membrane_time_constant = 100 self.tau_fast = 200 self.tau_slow = 1500 self.dt = 10 self.dt_sec = self.dt / 1000 self.trial_length = 2500 self.num_time_steps = self.trial_length // self.dt if self.exc_inh_prop < 1: self.EI = True else: self.EI = False self.num_exc_units = int(np.round(self.n_hidden * self.exc_inh_prop)) self.num_inh_units = self.n_hidden - self.num_exc_units self.EI_list = np.ones(self.n_hidden, dtype=np.float32) self.EI_list[-self.num_inh_units:] = -1.0 self.ind_inh = np.where(self.EI_list == -1)[0] self.EI_matrix = np.diag(self.EI_list) self.alpha_neuron = np.float32(self.dt) / self.membrane_time_constant self.h0 = 0.1 * np.ones((1, self.n_hidden), dtype=np.float32) self.w_in0 = initialize([self.n_input, self.n_hidden], shape=0.2, scale=1.0) if self.EI: self.w_rnn0 = initialize([self.n_hidden, self.n_hidden]) if self.balance_EI: self.w_rnn0[:, self.ind_inh] = initialize([self.n_hidden, self.num_inh_units], shape=0.2, scale=1.0) self.w_rnn0[self.ind_inh, :] = initialize([self. num_inh_units, self.n_hidden], shape=0.2, scale=1.0) else: self.w_rnn0 = 0.54 * np.eye(self.n_hidden) self.b_rnn0 = np.zeros(self.n_hidden, dtype=np.float32) self.w_rnn_mask = np.ones_like(self.w_rnn0) if self.EI: self.w_rnn_mask = np.ones((self.n_hidden, self.n_hidden), dtype =np.float32) - np.eye(self.n_hidden, dtype=np.float32) self.w_rnn0 *= self.w_rnn_mask synaptic_configurations = {'full': [('facilitating' if i % 2 == 0 else 'depressing') for i in range(self.n_hidden)], 'fac': [ 'facilitating' for i in range(self.n_hidden)], 'dep': [ 'depressing' for i in range(self.n_hidden)], 'exc_fac': [( 'facilitating' if self.EI_list[i] == 1 else 'static') for i in range(self.n_hidden)], 'exc_dep': [('depressing' if self. EI_list[i] == 1 else 'static') for i in range(self.n_hidden)], 'inh_fac': [('facilitating' if self.EI_list[i] == -1 else 'static') for i in range(self.n_hidden)], 'inh_dep': [( 'depressing' if self.EI_list[i] == -1 else 'static') for i in range(self.n_hidden)], 'exc_dep_inh_fac': [('depressing' if self.EI_list[i] == 1 else 'facilitating') for i in range(self. n_hidden)]} self.alpha_stf = np.ones((1, self.n_hidden), dtype=np.float32) self.alpha_std = np.ones((1, self.n_hidden), dtype=np.float32) self.U = np.ones((1, self.n_hidden), dtype=np.float32) self.syn_x_init = np.ones((1, self.n_hidden), dtype=np.float32) self.syn_u_init = 0.3 * np.ones((1, self.n_hidden), dtype=np.float32) self.dynamic_synapse = np.ones((1, self.n_hidden), dtype=np.float32) for i in range(self.n_hidden): if self.synapse_config not in synaptic_configurations.keys(): self.dynamic_synapse[0, i] = 0 elif synaptic_configurations[self.synapse_config][i ] == 'facilitating': self.alpha_stf[0, i] = self.dt / self.tau_slow self.alpha_std[0, i] = self.dt / self.tau_fast self.U[0, i] = 0.15 self.syn_u_init[0, i] = self.U[0, i] self.dynamic_synapse[0, i] = 1 elif synaptic_configurations[self.synapse_config][i ] == 'depressing': self.alpha_stf[0, i] = self.dt / self.tau_fast self.alpha_std[0, i] = self.dt / self.tau_slow self.U[0, i] = 0.45 self.syn_u_init[0, i] = self.U[0, i] self.dynamic_synapse[0, i] = 1 class RNNSTSPCell(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='relu'): super(RNNSTSPCell, self).__init__() self.syncfg = RNNSTSPConfig(input_size, hidden_size) self.input_size = self.syncfg.n_input self.hidden_size = self.syncfg.n_hidden self.nonlinearity = nonlinearity self.weight_ih = nn.Parameter(torch.from_numpy(self.syncfg.w_in0)) self.weight_hh = nn.Parameter(torch.from_numpy(self.syncfg.w_rnn0)) self.bias = nn.Parameter(torch.from_numpy(self.syncfg.b_rnn0)) self.EI = self.syncfg.EI if self.EI: self.EI_matrix = torch.from_numpy(self.syncfg.EI_matrix) self.w_rnn_mask = torch.from_numpy(self.syncfg.w_rnn_mask) self.alpha_stf = torch.from_numpy(self.syncfg.alpha_stf) self.alpha_std = torch.from_numpy(self.syncfg.alpha_std) self.U = torch.from_numpy(self.syncfg.U) self.dynamic_synapse = torch.from_numpy(self.syncfg.dynamic_synapse) if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def forward(self, inp, hidden_in): h_in, syn_x, syn_u = hidden_in syn_x = syn_x + (self.alpha_std * (1.0 - syn_x) - self.syncfg. dt_sec * syn_u * syn_x * h_in) * self.dynamic_synapse syn_u = syn_u + (self.alpha_stf * (self.U - syn_u) + self.syncfg. dt_sec * self.U * (1.0 - syn_u) * h_in) * self.dynamic_synapse syn_x = torch.clamp(syn_x, min=0.0, max=1.0) syn_u = torch.clamp(syn_u, min=0.0, max=1.0) h_post = syn_u * syn_x * h_in if self.EI: eff_rnn_w = self.w_rnn_mask * torch.matmul(self.EI_matrix, F. relu(self.weight_hh)) else: eff_rnn_w = self.w_rnn_mask * self.weight_hh h_out = h_in * (1 - self.syncfg.alpha_neuron ) + self.syncfg.alpha_neuron * self.act(torch.matmul(inp, F. relu(self.weight_ih)) + torch.matmul(h_post, eff_rnn_w) + self.bias ) hidden_out = h_out, syn_x, syn_u return hidden_out def init_hidden(self, batch_s): h_out_init = torch.from_numpy(self.syncfg.h0).repeat(batch_s, 1) syn_x_init = torch.from_numpy(self.syncfg.syn_x_init).repeat(batch_s, 1 ) syn_u_init = torch.from_numpy(self.syncfg.syn_u_init).repeat(batch_s, 1 ) hidden_init = h_out_init, syn_x_init, syn_u_init return hidden_init class RNNModel(nn.Module): def __init__(self, input_size, hidden_size, output_size, rnn_type): super(RNNModel, self).__init__() assert rnn_type in ['plainRNN', 'VanillaRNN', 'CTRNN', 'LSTM', 'GRU', 'RNNSTSP'], 'Given RNN type must be implemented' self.hidden_size = hidden_size self.rnn_type = rnn_type if self.rnn_type == 'plainRNN': self.rnn = nn.RNNCell(input_size, hidden_size) elif self.rnn_type == 'VanillaRNN': self.rnn = VanillaRNNCell(input_size, hidden_size) elif self.rnn_type == 'CTRNN': self.rnn = VanillaRNNCell(input_size, hidden_size, ct=True) elif self.rnn_type == 'LSTM': self.rnn = nn.LSTMCell(input_size, hidden_size) elif self.rnn_type == 'GRU': self.rnn = nn.GRUCell(input_size, hidden_size) elif self.rnn_type == 'RNNSTSP': self.rnn = RNNSTSPCell(input_size, hidden_size) else: raise NotImplementedError('RNN cell not implemented') self.out_layer = nn.Linear(hidden_size, output_size) def forward(self, inp, hidden_in): hid_out = self.rnn(inp, hidden_in) if self.rnn_type in ['LSTM', 'RNNSTSP']: rnn_out = hid_out[0] else: rnn_out = hid_out otp = self.out_layer(rnn_out) return otp, hid_out def init_hidden(self, batch_s): if self.rnn_type == 'LSTM': init_hid = torch.zeros(batch_s, self.hidden_size), torch.zeros( batch_s, self.hidden_size) elif self.rnn_type in ['plainRNN', 'GRU']: init_hid = torch.zeros(batch_s, self.hidden_size) elif self.rnn_type in ['VanillaRNN', 'CTRNN', 'RNNSTSP']: init_hid = self.rnn.init_hidden(batch_s) else: raise NotImplementedError('RNN init not implemented') return init_hid def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'input_size': 4, 'hidden_size': 4, 'output_size': 4, 'rnn_type': 'plainRNN'}]
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 numpy as np 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_add_tanh_0(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) tmp4 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp7 = libdevice.tanh(tmp6) tl.store(in_out_ptr0 + x2, tmp7, 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, 4), (4, 1)) assert_size_stride(primals_5, (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, reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf0) del primals_4 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_1, reinterpret_tensor(primals_3, (4, 4), (1, 4), 0), out=buf1) del primals_3 buf2 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_add_tanh_0[grid(16)](buf2, primals_6, buf1, primals_5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_5 del primals_6 buf3 = buf1 del buf1 extern_kernels.addmm(primals_8, buf2, reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf3) del primals_8 return buf3, buf2, primals_1, primals_2, buf2, primals_7 def initialize(dims, connection_prob=1.0, shape=0.1, scale=1.0): w = np.random.gamma(shape, scale, size=dims) w *= np.random.rand(*dims) < connection_prob return np.float32(w) class VanillaRNNCell(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='tanh', ct=False): super(VanillaRNNCell, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.nonlinearity = nonlinearity self.ct = ct self.weight_ih = nn.Parameter(torch.zeros((input_size, hidden_size))) self.weight_hh = nn.Parameter(torch.zeros((hidden_size, hidden_size))) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.reset_parameters() if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def reset_parameters(self): stdv = 1.0 / math.sqrt(self.hidden_size) for weight in self.parameters(): nn.init.uniform_(weight, -stdv, stdv) def forward(self, inp, hidden_in): if not self.ct: hidden_out = self.act(torch.matmul(inp, self.weight_ih) + torch .matmul(hidden_in, self.weight_hh) + self.bias) else: alpha = 0.1 hidden_out = (1 - alpha) * hidden_in + alpha * self.act(torch. matmul(inp, self.weight_ih) + torch.matmul(hidden_in, self. weight_hh) + self.bias) return hidden_out def init_hidden(self, batch_s): return torch.zeros(batch_s, self.hidden_size) class RNNSTSPConfig: def __init__(self, in_size, h_size): self.n_input = in_size self.n_hidden = h_size self.exc_inh_prop = 0.8 self.balance_EI = True self.synapse_config = 'exc_dep_inh_fac' self.membrane_time_constant = 100 self.tau_fast = 200 self.tau_slow = 1500 self.dt = 10 self.dt_sec = self.dt / 1000 self.trial_length = 2500 self.num_time_steps = self.trial_length // self.dt if self.exc_inh_prop < 1: self.EI = True else: self.EI = False self.num_exc_units = int(np.round(self.n_hidden * self.exc_inh_prop)) self.num_inh_units = self.n_hidden - self.num_exc_units self.EI_list = np.ones(self.n_hidden, dtype=np.float32) self.EI_list[-self.num_inh_units:] = -1.0 self.ind_inh = np.where(self.EI_list == -1)[0] self.EI_matrix = np.diag(self.EI_list) self.alpha_neuron = np.float32(self.dt) / self.membrane_time_constant self.h0 = 0.1 * np.ones((1, self.n_hidden), dtype=np.float32) self.w_in0 = initialize([self.n_input, self.n_hidden], shape=0.2, scale=1.0) if self.EI: self.w_rnn0 = initialize([self.n_hidden, self.n_hidden]) if self.balance_EI: self.w_rnn0[:, self.ind_inh] = initialize([self.n_hidden, self.num_inh_units], shape=0.2, scale=1.0) self.w_rnn0[self.ind_inh, :] = initialize([self. num_inh_units, self.n_hidden], shape=0.2, scale=1.0) else: self.w_rnn0 = 0.54 * np.eye(self.n_hidden) self.b_rnn0 = np.zeros(self.n_hidden, dtype=np.float32) self.w_rnn_mask = np.ones_like(self.w_rnn0) if self.EI: self.w_rnn_mask = np.ones((self.n_hidden, self.n_hidden), dtype =np.float32) - np.eye(self.n_hidden, dtype=np.float32) self.w_rnn0 *= self.w_rnn_mask synaptic_configurations = {'full': [('facilitating' if i % 2 == 0 else 'depressing') for i in range(self.n_hidden)], 'fac': [ 'facilitating' for i in range(self.n_hidden)], 'dep': [ 'depressing' for i in range(self.n_hidden)], 'exc_fac': [( 'facilitating' if self.EI_list[i] == 1 else 'static') for i in range(self.n_hidden)], 'exc_dep': [('depressing' if self. EI_list[i] == 1 else 'static') for i in range(self.n_hidden)], 'inh_fac': [('facilitating' if self.EI_list[i] == -1 else 'static') for i in range(self.n_hidden)], 'inh_dep': [( 'depressing' if self.EI_list[i] == -1 else 'static') for i in range(self.n_hidden)], 'exc_dep_inh_fac': [('depressing' if self.EI_list[i] == 1 else 'facilitating') for i in range(self. n_hidden)]} self.alpha_stf = np.ones((1, self.n_hidden), dtype=np.float32) self.alpha_std = np.ones((1, self.n_hidden), dtype=np.float32) self.U = np.ones((1, self.n_hidden), dtype=np.float32) self.syn_x_init = np.ones((1, self.n_hidden), dtype=np.float32) self.syn_u_init = 0.3 * np.ones((1, self.n_hidden), dtype=np.float32) self.dynamic_synapse = np.ones((1, self.n_hidden), dtype=np.float32) for i in range(self.n_hidden): if self.synapse_config not in synaptic_configurations.keys(): self.dynamic_synapse[0, i] = 0 elif synaptic_configurations[self.synapse_config][i ] == 'facilitating': self.alpha_stf[0, i] = self.dt / self.tau_slow self.alpha_std[0, i] = self.dt / self.tau_fast self.U[0, i] = 0.15 self.syn_u_init[0, i] = self.U[0, i] self.dynamic_synapse[0, i] = 1 elif synaptic_configurations[self.synapse_config][i ] == 'depressing': self.alpha_stf[0, i] = self.dt / self.tau_fast self.alpha_std[0, i] = self.dt / self.tau_slow self.U[0, i] = 0.45 self.syn_u_init[0, i] = self.U[0, i] self.dynamic_synapse[0, i] = 1 class RNNSTSPCell(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='relu'): super(RNNSTSPCell, self).__init__() self.syncfg = RNNSTSPConfig(input_size, hidden_size) self.input_size = self.syncfg.n_input self.hidden_size = self.syncfg.n_hidden self.nonlinearity = nonlinearity self.weight_ih = nn.Parameter(torch.from_numpy(self.syncfg.w_in0)) self.weight_hh = nn.Parameter(torch.from_numpy(self.syncfg.w_rnn0)) self.bias = nn.Parameter(torch.from_numpy(self.syncfg.b_rnn0)) self.EI = self.syncfg.EI if self.EI: self.EI_matrix = torch.from_numpy(self.syncfg.EI_matrix) self.w_rnn_mask = torch.from_numpy(self.syncfg.w_rnn_mask) self.alpha_stf = torch.from_numpy(self.syncfg.alpha_stf) self.alpha_std = torch.from_numpy(self.syncfg.alpha_std) self.U = torch.from_numpy(self.syncfg.U) self.dynamic_synapse = torch.from_numpy(self.syncfg.dynamic_synapse) if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def forward(self, inp, hidden_in): h_in, syn_x, syn_u = hidden_in syn_x = syn_x + (self.alpha_std * (1.0 - syn_x) - self.syncfg. dt_sec * syn_u * syn_x * h_in) * self.dynamic_synapse syn_u = syn_u + (self.alpha_stf * (self.U - syn_u) + self.syncfg. dt_sec * self.U * (1.0 - syn_u) * h_in) * self.dynamic_synapse syn_x = torch.clamp(syn_x, min=0.0, max=1.0) syn_u = torch.clamp(syn_u, min=0.0, max=1.0) h_post = syn_u * syn_x * h_in if self.EI: eff_rnn_w = self.w_rnn_mask * torch.matmul(self.EI_matrix, F. relu(self.weight_hh)) else: eff_rnn_w = self.w_rnn_mask * self.weight_hh h_out = h_in * (1 - self.syncfg.alpha_neuron ) + self.syncfg.alpha_neuron * self.act(torch.matmul(inp, F. relu(self.weight_ih)) + torch.matmul(h_post, eff_rnn_w) + self.bias ) hidden_out = h_out, syn_x, syn_u return hidden_out def init_hidden(self, batch_s): h_out_init = torch.from_numpy(self.syncfg.h0).repeat(batch_s, 1) syn_x_init = torch.from_numpy(self.syncfg.syn_x_init).repeat(batch_s, 1 ) syn_u_init = torch.from_numpy(self.syncfg.syn_u_init).repeat(batch_s, 1 ) hidden_init = h_out_init, syn_x_init, syn_u_init return hidden_init class RNNModelNew(nn.Module): def __init__(self, input_size, hidden_size, output_size, rnn_type): super(RNNModelNew, self).__init__() assert rnn_type in ['plainRNN', 'VanillaRNN', 'CTRNN', 'LSTM', 'GRU', 'RNNSTSP'], 'Given RNN type must be implemented' self.hidden_size = hidden_size self.rnn_type = rnn_type if self.rnn_type == 'plainRNN': self.rnn = nn.RNNCell(input_size, hidden_size) elif self.rnn_type == 'VanillaRNN': self.rnn = VanillaRNNCell(input_size, hidden_size) elif self.rnn_type == 'CTRNN': self.rnn = VanillaRNNCell(input_size, hidden_size, ct=True) elif self.rnn_type == 'LSTM': self.rnn = nn.LSTMCell(input_size, hidden_size) elif self.rnn_type == 'GRU': self.rnn = nn.GRUCell(input_size, hidden_size) elif self.rnn_type == 'RNNSTSP': self.rnn = RNNSTSPCell(input_size, hidden_size) else: raise NotImplementedError('RNN cell not implemented') self.out_layer = nn.Linear(hidden_size, output_size) def init_hidden(self, batch_s): if self.rnn_type == 'LSTM': init_hid = torch.zeros(batch_s, self.hidden_size), torch.zeros( batch_s, self.hidden_size) elif self.rnn_type in ['plainRNN', 'GRU']: init_hid = torch.zeros(batch_s, self.hidden_size) elif self.rnn_type in ['VanillaRNN', 'CTRNN', 'RNNSTSP']: init_hid = self.rnn.init_hidden(batch_s) else: raise NotImplementedError('RNN init not implemented') return init_hid def forward(self, input_0, input_1): primals_1 = self.rnn.weight_ih primals_2 = self.rnn.weight_hh primals_5 = self.rnn.bias_ih primals_6 = self.rnn.bias_hh primals_3 = self.out_layer.weight primals_8 = self.out_layer.bias primals_4 = 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], output[1]
YuXie96/time
RNNModel
false
1,279
[ "MIT" ]
0
8539d55d2449c712f54331b06720ab7faf3593df
https://github.com/YuXie96/time/tree/8539d55d2449c712f54331b06720ab7faf3593df
NHDUnitV2
import torch import torch.nn as nn class NHDUnitV2(nn.Module): def __init__(self, in_channels, hidden_channels, *args, **kwargs): super(NHDUnitV2, self).__init__() self.in_channels = in_channels self.hidden_channels = hidden_channels self._build() def _build(self): self.conv_1 = nn.Conv2d(self.in_channels, self.hidden_channels, 1) self.conv_2 = nn.Conv2d(self.hidden_channels, self.hidden_channels, 3, stride=1, padding=1) self.conv_trans_1 = nn.Conv2d(self.hidden_channels, self. hidden_channels, 1) self.conv_trans_2 = nn.Conv2d(self.hidden_channels, 1, 1) self.conv_atmos = nn.Conv2d(self.hidden_channels, self.in_channels, 1) self.relu = nn.ReLU() self.sigmoid = nn.Sigmoid() self.global_avg = nn.AdaptiveAvgPool2d((1, 1)) def forward(self, inp): feat = self.relu(self.conv_2(self.relu(self.conv_1(inp)))) trans = self.sigmoid(self.conv_trans_2(self.relu(self.conv_trans_1( feat)))) atmos = self.sigmoid(self.conv_atmos(self.global_avg(feat))) out = inp * trans + (1 - trans) * atmos return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'hidden_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._inductor.runtime import triton_helpers 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_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 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') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x3, tmp4, xmask) @triton.jit def triton_per_fused_convolution_mean_relu_1(in_out_ptr0, in_out_ptr1, 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) r2 = rindex x3 = xindex x0 = xindex % 4 tmp0 = tl.load(in_out_ptr0 + (r2 + 16 * x3), xmask, other=0.0) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1, 1], 0, tl.int32) tmp4 = triton_helpers.maximum(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 tl.store(in_out_ptr0 + (r2 + 16 * x3), tmp4, xmask) tl.debug_barrier() tl.store(in_out_ptr1 + x3, tmp10, xmask) @triton.jit def triton_poi_fused_convolution_2(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 x0 = xindex tmp0 = tl.load(in_out_ptr0 + x0, xmask) tmp1 = tl.load(in_ptr0 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = tmp0 + tmp2 tl.store(in_out_ptr0 + x0, tmp3, xmask) @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) @triton.jit def triton_poi_fused_add_mul_rsub_sigmoid_4(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 x0 = xindex % 16 x2 = xindex // 64 x4 = xindex // 16 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + (x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp2 = tl.sigmoid(tmp1) tmp3 = tmp0 * tmp2 tmp4 = 1.0 tmp5 = tmp4 - tmp2 tmp7 = tl.sigmoid(tmp6) tmp8 = tmp5 * tmp7 tmp9 = tmp3 + tmp8 tl.store(out_ptr0 + x3, tmp9, 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) = 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, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (1, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_9, (1,), (1,)) assert_size_stride(primals_10, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_11, (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, 4, 4, 4), (64, 16, 4, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(256)](buf1, primals_2, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4, 4), (64, 16, 4, 1)) buf3 = buf2 del buf2 buf8 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 16, 16), torch.float32) buf9 = reinterpret_tensor(buf8, (4, 4, 1, 1), (4, 1, 1, 1), 0) del buf8 triton_per_fused_convolution_mean_relu_1[grid(16)](buf3, buf9, primals_5, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del primals_5 buf4 = extern_kernels.convolution(buf3, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 4, 4, 4), (64, 16, 4, 1)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_0[grid(256)](buf5, primals_7, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_7 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 1, 4, 4), (16, 16, 4, 1)) buf7 = buf6 del buf6 triton_poi_fused_convolution_2[grid(64)](buf7, primals_9, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_9 buf10 = extern_kernels.convolution(buf9, primals_10, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf10, (4, 4, 1, 1), (4, 1, 1, 1)) buf11 = buf10 del buf10 triton_poi_fused_convolution_3[grid(16)](buf11, primals_11, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_11 buf12 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_mul_rsub_sigmoid_4[grid(256)](primals_3, buf7, buf11, buf12, 256, XBLOCK=128, num_warps=4, num_stages=1) return (buf12, primals_1, primals_3, primals_4, primals_6, primals_8, primals_10, buf1, buf3, buf5, buf7, buf9, buf11) class NHDUnitV2New(nn.Module): def __init__(self, in_channels, hidden_channels, *args, **kwargs): super(NHDUnitV2New, self).__init__() self.in_channels = in_channels self.hidden_channels = hidden_channels self._build() def _build(self): self.conv_1 = nn.Conv2d(self.in_channels, self.hidden_channels, 1) self.conv_2 = nn.Conv2d(self.hidden_channels, self.hidden_channels, 3, stride=1, padding=1) self.conv_trans_1 = nn.Conv2d(self.hidden_channels, self. hidden_channels, 1) self.conv_trans_2 = nn.Conv2d(self.hidden_channels, 1, 1) self.conv_atmos = nn.Conv2d(self.hidden_channels, self.in_channels, 1) self.relu = nn.ReLU() self.sigmoid = nn.Sigmoid() self.global_avg = nn.AdaptiveAvgPool2d((1, 1)) def forward(self, input_0): primals_1 = self.conv_1.weight primals_2 = self.conv_1.bias primals_4 = self.conv_2.weight primals_5 = self.conv_2.bias primals_6 = self.conv_trans_1.weight primals_7 = self.conv_trans_1.bias primals_8 = self.conv_trans_2.weight primals_9 = self.conv_trans_2.bias primals_10 = self.conv_atmos.weight primals_11 = self.conv_atmos.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]) return output[0]
YiqunChen1999/NTIRE2021NHDehazing
NHDUnitV2
false
1,280
[ "MIT" ]
0
3341ae561ac8caff7f40ddf6d4408032a28ff13c
https://github.com/YiqunChen1999/NTIRE2021NHDehazing/tree/3341ae561ac8caff7f40ddf6d4408032a28ff13c
EmbeddingLayer
import torch import torch.nn.functional class EmbeddingLayer(torch.nn.Module): """Attention layer.""" def __init__(self, feature_number: 'int'): """Initialize the relational embedding layer. :param feature_number: Number of features. """ super().__init__() self.weights = torch.nn.Parameter(torch.zeros(feature_number, feature_number)) torch.nn.init.xavier_uniform_(self.weights) def forward(self, left_representations: 'torch.FloatTensor', right_representations: 'torch.FloatTensor', alpha_scores: 'torch.FloatTensor'): """ Make a forward pass with the drug representations. :param left_representations: Left side drug representations. :param right_representations: Right side drug representations. :param alpha_scores: Attention scores. :returns: Positive label scores vector. """ attention = torch.nn.functional.normalize(self.weights, dim=-1) left_representations = torch.nn.functional.normalize( left_representations, dim=-1) right_representations = torch.nn.functional.normalize( right_representations, dim=-1) attention = attention.view(-1, self.weights.shape[0], self.weights. shape[1]) scores = alpha_scores * (left_representations @ attention @ right_representations.transpose(-2, -1)) scores = scores.sum(dim=(-2, -1)).view(-1, 1) return 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 [[], {'feature_number': 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.nn.functional 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 x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp2 = tmp1 * tmp1 tmp4 = tmp3 * tmp3 tmp5 = tmp2 + tmp4 tmp7 = tmp6 * tmp6 tmp8 = tmp5 + tmp7 tmp10 = tmp9 * tmp9 tmp11 = tmp8 + tmp10 tmp12 = libdevice.sqrt(tmp11) tmp13 = 1e-12 tmp14 = triton_helpers.maximum(tmp12, tmp13) tmp15 = tmp0 / tmp14 tl.store(out_ptr0 + x2, tmp15, xmask) @triton.jit def triton_poi_fused_div_1(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 x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp2 = tmp1 * tmp1 tmp4 = tmp3 * tmp3 tmp5 = tmp2 + tmp4 tmp7 = tmp6 * tmp6 tmp8 = tmp5 + tmp7 tmp10 = tmp9 * tmp9 tmp11 = tmp8 + tmp10 tmp12 = libdevice.sqrt(tmp11) tmp13 = 1e-12 tmp14 = triton_helpers.maximum(tmp12, tmp13) tmp15 = tmp0 / tmp14 tl.store(out_ptr0 + x2, tmp15, xmask) @triton.jit def triton_per_fused_mul_sum_2(in_ptr0, in_ptr1, out_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 = 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] tl.store(out_ptr0 + x0, tmp6, xmask) def call(args): primals_1, primals_2, primals_3, primals_4 = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (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)](primals_2, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused_div_1[grid(16)](primals_1, buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = 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(buf1, (16, 4, 4), (0, 4, 1), 0), out=buf2) buf3 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_div_0[grid(256)](primals_3, buf3, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_3 buf4 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(buf2, reinterpret_tensor(buf3, (16, 4, 4), (16, 1, 4), 0), out=buf4) del buf2 buf5 = buf1 del buf1 triton_per_fused_mul_sum_2[grid(16)](primals_4, buf4, buf5, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del buf4 return reinterpret_tensor(buf5, (16, 1), (1, 1), 0 ), primals_1, primals_4, reinterpret_tensor(buf3, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(buf0, (16, 4, 4), (16, 1, 4), 0) class EmbeddingLayerNew(torch.nn.Module): """Attention layer.""" def __init__(self, feature_number: 'int'): """Initialize the relational embedding layer. :param feature_number: Number of features. """ super().__init__() self.weights = torch.nn.Parameter(torch.zeros(feature_number, feature_number)) torch.nn.init.xavier_uniform_(self.weights) def forward(self, input_0, input_1, input_2): primals_1 = self.weights primals_2 = input_0 primals_3 = input_1 primals_4 = input_2 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]
YuWVandy/chemicalx
EmbeddingLayer
false
1,281
[ "Apache-2.0" ]
0
c02f979a502409c26700e6d5a1b2e6c0aa77e64c
https://github.com/YuWVandy/chemicalx/tree/c02f979a502409c26700e6d5a1b2e6c0aa77e64c
VanillaRNNCell
import math import torch import torch.nn as nn import torch.nn.functional as F class VanillaRNNCell(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='tanh', ct=False): super(VanillaRNNCell, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.nonlinearity = nonlinearity self.ct = ct self.weight_ih = nn.Parameter(torch.zeros((input_size, hidden_size))) self.weight_hh = nn.Parameter(torch.zeros((hidden_size, hidden_size))) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.reset_parameters() if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def reset_parameters(self): stdv = 1.0 / math.sqrt(self.hidden_size) for weight in self.parameters(): nn.init.uniform_(weight, -stdv, stdv) def forward(self, inp, hidden_in): if not self.ct: hidden_out = self.act(torch.matmul(inp, self.weight_ih) + torch .matmul(hidden_in, self.weight_hh) + self.bias) else: alpha = 0.1 hidden_out = (1 - alpha) * hidden_in + alpha * self.act(torch. matmul(inp, self.weight_ih) + torch.matmul(hidden_in, self. weight_hh) + self.bias) return hidden_out def init_hidden(self, batch_s): return torch.zeros(batch_s, self.hidden_size) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, '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 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_add_tanh_0(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 + x2, xmask) tmp3 = tl.load(in_ptr1 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = libdevice.tanh(tmp4) tl.store(in_out_ptr0 + x2, tmp5, 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, 1)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 4, 4, 4), (64, 16, 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_2, (64, 4), (4, 1), 0), primals_1, out=buf0) del primals_1 buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_4, (64, 4), (4, 1), 0), primals_3, out=buf1) del primals_3 buf2 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_tanh_0[grid(256)](buf2, buf1, primals_5, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf1 del primals_5 return buf2, buf2, reinterpret_tensor(primals_4, (4, 64), (1, 4), 0 ), reinterpret_tensor(primals_2, (4, 64), (1, 4), 0) class VanillaRNNCellNew(nn.Module): def __init__(self, input_size, hidden_size, nonlinearity='tanh', ct=False): super(VanillaRNNCellNew, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.nonlinearity = nonlinearity self.ct = ct self.weight_ih = nn.Parameter(torch.zeros((input_size, hidden_size))) self.weight_hh = nn.Parameter(torch.zeros((hidden_size, hidden_size))) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.reset_parameters() if self.nonlinearity == 'tanh': self.act = F.tanh elif self.nonlinearity == 'relu': self.act = F.relu else: raise RuntimeError('Unknown nonlinearity: {}'.format(self. nonlinearity)) def reset_parameters(self): stdv = 1.0 / math.sqrt(self.hidden_size) for weight in self.parameters(): nn.init.uniform_(weight, -stdv, stdv) def init_hidden(self, batch_s): return torch.zeros(batch_s, self.hidden_size) def forward(self, input_0, input_1): primals_1 = self.weight_ih primals_3 = self.weight_hh primals_5 = self.bias primals_2 = input_0 primals_4 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
YuXie96/time
VanillaRNNCell
false
1,282
[ "MIT" ]
0
8539d55d2449c712f54331b06720ab7faf3593df
https://github.com/YuXie96/time/tree/8539d55d2449c712f54331b06720ab7faf3593df
SpatialAttention
import torch import torch.nn as nn class SpatialAttention(nn.Module): def __init__(self, kernel_size=7): super(SpatialAttention, self).__init__() assert kernel_size in (3, 7), 'kernel size must be 3 or 7' padding = 3 if kernel_size == 7 else 1 self.conv1 = nn.Conv2d(2, 1, kernel_size, padding=padding, bias=False) self.sigmoid = nn.Sigmoid() def forward(self, x): residual = x avg_out = torch.mean(x, dim=1, keepdim=True) max_out, _ = torch.max(x, dim=1, keepdim=True) x = torch.cat([avg_out, max_out], dim=1) x = self.conv1(x) return self.sigmoid(x) * residual def get_inputs(): return [torch.rand([4, 4, 4, 4])] 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 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_cat_0(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 x1 = xindex // 16 % 2 x0 = xindex % 16 x2 = xindex // 32 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 + 64 * x2), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp6 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp7 = tmp5 + tmp6 tmp8 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp9 = tmp7 + tmp8 tmp10 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp11 = tmp9 + tmp10 tmp12 = 4.0 tmp13 = tmp11 / tmp12 tmp14 = tl.full(tmp13.shape, 0.0, tmp13.dtype) tmp15 = tl.where(tmp4, tmp13, tmp14) tmp16 = tmp0 >= tmp3 tl.full([1], 2, tl.int64) tmp19 = tl.load(in_ptr0 + (x0 + 64 * x2), tmp16 & xmask, eviction_policy='evict_last', other=0.0) tmp20 = tl.load(in_ptr0 + (16 + x0 + 64 * x2), tmp16 & xmask, eviction_policy='evict_last', other=0.0) tmp21 = triton_helpers.maximum(tmp19, tmp20) tmp22 = tl.load(in_ptr0 + (32 + x0 + 64 * x2), tmp16 & xmask, eviction_policy='evict_last', other=0.0) tmp23 = triton_helpers.maximum(tmp21, tmp22) tmp24 = tl.load(in_ptr0 + (48 + x0 + 64 * x2), tmp16 & xmask, eviction_policy='evict_last', other=0.0) tmp25 = triton_helpers.maximum(tmp23, tmp24) tmp26 = tl.full(tmp25.shape, 0.0, tmp25.dtype) tmp27 = tl.where(tmp16, tmp25, tmp26) tmp28 = tl.where(tmp4, tmp15, tmp27) tl.store(out_ptr0 + x3, tmp28, xmask) @triton.jit def triton_poi_fused_mul_sigmoid_1(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 % 16 x2 = xindex // 64 x3 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr1 + x3, xmask) tmp1 = tl.sigmoid(tmp0) tmp3 = tmp1 * tmp2 tl.store(out_ptr0 + x3, tmp3, 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, 2, 7, 7), (98, 49, 7, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 2, 4, 4), (32, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(128)](primals_1, buf0, 128, XBLOCK=128, num_warps=4, num_stages=1) buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1, 1), padding=(3, 3), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 1, 4, 4), (16, 16, 4, 1)) buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_mul_sigmoid_1[grid(256)](buf1, primals_1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) return buf2, primals_1, primals_2, buf0, buf1 class SpatialAttentionNew(nn.Module): def __init__(self, kernel_size=7): super(SpatialAttentionNew, self).__init__() assert kernel_size in (3, 7), 'kernel size must be 3 or 7' padding = 3 if kernel_size == 7 else 1 self.conv1 = nn.Conv2d(2, 1, kernel_size, padding=padding, bias=False) self.sigmoid = nn.Sigmoid() def forward(self, input_0): primals_2 = self.conv1.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0]
YuanZi1501040205/Ice-detection-for-smart-track-heating-with-normal-only-self-supervised-learning
SpatialAttention
false
1,283
[ "MIT" ]
0
ac7603dc27cf1cc9ce29cfae6c525dd5dbbcdd83
https://github.com/YuanZi1501040205/Ice-detection-for-smart-track-heating-with-normal-only-self-supervised-learning/tree/ac7603dc27cf1cc9ce29cfae6c525dd5dbbcdd83
ResidualUnit
import torch import torch.nn as nn def defaultConv(inChannels, outChannels, kernelSize, bias=True): return nn.Conv2d(inChannels, outChannels, kernelSize, padding= kernelSize // 2, bias=bias) class ResidualUnit(nn.Module): def __init__(self, inChannel, outChannel, reScale, kernelSize=1, bias=True ): super().__init__() self.reduction = defaultConv(inChannel, outChannel // 2, kernelSize, bias) self.expansion = defaultConv(outChannel // 2, inChannel, kernelSize, bias) self.lamRes = reScale[0] self.lamX = reScale[1] def forward(self, x): res = self.reduction(x) res = self.lamRes * self.expansion(res) x = self.lamX * x + res return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'inChannel': 4, 'outChannel': 4, 'reScale': [4, 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 @triton.jit def triton_poi_fused_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 128 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 2 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) @triton.jit def triton_poi_fused_add_convolution_mul_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 x3 = xindex x1 = xindex // 16 % 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp3 = tl.load(in_out_ptr0 + x3, xmask) tmp4 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp1 = 4.0 tmp2 = tmp0 * tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp5 * tmp1 tmp7 = tmp2 + tmp6 tl.store(in_out_ptr0 + x3, tmp7, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (2, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_2, (2,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (4, 2, 1, 1), (2, 1, 1, 1)) assert_size_stride(primals_5, (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, 2, 4, 4), (32, 16, 4, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(128)](buf1, primals_2, 128, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 4, 4), (64, 16, 4, 1)) buf3 = buf2 del buf2 triton_poi_fused_add_convolution_mul_1[grid(256)](buf3, primals_3, primals_5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 return buf3, primals_1, primals_3, primals_4, buf1 def defaultConv(inChannels, outChannels, kernelSize, bias=True): return nn.Conv2d(inChannels, outChannels, kernelSize, padding= kernelSize // 2, bias=bias) class ResidualUnitNew(nn.Module): def __init__(self, inChannel, outChannel, reScale, kernelSize=1, bias=True ): super().__init__() self.reduction = defaultConv(inChannel, outChannel // 2, kernelSize, bias) self.expansion = defaultConv(outChannel // 2, inChannel, kernelSize, bias) self.lamRes = reScale[0] self.lamX = reScale[1] def forward(self, input_0): primals_1 = self.reduction.weight primals_2 = self.reduction.bias primals_4 = self.expansion.weight primals_5 = self.expansion.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
YingqiLiulll/scrips_for_SR
ResidualUnit
false
1,284
[ "MIT" ]
0
04fa6fdaf157e913d3e2521cd80315a10a2ccedc
https://github.com/YingqiLiulll/scrips_for_SR/tree/04fa6fdaf157e913d3e2521cd80315a10a2ccedc
ClassificationModel
import torch import torch.nn as nn import torch.utils.data.distributed class ClassificationModel(nn.Module): def __init__(self, num_features_in, num_anchors=1, num_classes=80, prior=0.01, feature_size=256): super(ClassificationModel, self).__init__() self.num_classes = num_classes self.num_anchors = num_anchors self.conv1 = nn.Conv2d(num_features_in, feature_size, kernel_size=3, padding=1) self.act1 = nn.ReLU() self.conv2 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act2 = nn.ReLU() self.conv3 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act3 = nn.ReLU() self.conv4 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act4 = nn.ReLU() self.output = nn.Conv2d(feature_size, num_anchors * num_classes, kernel_size=3, padding=1) self.output_act = nn.Sigmoid() def forward(self, x): out = self.conv1(x) out = self.act1(out) out = self.conv2(out) out = self.act2(out) out = self.conv3(out) out = self.act3(out) out = self.conv4(out) out = self.act4(out) out = self.output(out) out = self.output_act(out) out1 = out.permute(0, 2, 3, 1) batch_size, width, height, _channels = out1.shape out2 = out1.view(batch_size, width, height, self.num_anchors, self. num_classes) return out2.contiguous().view(x.shape[0], -1, self.num_classes) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_features_in': 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 import torch.utils.data.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_convolution_relu_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) x3 = xindex x1 = xindex // 16 % 256 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_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 5120 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 80 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) @triton.jit def triton_poi_fused_clone_2(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): ynumel = 64 xnumel = 80 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 % 16 y1 = yindex // 16 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 16 * x2 + 1280 * y1), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.sigmoid(tmp0) tl.store(out_ptr0 + (x2 + 80 * y3), tmp1, xmask & ymask) 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) = args args.clear() assert_size_stride(primals_1, (256, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_2, (256,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_5, (256,), (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, (256, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_9, (256,), (1,)) assert_size_stride(primals_10, (80, 256, 3, 3), (2304, 9, 3, 1)) assert_size_stride(primals_11, (80,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 256, 4, 4), (4096, 16, 4, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(16384)](buf1, primals_2, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 256, 4, 4), (4096, 16, 4, 1)) buf3 = buf2 del buf2 triton_poi_fused_convolution_relu_0[grid(16384)](buf3, primals_5, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 buf4 = extern_kernels.convolution(buf3, primals_6, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 256, 4, 4), (4096, 16, 4, 1)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_0[grid(16384)](buf5, primals_7, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_7 buf6 = extern_kernels.convolution(buf5, primals_8, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 256, 4, 4), (4096, 16, 4, 1)) buf7 = buf6 del buf6 triton_poi_fused_convolution_relu_0[grid(16384)](buf7, primals_9, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_9 buf8 = extern_kernels.convolution(buf7, primals_10, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf8, (4, 80, 4, 4), (1280, 16, 4, 1)) buf9 = buf8 del buf8 triton_poi_fused_convolution_1[grid(5120)](buf9, primals_11, 5120, XBLOCK=128, num_warps=4, num_stages=1) del primals_11 buf10 = empty_strided_cuda((4, 4, 4, 1, 80), (1280, 320, 80, 80, 1), torch.float32) triton_poi_fused_clone_2[grid(64, 80)](buf9, buf10, 64, 80, XBLOCK= 32, YBLOCK=32, num_warps=4, num_stages=1) return (reinterpret_tensor(buf10, (4, 16, 80), (1280, 80, 1), 0), primals_1, primals_3, primals_4, primals_6, primals_8, primals_10, buf1, buf3, buf5, buf7, buf9) class ClassificationModelNew(nn.Module): def __init__(self, num_features_in, num_anchors=1, num_classes=80, prior=0.01, feature_size=256): super(ClassificationModelNew, self).__init__() self.num_classes = num_classes self.num_anchors = num_anchors self.conv1 = nn.Conv2d(num_features_in, feature_size, kernel_size=3, padding=1) self.act1 = nn.ReLU() self.conv2 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act2 = nn.ReLU() self.conv3 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act3 = nn.ReLU() self.conv4 = nn.Conv2d(feature_size, feature_size, kernel_size=3, padding=1) self.act4 = nn.ReLU() self.output = nn.Conv2d(feature_size, num_anchors * num_classes, kernel_size=3, padding=1) self.output_act = nn.Sigmoid() 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.conv4.weight primals_9 = self.conv4.bias primals_10 = self.output.weight primals_11 = self.output.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]) return output[0]
YuBeomGon/pytorch_retina
ClassificationModel
false
1,285
[ "Apache-2.0" ]
0
a1713ecbf99e3cf2f8f5edce3329b808b4f9dee8
https://github.com/YuBeomGon/pytorch_retina/tree/a1713ecbf99e3cf2f8f5edce3329b808b4f9dee8
TopicMemeoryMechanism
import torch import torch.multiprocessing from torch import nn import torch.utils.data class TopicMemeoryMechanism(nn.Module): def __init__(self, topic_num, bow_size, embed_size): super(TopicMemeoryMechanism, self).__init__() self.topic_num = topic_num self.bow_size = bow_size self.embed_size = embed_size self.source_linear = nn.Linear(bow_size, embed_size) self.target_linear = nn.Linear(bow_size, embed_size) self.embed_project = nn.Linear(embed_size, embed_size) self.source_project = nn.Linear(embed_size, embed_size) self.weight_p = nn.Linear(embed_size, 1) self.sigmoid = nn.Sigmoid() self.relu = nn.ReLU(inplace=True) def forward(self, y_embed, topic_word_dist, topic_represent, gamma=0.8): batch_size = y_embed.shape[0] y_features = self.embed_project(y_embed) y_features = y_features.unsqueeze(1).expand(batch_size, self. topic_num, self.embed_size).contiguous() y_features = y_features.view(-1, self.embed_size) source_weight = self.relu(self.source_linear(topic_word_dist)) source_features = self.source_project(source_weight) source_features = source_features.unsqueeze(0).expand(batch_size, self.topic_num, self.embed_size).contiguous() source_features = source_features.view(-1, self.embed_size) p_k_weights = self.sigmoid(self.weight_p(source_features + y_features)) p_k_weights = p_k_weights.view(batch_size, self.topic_num) p_batch = torch.add(gamma * p_k_weights, topic_represent) target_weight = self.relu(self.target_linear(topic_word_dist)) torch.matmul(p_batch, target_weight) return p_batch def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'topic_num': 4, 'bow_size': 4, 'embed_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 import torch.multiprocessing from torch import nn import torch.utils.data 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_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_1(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 x0 = xindex % 4 x1 = xindex // 4 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 4 * (x1 % 4)), xmask) tmp1 = tl.load(in_ptr1 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + (x0 + 4 * (x1 // 4)), xmask) tmp4 = tl.load(in_ptr3 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tl.store(out_ptr0 + x2, tmp6, xmask) @triton.jit def triton_poi_fused_add_mul_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 x0 = xindex % 16 x2 = xindex tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + x2, xmask) tmp1 = tl.sigmoid(tmp0) tmp2 = 0.8 tmp3 = tmp1 * tmp2 tmp5 = tmp3 + tmp4 tl.store(out_ptr0 + x2, tmp5, 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), (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, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) assert_size_stride(primals_9, (1, 4), (4, 1)) assert_size_stride(primals_10, (1,), (1,)) assert_size_stride(primals_11, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_12, (4, 4), (4, 1)) assert_size_stride(primals_13, (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_1, reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf0) del primals_2 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(primals_6, reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = buf1 del buf1 get_raw_stream(0) triton_poi_fused_relu_0[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.mm(buf2, reinterpret_tensor(primals_7, (4, 4), (1, 4 ), 0), out=buf3) buf4 = empty_strided_cuda((16, 4), (4, 1), torch.float32) triton_poi_fused_add_1[grid(64)](buf3, primals_8, buf0, primals_3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf0 del primals_3 del primals_8 buf6 = reinterpret_tensor(buf3, (16, 1), (1, 1), 0) del buf3 extern_kernels.addmm(primals_10, buf4, reinterpret_tensor(primals_9, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf6) del primals_10 buf7 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_mul_2[grid(256)](buf6, primals_11, buf7, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_11 return buf7, primals_1, primals_6, buf2, buf4, buf6, primals_9, primals_7 class TopicMemeoryMechanismNew(nn.Module): def __init__(self, topic_num, bow_size, embed_size): super(TopicMemeoryMechanismNew, self).__init__() self.topic_num = topic_num self.bow_size = bow_size self.embed_size = embed_size self.source_linear = nn.Linear(bow_size, embed_size) self.target_linear = nn.Linear(bow_size, embed_size) self.embed_project = nn.Linear(embed_size, embed_size) self.source_project = nn.Linear(embed_size, embed_size) self.weight_p = nn.Linear(embed_size, 1) self.sigmoid = nn.Sigmoid() self.relu = nn.ReLU(inplace=True) def forward(self, input_0, input_1, input_2): primals_1 = self.source_linear.weight primals_3 = self.source_linear.bias primals_2 = self.target_linear.weight primals_5 = self.target_linear.bias primals_4 = self.embed_project.weight primals_8 = self.embed_project.bias primals_6 = self.source_project.weight primals_13 = self.source_project.bias primals_9 = self.weight_p.weight primals_10 = self.weight_p.bias primals_7 = input_0 primals_12 = input_1 primals_11 = input_2 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]
WuDiDaBinGe/TAKG
TopicMemeoryMechanism
false
1,286
[ "MIT" ]
0
83e608e677a4ee74722d18cb5ef430f4f6c6ad31
https://github.com/WuDiDaBinGe/TAKG/tree/83e608e677a4ee74722d18cb5ef430f4f6c6ad31
Lda2Vec
import torch from torch.nn import functional as F import torch.multiprocessing from torch import nn import torch.utils.data class ContextGate(nn.Module): def __init__(self, vector_dim, topic_dim): super().__init__() assert vector_dim == topic_dim self.fusion_linear = nn.Linear(vector_dim + topic_dim, vector_dim) self.sigmoid = nn.Sigmoid() self.tanh = nn.Tanh() def forward(self, source_vector, other_vector): context_input = torch.cat((source_vector, other_vector), dim=1) context_gate = self.sigmoid(self.fusion_linear(context_input)) context_fusion = context_gate * source_vector + (1.0 - context_gate ) * other_vector return self.tanh(context_fusion) class SingleGate(nn.Module): def __init__(self, vector_dim, topic_dim): super().__init__() assert vector_dim == topic_dim self.fusion_linear = nn.Linear(vector_dim + topic_dim, 1) self.sigmoid = nn.Sigmoid() def forward(self, source_vector, other_vector): context_input = torch.cat((source_vector, other_vector), dim=1) context_gate = self.sigmoid(self.fusion_linear(context_input)) context_fusion = context_gate * source_vector + (1.0 - context_gate ) * other_vector return context_fusion class Lda2Vec(nn.Module): def __init__(self, word_vec_dim, topic_emb_dim, topic_threshold=0.1, mode='gate_all'): super(Lda2Vec, self).__init__() self.mode = mode if mode == 'gate_one': self.fusion_layer = SingleGate(word_vec_dim, topic_emb_dim) elif mode == 'gate_all': assert word_vec_dim == topic_emb_dim self.fusion_layer = ContextGate(word_vec_dim, topic_emb_dim) self.topic_threshold = topic_threshold self.sigmoid = nn.Sigmoid() def forward(self, word_embedding, topic_embedding, topic_dist): topic_dist = F.softmax(topic_dist, dim=1) topic_dist = topic_dist - self.topic_threshold topic_hidden = torch.matmul(topic_dist, topic_embedding) merge_embedding = self.fusion_layer(word_embedding, topic_hidden) return merge_embedding def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'word_vec_dim': 4, 'topic_emb_dim': 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, math as tl_math import torch.multiprocessing from torch import nn import torch.utils.data 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 = 16 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_sub_1(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 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 tmp9 = 0.1 tmp10 = tmp8 - tmp9 tl.store(out_ptr0 + x2, tmp10, 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) @triton.jit def triton_poi_fused_add_mul_rsub_sigmoid_tanh_3(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) tmp2 = tl.load(in_ptr1 + x0, xmask) tmp6 = tl.load(in_ptr2 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp3 = tmp1 * tmp2 tmp4 = 1.0 tmp5 = tmp4 - tmp1 tmp7 = tmp5 * tmp6 tmp8 = tmp3 + 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 = 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, 8), (8, 1)) assert_size_stride(primals_5, (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__softmax_0[grid(16)](primals_1, buf0, 16, XBLOCK= 16, num_warps=1, num_stages=1) del primals_1 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused__softmax_sub_1[grid(16)](buf0, buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = buf0 del buf0 extern_kernels.mm(buf1, primals_2, out=buf2) del primals_2 buf3 = empty_strided_cuda((4, 8), (8, 1), torch.float32) triton_poi_fused_cat_2[grid(32)](primals_3, buf2, buf3, 32, XBLOCK= 32, num_warps=1, num_stages=1) buf4 = buf1 del buf1 extern_kernels.addmm(primals_5, buf3, reinterpret_tensor(primals_4, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf4) del primals_4 del primals_5 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused_add_mul_rsub_sigmoid_tanh_3[grid(16)](buf4, primals_3, buf2, buf5, 16, XBLOCK=16, num_warps=1, num_stages=1) return buf5, primals_3, buf2, buf3, buf4, buf5 class ContextGate(nn.Module): def __init__(self, vector_dim, topic_dim): super().__init__() assert vector_dim == topic_dim self.fusion_linear = nn.Linear(vector_dim + topic_dim, vector_dim) self.sigmoid = nn.Sigmoid() self.tanh = nn.Tanh() def forward(self, source_vector, other_vector): context_input = torch.cat((source_vector, other_vector), dim=1) context_gate = self.sigmoid(self.fusion_linear(context_input)) context_fusion = context_gate * source_vector + (1.0 - context_gate ) * other_vector return self.tanh(context_fusion) class SingleGate(nn.Module): def __init__(self, vector_dim, topic_dim): super().__init__() assert vector_dim == topic_dim self.fusion_linear = nn.Linear(vector_dim + topic_dim, 1) self.sigmoid = nn.Sigmoid() def forward(self, source_vector, other_vector): context_input = torch.cat((source_vector, other_vector), dim=1) context_gate = self.sigmoid(self.fusion_linear(context_input)) context_fusion = context_gate * source_vector + (1.0 - context_gate ) * other_vector return context_fusion class Lda2VecNew(nn.Module): def __init__(self, word_vec_dim, topic_emb_dim, topic_threshold=0.1, mode='gate_all'): super(Lda2VecNew, self).__init__() self.mode = mode if mode == 'gate_one': self.fusion_layer = SingleGate(word_vec_dim, topic_emb_dim) elif mode == 'gate_all': assert word_vec_dim == topic_emb_dim self.fusion_layer = ContextGate(word_vec_dim, topic_emb_dim) self.topic_threshold = topic_threshold self.sigmoid = nn.Sigmoid() def forward(self, input_0, input_1, input_2): primals_4 = self.fusion_layer.fusion_linear.weight primals_5 = self.fusion_layer.fusion_linear.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]
WuDiDaBinGe/TAKG
Lda2Vec
false
1,287
[ "MIT" ]
0
83e608e677a4ee74722d18cb5ef430f4f6c6ad31
https://github.com/WuDiDaBinGe/TAKG/tree/83e608e677a4ee74722d18cb5ef430f4f6c6ad31
PA_UP
import torch import torch.nn as nn import torch.nn.functional as F class PA(nn.Module): """PA is pixel attention""" def __init__(self, nf): super(PA, self).__init__() self.conv = nn.Conv2d(nf, nf, 1) self.sigmoid = nn.Sigmoid() def forward(self, x): y = self.conv(x) y = self.sigmoid(y) out = torch.mul(x, y) return out class PA_UP(nn.Module): def __init__(self, nf, unf, out_nc, scale=4): super(PA_UP, self).__init__() self.upconv1 = nn.Conv2d(nf, unf, 3, 1, 1, bias=True) self.att1 = PA(unf) self.HRconv1 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) if scale == 4: self.upconv2 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) self.att2 = PA(unf) self.HRconv2 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) self.conv_last = nn.Conv2d(unf, out_nc, 3, 1, 1, bias=True) self.lrelu = nn.LeakyReLU(negative_slope=0.2, inplace=True) def forward(self, fea): fea = self.upconv1(F.interpolate(fea, scale_factor=2, mode='nearest')) fea = self.lrelu(self.att1(fea)) fea = self.lrelu(self.HRconv1(fea)) fea = self.upconv2(F.interpolate(fea, scale_factor=2, mode='nearest')) fea = self.lrelu(self.att2(fea)) fea = self.lrelu(self.HRconv2(fea)) fea = self.conv_last(fea) return fea def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'nf': 4, 'unf': 4, 'out_nc': 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 @triton.jit def triton_poi_fused__unsafe_index_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 8 % 8 x0 = xindex % 8 x2 = xindex // 64 x4 = xindex tmp0 = x1 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 * tmp2 tmp4 = tmp3.to(tl.int32) tmp5 = x0 tmp6 = tmp5.to(tl.float32) tmp7 = tmp6 * tmp2 tmp8 = tmp7.to(tl.int32) tmp9 = tl.load(in_ptr0 + (tmp8 + 4 * tmp4 + 16 * x2), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x4, tmp9, xmask) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 64 % 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) @triton.jit def triton_poi_fused_convolution_leaky_relu_mul_sigmoid_2(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 64 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x3, xmask) tmp2 = tmp0 + tmp1 tmp4 = tl.sigmoid(tmp2) tmp5 = tmp3 * tmp4 tmp6 = 0.0 tmp7 = tmp5 > tmp6 tmp8 = 0.2 tmp9 = tmp5 * tmp8 tmp10 = tl.where(tmp7, tmp5, tmp9) tl.store(in_out_ptr0 + x3, tmp2, xmask) tl.store(out_ptr0 + x3, tmp10, xmask) @triton.jit def triton_poi_fused__to_copy_add_arange_mul_3(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 = x0 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 * tmp2 tmp4 = tmp3.to(tl.int32) tl.store(out_ptr0 + x0, tmp4, xmask) @triton.jit def triton_poi_fused__unsafe_index_convolution_leaky_relu_4(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) x1 = xindex // 16 % 16 x0 = xindex % 16 x5 = xindex // 256 x2 = xindex // 256 % 4 x6 = xindex tmp0 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + x0, None, eviction_policy='evict_last') tmp10 = tl.load(in_ptr2 + x2, None, eviction_policy='evict_last') tmp1 = tl.full([XBLOCK], 8, tl.int32) tmp2 = tmp0 + tmp1 tmp3 = tmp0 < 0 tmp4 = tl.where(tmp3, tmp2, tmp0) tmp6 = tmp5 + tmp1 tmp7 = tmp5 < 0 tmp8 = tl.where(tmp7, tmp6, tmp5) tmp9 = tl.load(in_ptr1 + (tmp8 + 8 * tmp4 + 64 * x5), None, eviction_policy='evict_last') tmp11 = tmp9 + tmp10 tmp12 = 0.0 tmp13 = tmp11 > tmp12 tmp14 = 0.2 tmp15 = tmp11 * tmp14 tmp16 = tl.where(tmp13, tmp11, tmp15) tl.store(out_ptr0 + x6, tmp16, None) @triton.jit def triton_poi_fused_convolution_5(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 // 256 % 4 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_leaky_relu_mul_sigmoid_6(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') tmp3 = tl.load(in_ptr1 + x3, None) tmp2 = tmp0 + tmp1 tmp4 = tl.sigmoid(tmp2) tmp5 = tmp3 * tmp4 tmp6 = 0.0 tmp7 = tmp5 > tmp6 tmp8 = 0.2 tmp9 = tmp5 * tmp8 tmp10 = tl.where(tmp7, tmp5, tmp9) tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp10, None) @triton.jit def triton_poi_fused_convolution_leaky_relu_7(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 // 256 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp5 = 0.2 tmp6 = tmp2 * tmp5 tmp7 = tl.where(tmp4, tmp2, tmp6) tl.store(in_out_ptr0 + x3, tmp7, None) @triton.jit def triton_poi_fused_convolution_leaky_relu_leaky_relu_backward_8(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 64 % 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp5 = 0.2 tmp6 = tmp2 * tmp5 tmp7 = tl.where(tmp4, tmp2, tmp6) tmp8 = tmp7 > tmp3 tl.store(out_ptr0 + x3, tmp8, 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) = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_11, (4,), (1,)) assert_size_stride(primals_12, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_13, (4,), (1,)) assert_size_stride(primals_14, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_15, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 8, 8), (256, 64, 8, 1), torch.float32) get_raw_stream(0) triton_poi_fused__unsafe_index_0[grid(1024)](primals_1, buf0, 1024, XBLOCK=256, num_warps=4, num_stages=1) del primals_1 buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 4, 8, 8), (256, 64, 8, 1)) buf2 = buf1 del buf1 triton_poi_fused_convolution_1[grid(1024)](buf2, primals_3, 1024, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 buf3 = extern_kernels.convolution(buf2, primals_4, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 4, 8, 8), (256, 64, 8, 1)) buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 8, 8), (256, 64, 8, 1), torch.float32) triton_poi_fused_convolution_leaky_relu_mul_sigmoid_2[grid(1024)](buf4, primals_5, buf2, buf5, 1024, XBLOCK=128, num_warps=4, num_stages=1) del primals_5 buf6 = extern_kernels.convolution(buf5, primals_6, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 8, 8), (256, 64, 8, 1)) buf7 = empty_strided_cuda((16,), (1,), torch.int64) triton_poi_fused__to_copy_add_arange_mul_3[grid(16)](buf7, 16, XBLOCK=16, num_warps=1, num_stages=1) buf8 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) triton_poi_fused__unsafe_index_convolution_leaky_relu_4[grid(4096)]( buf7, buf6, primals_7, buf8, 4096, XBLOCK=256, num_warps=4, num_stages=1) buf9 = extern_kernels.convolution(buf8, primals_8, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf9, (4, 4, 16, 16), (1024, 256, 16, 1)) buf10 = buf9 del buf9 triton_poi_fused_convolution_5[grid(4096)](buf10, primals_9, 4096, XBLOCK=256, num_warps=4, num_stages=1) del primals_9 buf11 = extern_kernels.convolution(buf10, primals_10, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf11, (4, 4, 16, 16), (1024, 256, 16, 1)) buf12 = buf11 del buf11 buf13 = empty_strided_cuda((4, 4, 16, 16), (1024, 256, 16, 1), torch.float32) triton_poi_fused_convolution_leaky_relu_mul_sigmoid_6[grid(4096)](buf12 , primals_11, buf10, buf13, 4096, XBLOCK=256, num_warps=4, num_stages=1) del primals_11 buf14 = extern_kernels.convolution(buf13, primals_12, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf14, (4, 4, 16, 16), (1024, 256, 16, 1)) buf15 = buf14 del buf14 triton_poi_fused_convolution_leaky_relu_7[grid(4096)](buf15, primals_13, 4096, XBLOCK=256, num_warps=4, num_stages=1) del primals_13 buf16 = extern_kernels.convolution(buf15, primals_14, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf16, (4, 4, 16, 16), (1024, 256, 16, 1)) buf17 = buf16 del buf16 triton_poi_fused_convolution_5[grid(4096)](buf17, primals_15, 4096, XBLOCK=256, num_warps=4, num_stages=1) del primals_15 buf18 = empty_strided_cuda((4, 4, 8, 8), (256, 64, 8, 1), torch.bool) triton_poi_fused_convolution_leaky_relu_leaky_relu_backward_8[grid( 1024)](buf6, primals_7, buf18, 1024, XBLOCK=256, num_warps=4, num_stages=1) del buf6 del primals_7 return (buf17, primals_2, primals_4, primals_6, primals_8, primals_10, primals_12, primals_14, buf0, buf2, buf4, buf5, buf7, buf8, buf10, buf12, buf13, buf15, buf18) class PA(nn.Module): """PA is pixel attention""" def __init__(self, nf): super(PA, self).__init__() self.conv = nn.Conv2d(nf, nf, 1) self.sigmoid = nn.Sigmoid() def forward(self, x): y = self.conv(x) y = self.sigmoid(y) out = torch.mul(x, y) return out class PA_UPNew(nn.Module): def __init__(self, nf, unf, out_nc, scale=4): super(PA_UPNew, self).__init__() self.upconv1 = nn.Conv2d(nf, unf, 3, 1, 1, bias=True) self.att1 = PA(unf) self.HRconv1 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) if scale == 4: self.upconv2 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) self.att2 = PA(unf) self.HRconv2 = nn.Conv2d(unf, unf, 3, 1, 1, bias=True) self.conv_last = nn.Conv2d(unf, out_nc, 3, 1, 1, bias=True) self.lrelu = nn.LeakyReLU(negative_slope=0.2, inplace=True) def forward(self, input_0): primals_2 = self.upconv1.weight primals_3 = self.upconv1.bias primals_4 = self.att1.conv.weight primals_5 = self.att1.conv.bias primals_6 = self.HRconv1.weight primals_7 = self.HRconv1.bias primals_8 = self.upconv2.weight primals_9 = self.upconv2.bias primals_10 = self.att2.conv.weight primals_11 = self.att2.conv.bias primals_12 = self.HRconv2.weight primals_13 = self.HRconv2.bias primals_14 = self.conv_last.weight primals_15 = self.conv_last.bias primals_1 = 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]) return output[0]
YingqiLiulll/scrips_for_SR
PA_UP
false
1,288
[ "MIT" ]
0
04fa6fdaf157e913d3e2521cd80315a10a2ccedc
https://github.com/YingqiLiulll/scrips_for_SR/tree/04fa6fdaf157e913d3e2521cd80315a10a2ccedc
BCEDiceLoss
import torch import torch.nn as nn class DiceLoss(nn.Module): def __init__(self, eps: 'float'=1e-09): super(DiceLoss, self).__init__() self.smooth = 1.0 self.eps = eps def forward(self, y_pred, y_true): num = y_true.size(0) probability = torch.sigmoid(y_pred) probability = probability.view(num, -1) targets = y_true.view(num, -1) assert probability.shape == targets.shape intersection = 2.0 * (probability * targets).sum() union = probability.sum() + targets.sum() dice_score = (intersection + self.eps) / union return 1.0 - dice_score class BCEDiceLoss(nn.Module): """Compute objective loss: BCE loss + DICE loss.""" def __init__(self): super(BCEDiceLoss, self).__init__() self.bce = nn.BCEWithLogitsLoss() self.dice = DiceLoss() def forward(self, logits: 'torch.Tensor', targets: 'torch.Tensor' ) ->torch.Tensor: assert logits.shape == targets.shape dice_loss = self.dice(logits, targets) bce_loss = self.bce(logits, targets) return bce_loss + dice_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 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_add_binary_cross_entropy_with_logits_div_mul_rsub_sum_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 = tl.broadcast_to(tmp12, [RBLOCK]) tmp15 = triton_helpers.promote_to_tensor(tl.sum(tmp13, 0)) tmp16 = tl.sigmoid(tmp3) tmp17 = tmp16 * tmp0 tmp18 = tl.broadcast_to(tmp17, [RBLOCK]) tmp20 = triton_helpers.promote_to_tensor(tl.sum(tmp18, 0)) tmp21 = tl.broadcast_to(tmp16, [RBLOCK]) tmp23 = triton_helpers.promote_to_tensor(tl.sum(tmp21, 0)) tmp24 = tl.broadcast_to(tmp0, [RBLOCK]) tmp26 = triton_helpers.promote_to_tensor(tl.sum(tmp24, 0)) tmp27 = 256.0 tmp28 = tmp15 / tmp27 tmp29 = 2.0 tmp30 = tmp20 * tmp29 tmp31 = 1e-09 tmp32 = tmp30 + tmp31 tmp33 = tmp23 + tmp26 tmp34 = tmp32 / tmp33 tmp35 = tmp1 - tmp34 tmp36 = tmp28 + tmp35 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp36, 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) buf4 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_binary_cross_entropy_with_logits_div_mul_rsub_sum_0[ grid(1)](buf4, arg1_1, arg0_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf4, class DiceLoss(nn.Module): def __init__(self, eps: 'float'=1e-09): super(DiceLoss, self).__init__() self.smooth = 1.0 self.eps = eps def forward(self, y_pred, y_true): num = y_true.size(0) probability = torch.sigmoid(y_pred) probability = probability.view(num, -1) targets = y_true.view(num, -1) assert probability.shape == targets.shape intersection = 2.0 * (probability * targets).sum() union = probability.sum() + targets.sum() dice_score = (intersection + self.eps) / union return 1.0 - dice_score class BCEDiceLossNew(nn.Module): """Compute objective loss: BCE loss + DICE loss.""" def __init__(self): super(BCEDiceLossNew, self).__init__() self.bce = nn.BCEWithLogitsLoss() self.dice = DiceLoss() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]
Yukei7/Multimodal-Segmentation-Network
BCEDiceLoss
false
1,289
[ "MIT" ]
0
0a38aa8bbd2eb87e28209c810438248c0464a240
https://github.com/Yukei7/Multimodal-Segmentation-Network/tree/0a38aa8bbd2eb87e28209c810438248c0464a240
Upsample
import torch import torch.nn.functional as F import torch.nn as nn def conv_nd(dims, *args, **kwargs): """ Create a 1D, 2D, or 3D convolution module. """ if dims == 1: return nn.Conv1d(*args, **kwargs) elif dims == 2: return nn.Conv2d(*args, **kwargs) elif dims == 3: return nn.Conv3d(*args, **kwargs) raise ValueError(f'unsupported dimensions: {dims}') class Upsample(nn.Module): """ An upsampling layer with an optional convolution. :param channels: channels in the inputs and outputs. :param use_conv: a bool determining if a convolution is applied. :param dims: determines if the signal is 1D, 2D, or 3D. If 3D, then upsampling occurs in the inner-two dimensions. """ def __init__(self, channels, use_conv, dims=2, out_channels=None): super().__init__() self.channels = channels self.out_channels = out_channels or channels self.use_conv = use_conv self.dims = dims if use_conv: self.conv = conv_nd(dims, self.channels, self.out_channels, 3, padding=1) def forward(self, x): assert x.shape[1] == self.channels if self.dims == 3: x = F.interpolate(x, (x.shape[2], x.shape[3] * 2, x.shape[4] * 2), mode='nearest') else: x = F.interpolate(x, scale_factor=2, mode='nearest') if self.use_conv: x = self.conv(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'channels': 4, 'use_conv': 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 @triton.jit def triton_poi_fused__unsafe_index_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 8 % 8 x0 = xindex % 8 x2 = xindex // 64 x4 = xindex tmp0 = x1 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 * tmp2 tmp4 = tmp3.to(tl.int32) tmp5 = x0 tmp6 = tmp5.to(tl.float32) tmp7 = tmp6 * tmp2 tmp8 = tmp7.to(tl.int32) tmp9 = tl.load(in_ptr0 + (tmp8 + 4 * tmp4 + 16 * x2), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x4, tmp9, xmask) @triton.jit def triton_poi_fused_convolution_1(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 64 % 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, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_3, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 8, 8), (256, 64, 8, 1), torch.float32) get_raw_stream(0) triton_poi_fused__unsafe_index_0[grid(1024)](primals_1, buf0, 1024, XBLOCK=256, num_warps=4, num_stages=1) del primals_1 buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 4, 8, 8), (256, 64, 8, 1)) buf2 = buf1 del buf1 triton_poi_fused_convolution_1[grid(1024)](buf2, primals_3, 1024, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 return buf2, primals_2, buf0 def conv_nd(dims, *args, **kwargs): """ Create a 1D, 2D, or 3D convolution module. """ if dims == 1: return nn.Conv1d(*args, **kwargs) elif dims == 2: return nn.Conv2d(*args, **kwargs) elif dims == 3: return nn.Conv3d(*args, **kwargs) raise ValueError(f'unsupported dimensions: {dims}') class UpsampleNew(nn.Module): """ An upsampling layer with an optional convolution. :param channels: channels in the inputs and outputs. :param use_conv: a bool determining if a convolution is applied. :param dims: determines if the signal is 1D, 2D, or 3D. If 3D, then upsampling occurs in the inner-two dimensions. """ def __init__(self, channels, use_conv, dims=2, out_channels=None): super().__init__() self.channels = channels self.out_channels = out_channels or channels self.use_conv = use_conv self.dims = dims if use_conv: self.conv = conv_nd(dims, self.channels, self.out_channels, 3, padding=1) def forward(self, input_0): primals_2 = self.conv.weight primals_3 = self.conv.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
ZGCTroy/guided-diffusion
Upsample
false
1,290
[ "MIT" ]
0
af987bb2b65db2875148a5466df79736ea5ae6a1
https://github.com/ZGCTroy/guided-diffusion/tree/af987bb2b65db2875148a5466df79736ea5ae6a1
ValueNetwork
import torch import torch.nn as nn import torch.nn.functional as F import torch.utils.data def weights_init_(m): if isinstance(m, nn.Linear): torch.nn.init.xavier_uniform_(m.weight, gain=1) torch.nn.init.constant_(m.bias, 0) class ValueNetwork(nn.Module): def __init__(self, num_inputs, hidden_dim): super(ValueNetwork, self).__init__() self.linear1 = nn.Linear(num_inputs, hidden_dim) self.linear2 = nn.Linear(hidden_dim, hidden_dim) self.linear4 = nn.Linear(hidden_dim, hidden_dim) self.linear3 = nn.Linear(hidden_dim, 1) self.apply(weights_init_) def forward(self, state): x = F.relu(self.linear1(state)) x = F.relu(self.linear2(x)) x = F.relu(self.linear4(x)) x = self.linear3(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_inputs': 4, 'hidden_dim': 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 import torch.utils.data 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) 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,), (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, (1, 4), (4, 1)) assert_size_stride(primals_9, (1,), (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 buf10 = 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, buf10, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf2) buf3 = reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf2 buf9 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf3, primals_5, buf9, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 buf4 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf4) buf5 = reinterpret_tensor(buf4, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf4 buf8 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf5, primals_7, buf8, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_7 buf7 = empty_strided_cuda((64, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_9, reinterpret_tensor(buf5, (64, 4), ( 4, 1), 0), reinterpret_tensor(primals_8, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf7) del primals_9 return reinterpret_tensor(buf7, (4, 4, 4, 1), (16, 4, 1, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), reinterpret_tensor(buf1, (64, 4), (4, 1), 0), reinterpret_tensor( buf3, (64, 4), (4, 1), 0), reinterpret_tensor(buf5, (64, 4), (4, 1), 0 ), primals_8, buf8, primals_6, buf9, primals_4, buf10 def weights_init_(m): if isinstance(m, nn.Linear): torch.nn.init.xavier_uniform_(m.weight, gain=1) torch.nn.init.constant_(m.bias, 0) class ValueNetworkNew(nn.Module): def __init__(self, num_inputs, hidden_dim): super(ValueNetworkNew, self).__init__() self.linear1 = nn.Linear(num_inputs, hidden_dim) self.linear2 = nn.Linear(hidden_dim, hidden_dim) self.linear4 = nn.Linear(hidden_dim, hidden_dim) self.linear3 = nn.Linear(hidden_dim, 1) self.apply(weights_init_) 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.linear4.weight primals_7 = self.linear4.bias primals_8 = self.linear3.weight primals_9 = self.linear3.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]
Yunaik/drl_env
ValueNetwork
false
1,291
[ "MIT" ]
0
d284e79847c59daa6ccb222f30fc7e2a86375546
https://github.com/Yunaik/drl_env/tree/d284e79847c59daa6ccb222f30fc7e2a86375546
QNetwork
import torch import torch.nn as nn import torch.nn.functional as F import torch.utils.data def weights_init_(m): if isinstance(m, nn.Linear): torch.nn.init.xavier_uniform_(m.weight, gain=1) torch.nn.init.constant_(m.bias, 0) class QNetwork(nn.Module): def __init__(self, num_inputs, num_actions, hidden_dim): super(QNetwork, self).__init__() self.linear1 = nn.Linear(num_inputs + num_actions, hidden_dim) self.linear2 = nn.Linear(hidden_dim, hidden_dim) self.linear7 = nn.Linear(hidden_dim, hidden_dim) self.linear3 = nn.Linear(hidden_dim, 1) self.linear4 = nn.Linear(num_inputs + num_actions, hidden_dim) self.linear5 = nn.Linear(hidden_dim, hidden_dim) self.linear8 = nn.Linear(hidden_dim, hidden_dim) self.linear6 = nn.Linear(hidden_dim, 1) self.apply(weights_init_) def forward(self, state, action): xu = torch.cat([state, action], 1) x1 = F.relu(self.linear1(xu)) x1 = F.relu(self.linear2(x1)) x1 = F.relu(self.linear7(x1)) x1 = self.linear3(x1) x2 = F.relu(self.linear4(xu)) x2 = F.relu(self.linear5(x2)) x2 = F.relu(self.linear8(x2)) x2 = self.linear6(x2) return x1, x2 def get_inputs(): return [torch.rand([4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'num_inputs': 4, 'num_actions': 4, 'hidden_dim': 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 import torch.utils.data 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, 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_relu_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.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) 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 ) = 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, 8), (8, 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,)) assert_size_stride(primals_9, (1, 4), (4, 1)) assert_size_stride(primals_10, (1,), (1,)) assert_size_stride(primals_11, (4, 8), (8, 1)) assert_size_stride(primals_12, (4,), (1,)) assert_size_stride(primals_13, (4, 4), (4, 1)) assert_size_stride(primals_14, (4,), (1,)) assert_size_stride(primals_15, (4, 4), (4, 1)) assert_size_stride(primals_16, (4,), (1,)) assert_size_stride(primals_17, (1, 4), (4, 1)) assert_size_stride(primals_18, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 8), (8, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(32)](primals_1, primals_2, buf0, 32, XBLOCK=32, num_warps=1, num_stages=1) del primals_1 del primals_2 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_3, (8, 4), (1, 8 ), 0), out=buf1) del primals_3 buf2 = buf1 del buf1 triton_poi_fused_relu_1[grid(16)](buf2, primals_4, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_4 buf3 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf2, reinterpret_tensor(primals_5, (4, 4), (1, 4 ), 0), out=buf3) buf4 = buf3 del buf3 triton_poi_fused_relu_1[grid(16)](buf4, primals_6, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_6 buf5 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf4, reinterpret_tensor(primals_7, (4, 4), (1, 4 ), 0), out=buf5) buf6 = buf5 del buf5 triton_poi_fused_relu_1[grid(16)](buf6, primals_8, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_8 buf8 = empty_strided_cuda((4, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_10, buf6, reinterpret_tensor(primals_9, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf8) del primals_10 buf9 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_11, (8, 4), (1, 8), 0), out=buf9) del primals_11 buf10 = buf9 del buf9 triton_poi_fused_relu_1[grid(16)](buf10, primals_12, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_12 buf11 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf10, reinterpret_tensor(primals_13, (4, 4), (1, 4), 0), out=buf11) buf12 = buf11 del buf11 triton_poi_fused_relu_1[grid(16)](buf12, primals_14, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_14 buf13 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf12, reinterpret_tensor(primals_15, (4, 4), (1, 4), 0), out=buf13) buf14 = buf13 del buf13 triton_poi_fused_relu_1[grid(16)](buf14, primals_16, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_16 buf16 = empty_strided_cuda((4, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_18, buf14, reinterpret_tensor( primals_17, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf16) del primals_18 return (buf8, buf16, buf0, buf2, buf4, buf6, buf10, buf12, buf14, primals_17, primals_15, primals_13, primals_9, primals_7, primals_5) def weights_init_(m): if isinstance(m, nn.Linear): torch.nn.init.xavier_uniform_(m.weight, gain=1) torch.nn.init.constant_(m.bias, 0) class QNetworkNew(nn.Module): def __init__(self, num_inputs, num_actions, hidden_dim): super(QNetworkNew, self).__init__() self.linear1 = nn.Linear(num_inputs + num_actions, hidden_dim) self.linear2 = nn.Linear(hidden_dim, hidden_dim) self.linear7 = nn.Linear(hidden_dim, hidden_dim) self.linear3 = nn.Linear(hidden_dim, 1) self.linear4 = nn.Linear(num_inputs + num_actions, hidden_dim) self.linear5 = nn.Linear(hidden_dim, hidden_dim) self.linear8 = nn.Linear(hidden_dim, hidden_dim) self.linear6 = nn.Linear(hidden_dim, 1) self.apply(weights_init_) def forward(self, input_0, input_1): primals_3 = self.linear1.weight primals_4 = self.linear1.bias primals_1 = self.linear2.weight primals_6 = self.linear2.bias primals_2 = self.linear7.weight primals_8 = self.linear7.bias primals_9 = self.linear3.weight primals_10 = self.linear3.bias primals_11 = self.linear4.weight primals_12 = self.linear4.bias primals_5 = self.linear5.weight primals_14 = self.linear5.bias primals_7 = self.linear8.weight primals_16 = self.linear8.bias primals_17 = self.linear6.weight primals_18 = self.linear6.bias primals_13 = input_0 primals_15 = 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, primals_13, primals_14, primals_15, primals_16, primals_17, primals_18]) return output[0], output[1]
Yunaik/drl_env
QNetwork
false
1,292
[ "MIT" ]
0
d284e79847c59daa6ccb222f30fc7e2a86375546
https://github.com/Yunaik/drl_env/tree/d284e79847c59daa6ccb222f30fc7e2a86375546
InnerProductModel
import torch class InnerProductModel(torch.nn.Module): @staticmethod def is_valid_model_type(model_type): raise NotImplementedError @staticmethod def get_model_from_type(model_type): raise NotImplementedError @property def loss_criterion(self): return torch.nn.MSELoss() def __init__(self, n): super().__init__() self.layer = torch.nn.Linear(n, 1, bias=False) self.layer.weight.data = torch.arange(n, dtype=torch.float32) def forward(self, x): return self.layer(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'n': 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 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_mv_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 tmp0 = tl.load(in_ptr0 + 4 * x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp4 = tl.load(in_ptr0 + (1 + 4 * x0), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + 1) tmp6 = tl.broadcast_to(tmp5, [XBLOCK]) tmp9 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last') tmp10 = tl.load(in_ptr1 + 2) tmp11 = tl.broadcast_to(tmp10, [XBLOCK]) tmp14 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp15 = tl.load(in_ptr1 + 3) tmp16 = tl.broadcast_to(tmp15, [XBLOCK]) tmp3 = tmp0 * tmp2 tmp7 = tmp4 * tmp6 tmp8 = tmp3 + tmp7 tmp12 = tmp9 * tmp11 tmp13 = tmp8 + tmp12 tmp17 = tmp14 * tmp16 tmp18 = tmp13 + tmp17 tl.store(out_ptr0 + x0, tmp18, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4,), (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((64,), (1,), torch.float32) get_raw_stream(0) triton_poi_fused_mv_0[grid(64)](primals_2, primals_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_1 return reinterpret_tensor(buf0, (4, 4, 4), (16, 4, 1), 0), primals_2 class InnerProductModelNew(torch.nn.Module): @staticmethod def is_valid_model_type(model_type): raise NotImplementedError @staticmethod def get_model_from_type(model_type): raise NotImplementedError @property def loss_criterion(self): return torch.nn.MSELoss() def __init__(self, n): super().__init__() self.layer = torch.nn.Linear(n, 1, bias=False) self.layer.weight.data = torch.arange(n, dtype=torch.float32) def forward(self, input_0): primals_1 = self.layer.weight primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]
Yufei-Kang/plato
InnerProductModel
false
1,293
[ "Apache-2.0" ]
0
16b170698242b1e11677e80229c3439a9e26965a
https://github.com/Yufei-Kang/plato/tree/16b170698242b1e11677e80229c3439a9e26965a
SequenceSummaryLayer
import torch import torch.nn as nn class SequenceSummaryLayer(nn.Module): def __init__(self, hidden_size, summary_layers): super().__init__() self.summary_layers = summary_layers self.linear = nn.Linear(hidden_size * summary_layers, hidden_size) self.pooler = nn.Linear(hidden_size, hidden_size) self.pooler_activation = nn.Tanh() def forward(self, x): stacked_hidden_states = torch.stack(list(x[-self.summary_layers:]), dim=-2) stacked_hidden_states = stacked_hidden_states[:, 0] concat_hidden_states = stacked_hidden_states.view(stacked_hidden_states .shape[0], stacked_hidden_states.shape[-2] * stacked_hidden_states.shape[-1]) resized_hidden_states = self.linear(concat_hidden_states) pooled_hidden_states = self.pooler_activation(self.pooler( resized_hidden_states)) return pooled_hidden_states def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'hidden_size': 4, 'summary_layers': 1}]
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 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_tanh_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 = libdevice.tanh(tmp2) tl.store(in_out_ptr0 + x2, tmp3, 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((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_3, reinterpret_tensor(primals_1, (4, 4 ), (16, 1), 192), 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, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_4, (4, 4), (1, 4 ), 0), out=buf1) buf2 = buf1 del buf1 get_raw_stream(0) triton_poi_fused_tanh_0[grid(16)](buf2, primals_5, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_5 return buf2, reinterpret_tensor(primals_1, (4, 4), (16, 1), 192 ), buf0, buf2, primals_4 class SequenceSummaryLayerNew(nn.Module): def __init__(self, hidden_size, summary_layers): super().__init__() self.summary_layers = summary_layers self.linear = nn.Linear(hidden_size * summary_layers, hidden_size) self.pooler = nn.Linear(hidden_size, hidden_size) self.pooler_activation = nn.Tanh() def forward(self, input_0): primals_2 = self.linear.weight primals_3 = self.linear.bias primals_4 = self.pooler.weight primals_5 = self.pooler.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
Zaaachary/CSQA
SequenceSummaryLayer
false
1,294
[ "BSD-3-Clause" ]
0
6da6e076f67e9458deacb665d31463db14c7d860
https://github.com/Zaaachary/CSQA/tree/6da6e076f67e9458deacb665d31463db14c7d860
EltwiseProdScoring
import torch import torch.nn as nn class EltwiseProdScoring(nn.Module): """ Linearly mapping h and v to the same dimension, and do a elementwise multiplication and a linear scoring """ def __init__(self, h_dim, a_dim, dot_dim=256): """Initialize layer.""" super(EltwiseProdScoring, self).__init__() self.linear_in_h = nn.Linear(h_dim, dot_dim, bias=True) self.linear_in_a = nn.Linear(a_dim, dot_dim, bias=True) self.linear_out = nn.Linear(dot_dim, 1, bias=True) def forward(self, h, all_u_t, mask=None): """Propagate h through the network. h: batch x h_dim all_u_t: batch x a_num x a_dim """ target = self.linear_in_h(h).unsqueeze(1) context = self.linear_in_a(all_u_t) eltprod = torch.mul(target, context) logits = self.linear_out(eltprod).squeeze(2) return logits def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'h_dim': 4, 'a_dim': 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_mul_0(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) x0 = xindex % 4096 x2 = xindex // 16384 x3 = xindex % 16384 x4 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 4096 * x2), None, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr1 + x3, None, eviction_policy='evict_last') tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x4, tmp2, None) 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, (256, 4), (4, 1)) assert_size_stride(primals_2, (256,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (256, 4), (4, 1)) assert_size_stride(primals_5, (256,), (1,)) assert_size_stride(primals_6, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_7, (1, 256), (256, 1)) assert_size_stride(primals_8, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 256), (256, 1), torch.float32) extern_kernels.addmm(primals_2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 256), (1, 4), 0), alpha=1, beta=1, out=buf0) del primals_1 del primals_2 buf1 = empty_strided_cuda((64, 256), (256, 1), torch.float32) extern_kernels.addmm(primals_5, reinterpret_tensor(primals_6, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 256), (1, 4), 0), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4, 4, 4, 256), (16384, 4096, 1024, 256, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mul_0[grid(65536)](buf0, buf1, buf2, 65536, XBLOCK =256, num_warps=4, num_stages=1) buf4 = empty_strided_cuda((256, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_8, reinterpret_tensor(buf2, (256, 256), (256, 1), 0), reinterpret_tensor(primals_7, (256, 1), (1, 256), 0), alpha=1, beta=1, out=buf4) del primals_8 return reinterpret_tensor(buf4, (4, 4, 4, 4, 1), (64, 16, 4, 1, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), buf0, reinterpret_tensor(primals_6, (64, 4), (4, 1), 0 ), buf1, reinterpret_tensor(buf2, (256, 256), (256, 1), 0), primals_7 class EltwiseProdScoringNew(nn.Module): """ Linearly mapping h and v to the same dimension, and do a elementwise multiplication and a linear scoring """ def __init__(self, h_dim, a_dim, dot_dim=256): """Initialize layer.""" super(EltwiseProdScoringNew, self).__init__() self.linear_in_h = nn.Linear(h_dim, dot_dim, bias=True) self.linear_in_a = nn.Linear(a_dim, dot_dim, bias=True) self.linear_out = nn.Linear(dot_dim, 1, bias=True) def forward(self, input_0, input_1): primals_1 = self.linear_in_h.weight primals_2 = self.linear_in_h.bias primals_4 = self.linear_in_a.weight primals_5 = self.linear_in_a.bias primals_7 = self.linear_out.weight primals_8 = self.linear_out.bias primals_3 = input_0 primals_6 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8]) return output[0]
YzyLmc/AC-GG_0.2
EltwiseProdScoring
false
1,295
[ "BSD-2-Clause", "MIT" ]
0
ddedbbe4062f6646041e24c16593b087d3cf0095
https://github.com/YzyLmc/AC-GG_0.2/tree/ddedbbe4062f6646041e24c16593b087d3cf0095
AttentionMerge
import math import torch import torch.nn as nn import torch.nn.functional as F class AttentionMerge(nn.Module): def __init__(self, input_size, attention_size, dropout_prob=0.1): super(AttentionMerge, self).__init__() self.attention_size = attention_size self.hidden_layer = nn.Linear(input_size, self.attention_size) self.query_ = nn.Parameter(torch.Tensor(self.attention_size, 1)) self.dropout = nn.Dropout(dropout_prob) self.query_.data.normal_(mean=0.0, std=0.02) def forward(self, values, mask=None): """ H (B, L, hidden_size) => h (B, hidden_size) (B, L1, L2, hidden_size) => (B, L2, hidden) """ if mask is None: mask = torch.zeros_like(values) else: mask = (1 - mask.unsqueeze(-1).type(torch.float)) * -1000.0 keys = self.hidden_layer(values) keys = torch.tanh(keys) query_var = torch.var(self.query_) attention_probs = keys @ self.query_ / math.sqrt(self. attention_size * query_var) attention_probs = F.softmax(attention_probs * mask, dim=1) attention_probs = self.dropout(attention_probs) context = torch.sum(attention_probs + values, dim=1) return context def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, 'attention_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 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_zeros_like_0(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 = 0.0 tl.store(out_ptr0 + x0, tmp0, xmask) @triton.jit def triton_poi_fused_tanh_1(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 = libdevice.tanh(tmp2) tl.store(in_out_ptr0 + x2, tmp3, xmask) @triton.jit def triton_per_fused_mul_var_2(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 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.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.broadcast_to(tmp1, [XBLOCK, RBLOCK]) tmp5 = tl.sum(tmp3, 1)[:, None] tmp6 = tl.full([XBLOCK, 1], 4, tl.int32) tmp7 = tmp6.to(tl.float32) tmp8 = tmp5 / tmp7 tmp9 = tmp1 - tmp8 tmp10 = tmp9 * tmp9 tmp11 = tl.broadcast_to(tmp10, [XBLOCK, RBLOCK]) tmp13 = tl.sum(tmp11, 1)[:, None] tmp14 = 3.0 tmp15 = tmp13 / tmp14 tmp16 = 4.0 tmp17 = tmp15 * tmp16 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp17, None) def call(args): primals_1, primals_2, primals_3, primals_4 = 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, 1), (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_zeros_like_0[grid(256)](buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) 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_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused_tanh_1[grid(256)](buf2, primals_3, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_3 buf4 = empty_strided_cuda((), (), torch.float32) buf7 = buf4 del buf4 triton_per_fused_mul_var_2[grid(1)](buf7, primals_4, 1, 4, XBLOCK=1, num_warps=2, num_stages=1) buf6 = empty_strided_cuda((64, 1), (1, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf2, (64, 4), (4, 1), 0), primals_4, out=buf6) return reinterpret_tensor(buf6, (4, 4, 4, 1), (16, 4, 1, 1), 0 ), buf7, buf0, primals_4, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), buf2 class AttentionMergeNew(nn.Module): def __init__(self, input_size, attention_size, dropout_prob=0.1): super(AttentionMergeNew, self).__init__() self.attention_size = attention_size self.hidden_layer = nn.Linear(input_size, self.attention_size) self.query_ = nn.Parameter(torch.Tensor(self.attention_size, 1)) self.dropout = nn.Dropout(dropout_prob) self.query_.data.normal_(mean=0.0, std=0.02) def forward(self, input_0): primals_4 = self.query_ primals_2 = self.hidden_layer.weight primals_3 = self.hidden_layer.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4]) return output[0]
Zaaachary/CSQA
AttentionMerge
false
1,297
[ "BSD-3-Clause" ]
0
6da6e076f67e9458deacb665d31463db14c7d860
https://github.com/Zaaachary/CSQA/tree/6da6e076f67e9458deacb665d31463db14c7d860
ConformerFeedForward
import torch from torch import nn import torch.utils.data import torch.optim class Swish(nn.Module): """ Swish activation function introduced in 'https://arxiv.org/abs/1710.05941' """ def forward(self, x): return x * torch.sigmoid(x) class ConformerFeedForward(nn.Module): """ feed-forward module of Conformer model. """ def __init__(self, d_model, d_ff, dropout, activation=Swish()): super(ConformerFeedForward, self).__init__() self.linear1 = nn.Linear(d_model, d_ff) self.activation = activation self.dropout = nn.Dropout(p=dropout) self.linear2 = nn.Linear(d_ff, d_model) def forward(self, x): x = self.linear1(x) x = self.activation(x) x = self.dropout(x) x = self.linear2(x) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'d_model': 4, 'd_ff': 4, 'dropout': 0.5}]
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 import nn import torch.utils.data import torch.optim 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_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) tmp2 = tmp0 * tmp1 tl.store(out_ptr0 + x0, tmp2, 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, 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,)) 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_mul_sigmoid_0[grid(256)](buf0, buf1, 256, XBLOCK= 256, num_warps=4, num_stages=1) 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 return reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), buf0, reinterpret_tensor(buf1, (64, 4), (4, 1), 0), primals_4 class Swish(nn.Module): """ Swish activation function introduced in 'https://arxiv.org/abs/1710.05941' """ def forward(self, x): return x * torch.sigmoid(x) class ConformerFeedForwardNew(nn.Module): """ feed-forward module of Conformer model. """ def __init__(self, d_model, d_ff, dropout, activation=Swish()): super(ConformerFeedForwardNew, self).__init__() self.linear1 = nn.Linear(d_model, d_ff) self.activation = activation self.dropout = nn.Dropout(p=dropout) self.linear2 = nn.Linear(d_ff, 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_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
Zenodia/NeMo
ConformerFeedForward
false
1,298
[ "Apache-2.0" ]
0
3c288d8a7caf667c95444c39434e3ebc5f53d911
https://github.com/Zenodia/NeMo/tree/3c288d8a7caf667c95444c39434e3ebc5f53d911
MultiLayerPerceptron
import torch import torch.utils.data import torch.optim class MultiLayerPerceptron(torch.nn.Module): """ A simple MLP that can either be used independently or put on top of pretrained models (such as BERT) and act as a classifier. Args: hidden_size (int): the size of each layer num_classes (int): number of output classes num_layers (int): number of layers activation (str): type of activations for layers in between log_softmax (bool): whether to add a log_softmax layer before output """ def __init__(self, hidden_size: 'int', num_classes: 'int', num_layers: 'int'=2, activation: 'str'='relu', log_softmax: 'bool'=True): super().__init__() self.layers = 0 for _ in range(num_layers - 1): layer = torch.nn.Linear(hidden_size, hidden_size) setattr(self, f'layer{self.layers}', layer) setattr(self, f'layer{self.layers + 1}', getattr(torch, activation) ) self.layers += 2 layer = torch.nn.Linear(hidden_size, num_classes) setattr(self, f'layer{self.layers}', layer) self.layers += 1 self.log_softmax = log_softmax @property def last_linear_layer(self): return getattr(self, f'layer{self.layers - 1}') def forward(self, hidden_states): output_states = hidden_states[:] for i in range(self.layers): output_states = getattr(self, f'layer{i}')(output_states) if self.log_softmax: output_states = torch.log_softmax(output_states, dim=-1) return output_states def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'hidden_size': 4, 'num_classes': 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.utils.data import torch.optim 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__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 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 tl.store(out_ptr0 + x2, tmp8, xmask) @triton.jit def triton_poi_fused__log_softmax_2(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') tmp3 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') 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 tl.store(out_ptr0 + x2, tmp13, 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 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 buf5 = 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_3, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 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, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__log_softmax_1[grid(256)](buf2, buf3, 256, XBLOCK= 256, num_warps=4, num_stages=1) buf4 = reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf2 triton_poi_fused__log_softmax_2[grid(256)](buf3, buf4, 256, XBLOCK= 128, num_warps=4, num_stages=1) del buf3 return buf4, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0 ), reinterpret_tensor(buf1, (64, 4), (4, 1), 0), buf4, primals_4, buf5 class MultiLayerPerceptronNew(torch.nn.Module): """ A simple MLP that can either be used independently or put on top of pretrained models (such as BERT) and act as a classifier. Args: hidden_size (int): the size of each layer num_classes (int): number of output classes num_layers (int): number of layers activation (str): type of activations for layers in between log_softmax (bool): whether to add a log_softmax layer before output """ def __init__(self, hidden_size: 'int', num_classes: 'int', num_layers: 'int'=2, activation: 'str'='relu', log_softmax: 'bool'=True): super().__init__() self.layers = 0 for _ in range(num_layers - 1): layer = torch.nn.Linear(hidden_size, hidden_size) setattr(self, f'layer{self.layers}', layer) setattr(self, f'layer{self.layers + 1}', getattr(torch, activation) ) self.layers += 2 layer = torch.nn.Linear(hidden_size, num_classes) setattr(self, f'layer{self.layers}', layer) self.layers += 1 self.log_softmax = log_softmax @property def last_linear_layer(self): return getattr(self, f'layer{self.layers - 1}') def forward(self, input_0): primals_2 = self.layer0.weight primals_3 = self.layer0.bias primals_4 = self.layer2.weight primals_5 = self.layer2.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
Zenodia/NeMo
MultiLayerPerceptron
false
1,299
[ "Apache-2.0" ]
0
3c288d8a7caf667c95444c39434e3ebc5f53d911
https://github.com/Zenodia/NeMo/tree/3c288d8a7caf667c95444c39434e3ebc5f53d911
Encoder
import torch import torch.nn as nn import torch.nn.functional as F class Encoder(nn.Module): def __init__(self, out_dim=64): super(Encoder, self).__init__() self.conv1 = nn.Conv2d(3, 16, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(16, 32, kernel_size=3, stride=1, padding=1) self.conv3 = nn.Conv2d(32, 64, kernel_size=3, stride=1, padding=1) self.conv4 = nn.Conv2d(64, 64, kernel_size=3, stride=1, padding=1) self.pool = nn.MaxPool2d(2, 2) self.l1 = nn.Linear(64, 64) self.l2 = nn.Linear(64, out_dim) def forward(self, x): x = self.conv1(x) x = F.relu(x) x = self.pool(x) x = self.conv2(x) x = F.relu(x) x = self.pool(x) x = self.conv3(x) x = F.relu(x) x = self.pool(x) x = self.conv4(x) x = F.relu(x) x = self.pool(x) h = torch.mean(x, dim=[2, 3]) x = self.l1(h) x = F.relu(x) x = self.l2(x) return h, x def get_inputs(): return [torch.rand([4, 3, 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 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_relu_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) x3 = xindex x1 = xindex // 4096 % 16 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_max_pool2d_with_indices_1(in_ptr0, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x0 = xindex % 32 x1 = xindex // 32 x2 = xindex tmp0 = tl.load(in_ptr0 + (2 * x0 + 128 * x1), None, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr0 + (1 + 2 * x0 + 128 * x1), None, eviction_policy ='evict_last') tmp3 = tl.load(in_ptr0 + (64 + 2 * x0 + 128 * x1), None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (65 + 2 * x0 + 128 * x1), None, eviction_policy='evict_last') tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tmp7 = tmp1 > tmp0 tmp8 = tl.full([1], 1, tl.int8) tmp9 = tl.full([1], 0, tl.int8) tmp10 = tl.where(tmp7, tmp8, tmp9) tmp11 = tmp3 > tmp2 tmp12 = tl.full([1], 2, tl.int8) tmp13 = tl.where(tmp11, tmp12, tmp10) tmp14 = tmp5 > tmp4 tmp15 = tl.full([1], 3, tl.int8) tmp16 = tl.where(tmp14, tmp15, tmp13) tl.store(out_ptr0 + x2, tmp6, None) tl.store(out_ptr1 + x2, tmp16, None) @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) x3 = xindex x1 = xindex // 1024 % 32 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_max_pool2d_with_indices_3(in_ptr0, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x0 = xindex % 16 x1 = xindex // 16 x2 = xindex tmp0 = tl.load(in_ptr0 + (2 * x0 + 64 * x1), None, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr0 + (1 + 2 * x0 + 64 * x1), None, eviction_policy= 'evict_last') tmp3 = tl.load(in_ptr0 + (32 + 2 * x0 + 64 * x1), None, eviction_policy ='evict_last') tmp5 = tl.load(in_ptr0 + (33 + 2 * x0 + 64 * x1), None, eviction_policy ='evict_last') tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tmp7 = tmp1 > tmp0 tmp8 = tl.full([1], 1, tl.int8) tmp9 = tl.full([1], 0, tl.int8) tmp10 = tl.where(tmp7, tmp8, tmp9) tmp11 = tmp3 > tmp2 tmp12 = tl.full([1], 2, tl.int8) tmp13 = tl.where(tmp11, tmp12, tmp10) tmp14 = tmp5 > tmp4 tmp15 = tl.full([1], 3, tl.int8) tmp16 = tl.where(tmp14, tmp15, tmp13) tl.store(out_ptr0 + x2, tmp6, None) tl.store(out_ptr1 + x2, tmp16, None) @triton.jit def triton_poi_fused_convolution_relu_4(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 // 256 % 64 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_max_pool2d_with_indices_5(in_ptr0, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x0 = xindex % 8 x1 = xindex // 8 x2 = xindex tmp0 = tl.load(in_ptr0 + (2 * x0 + 32 * x1), None, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr0 + (1 + 2 * x0 + 32 * x1), None, eviction_policy= 'evict_last') tmp3 = tl.load(in_ptr0 + (16 + 2 * x0 + 32 * x1), None, eviction_policy ='evict_last') tmp5 = tl.load(in_ptr0 + (17 + 2 * x0 + 32 * x1), None, eviction_policy ='evict_last') tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tmp7 = tmp1 > tmp0 tmp8 = tl.full([1], 1, tl.int8) tmp9 = tl.full([1], 0, tl.int8) tmp10 = tl.where(tmp7, tmp8, tmp9) tmp11 = tmp3 > tmp2 tmp12 = tl.full([1], 2, tl.int8) tmp13 = tl.where(tmp11, tmp12, tmp10) tmp14 = tmp5 > tmp4 tmp15 = tl.full([1], 3, tl.int8) tmp16 = tl.where(tmp14, tmp15, tmp13) tl.store(out_ptr0 + x2, tmp6, None) tl.store(out_ptr1 + x2, tmp16, None) @triton.jit def triton_poi_fused_convolution_relu_6(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 // 64 % 64 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_per_fused_max_pool2d_with_indices_mean_7(in_out_ptr0, in_ptr0, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 256 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 % 4 r2 = rindex // 4 x0 = xindex r3 = rindex tmp0 = tl.load(in_ptr0 + (2 * r1 + 16 * r2 + 64 * x0), xmask, eviction_policy='evict_last', other=0.0) tmp1 = tl.load(in_ptr0 + (1 + 2 * r1 + 16 * r2 + 64 * x0), xmask, eviction_policy='evict_last', other=0.0) tmp7 = tl.load(in_ptr0 + (8 + 2 * r1 + 16 * r2 + 64 * x0), xmask, eviction_policy='evict_last', other=0.0) tmp12 = tl.load(in_ptr0 + (9 + 2 * r1 + 16 * r2 + 64 * x0), xmask, eviction_policy='evict_last', other=0.0) tmp2 = tmp1 > tmp0 tmp3 = tl.full([1, 1], 1, tl.int8) tmp4 = tl.full([1, 1], 0, tl.int8) tmp5 = tl.where(tmp2, tmp3, tmp4) tmp6 = triton_helpers.maximum(tmp1, tmp0) tmp8 = tmp7 > tmp6 tmp9 = tl.full([1, 1], 2, tl.int8) tmp10 = tl.where(tmp8, tmp9, tmp5) tmp11 = triton_helpers.maximum(tmp7, tmp6) tmp13 = tmp12 > tmp11 tmp14 = tl.full([1, 1], 3, tl.int8) tmp15 = tl.where(tmp13, tmp14, tmp10) tmp16 = triton_helpers.maximum(tmp12, tmp11) tmp17 = tl.broadcast_to(tmp16, [XBLOCK, RBLOCK]) tmp19 = tl.where(xmask, tmp17, 0) tmp20 = tl.sum(tmp19, 1)[:, None] tmp21 = 16.0 tmp22 = tmp20 / tmp21 tl.store(out_ptr0 + (r3 + 16 * x0), tmp15, xmask) tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp22, xmask) @triton.jit def triton_poi_fused_relu_8(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 % 64 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): (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, (16, 3, 3, 3), (27, 9, 3, 1)) assert_size_stride(primals_2, (16,), (1,)) assert_size_stride(primals_3, (4, 3, 64, 64), (12288, 4096, 64, 1)) assert_size_stride(primals_4, (32, 16, 3, 3), (144, 9, 3, 1)) assert_size_stride(primals_5, (32,), (1,)) assert_size_stride(primals_6, (64, 32, 3, 3), (288, 9, 3, 1)) assert_size_stride(primals_7, (64,), (1,)) assert_size_stride(primals_8, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_9, (64,), (1,)) assert_size_stride(primals_10, (64, 64), (64, 1)) assert_size_stride(primals_11, (64,), (1,)) assert_size_stride(primals_12, (64, 64), (64, 1)) assert_size_stride(primals_13, (64,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 16, 64, 64), (65536, 4096, 64, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(262144)](buf1, primals_2, 262144, XBLOCK=1024, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 16, 32, 32), (16384, 1024, 32, 1), torch.float32) buf3 = empty_strided_cuda((4, 16, 32, 32), (16384, 1024, 32, 1), torch.int8) triton_poi_fused_max_pool2d_with_indices_1[grid(65536)](buf1, buf2, buf3, 65536, XBLOCK=512, num_warps=4, num_stages=1) buf4 = extern_kernels.convolution(buf2, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf4, (4, 32, 32, 32), (32768, 1024, 32, 1)) buf5 = buf4 del buf4 triton_poi_fused_convolution_relu_2[grid(131072)](buf5, primals_5, 131072, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf6 = empty_strided_cuda((4, 32, 16, 16), (8192, 256, 16, 1), torch.float32) buf7 = empty_strided_cuda((4, 32, 16, 16), (8192, 256, 16, 1), torch.int8) triton_poi_fused_max_pool2d_with_indices_3[grid(32768)](buf5, buf6, buf7, 32768, XBLOCK=128, num_warps=4, num_stages=1) buf8 = extern_kernels.convolution(buf6, primals_6, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf8, (4, 64, 16, 16), (16384, 256, 16, 1)) buf9 = buf8 del buf8 triton_poi_fused_convolution_relu_4[grid(65536)](buf9, primals_7, 65536, XBLOCK=512, num_warps=4, num_stages=1) del primals_7 buf10 = empty_strided_cuda((4, 64, 8, 8), (4096, 64, 8, 1), torch. float32) buf11 = empty_strided_cuda((4, 64, 8, 8), (4096, 64, 8, 1), torch.int8) triton_poi_fused_max_pool2d_with_indices_5[grid(16384)](buf9, buf10, buf11, 16384, XBLOCK=256, num_warps=4, num_stages=1) buf12 = extern_kernels.convolution(buf10, primals_8, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf12, (4, 64, 8, 8), (4096, 64, 8, 1)) buf13 = buf12 del buf12 triton_poi_fused_convolution_relu_6[grid(16384)](buf13, primals_9, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_9 buf14 = empty_strided_cuda((4, 64, 4, 4), (1024, 16, 4, 1), torch.int8) buf15 = empty_strided_cuda((4, 64), (64, 1), torch.float32) buf16 = buf15 del buf15 triton_per_fused_max_pool2d_with_indices_mean_7[grid(256)](buf16, buf13, buf14, 256, 16, XBLOCK=1, num_warps=2, num_stages=1) buf17 = empty_strided_cuda((4, 64), (64, 1), torch.float32) extern_kernels.mm(buf16, reinterpret_tensor(primals_10, (64, 64), ( 1, 64), 0), out=buf17) buf18 = buf17 del buf17 triton_poi_fused_relu_8[grid(256)](buf18, primals_11, 256, XBLOCK= 128, num_warps=4, num_stages=1) del primals_11 buf19 = empty_strided_cuda((4, 64), (64, 1), torch.float32) extern_kernels.addmm(primals_13, buf18, reinterpret_tensor( primals_12, (64, 64), (1, 64), 0), alpha=1, beta=1, out=buf19) del primals_13 return (buf16, buf19, primals_1, primals_3, primals_4, primals_6, primals_8, buf1, buf2, buf3, buf5, buf6, buf7, buf9, buf10, buf11, buf13, buf14, buf16, buf18, primals_12, primals_10) class EncoderNew(nn.Module): def __init__(self, out_dim=64): super(EncoderNew, self).__init__() self.conv1 = nn.Conv2d(3, 16, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(16, 32, kernel_size=3, stride=1, padding=1) self.conv3 = nn.Conv2d(32, 64, kernel_size=3, stride=1, padding=1) self.conv4 = nn.Conv2d(64, 64, kernel_size=3, stride=1, padding=1) self.pool = nn.MaxPool2d(2, 2) self.l1 = nn.Linear(64, 64) self.l2 = nn.Linear(64, out_dim) 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.conv4.weight primals_9 = self.conv4.bias primals_10 = self.l1.weight primals_11 = self.l1.bias primals_12 = self.l2.weight primals_13 = self.l2.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]) return output[0], output[1]
YoniSchirris/SimCLR
Encoder
false
1,300
[ "MIT" ]
0
a99b7f7d0fdbc5a9747abf70a8b216b328608796
https://github.com/YoniSchirris/SimCLR/tree/a99b7f7d0fdbc5a9747abf70a8b216b328608796
mnist_model
import torch import torch.nn as nn import torch.nn.functional as F class mnist_model(nn.Module): def __init__(self): super(mnist_model, self).__init__() self.conv1 = nn.Conv2d(1, 32, 3, 1, 0) self.conv2 = nn.Conv2d(32, 64, 3, 1, 0) self.conv3 = nn.Conv2d(64, 128, 1, 1, 0) self.pool1 = nn.MaxPool2d(2, 2, 0) self.fc1 = nn.Linear(128 * 14 * 14, 1024) self.fc2 = nn.Linear(1024, 10) self.relu = nn.ReLU() def forward(self, x): h1 = self.relu(self.conv1(x)) h2 = self.relu(self.conv2(h1)) h3 = self.pool1(self.relu(self.conv3(h2))) h3 = h3.view(-1, 128 * 14 * 14) h4 = self.fc1(h3) h5 = self.fc2(h4) return F.log_softmax(h5, dim=1) def get_inputs(): return [torch.rand([4, 1, 32, 32])] 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 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 reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @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 % 32 y1 = yindex // 32 tmp0 = tl.load(in_ptr0 + (x2 + 9 * y3), xmask, eviction_policy='evict_last' ) tl.store(out_ptr0 + (y0 + 32 * x2 + 288 * y1), tmp0, xmask) @triton.jit def triton_poi_fused_convolution_relu_1(in_ptr0, in_ptr1, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 128 xnumel = 900 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 y3 = yindex y0 = yindex % 32 y1 = yindex // 32 tmp0 = tl.load(in_ptr0 + (x2 + 900 * y3), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1, 1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(out_ptr0 + (y0 + 32 * x2 + 28800 * y1), tmp4, xmask & ymask) @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_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 % 128 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_max_pool2d_with_indices_4(in_ptr0, out_ptr0, out_ptr1, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 784 xnumel = 128 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 % 14 y1 = yindex // 14 y5 = yindex y4 = yindex // 196 y6 = yindex % 196 tmp0 = tl.load(in_ptr0 + (x2 + 256 * y0 + 7168 * y1), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (128 + x2 + 256 * y0 + 7168 * y1), xmask & ymask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (3584 + x2 + 256 * y0 + 7168 * y1), xmask & ymask, eviction_policy='evict_last') tmp12 = tl.load(in_ptr0 + (3712 + x2 + 256 * y0 + 7168 * y1), xmask & ymask, eviction_policy='evict_last') tmp2 = tmp1 > tmp0 tmp3 = tl.full([1, 1], 1, tl.int8) tmp4 = tl.full([1, 1], 0, tl.int8) tmp5 = tl.where(tmp2, tmp3, tmp4) tmp6 = triton_helpers.maximum(tmp1, tmp0) tmp8 = tmp7 > tmp6 tmp9 = tl.full([1, 1], 2, tl.int8) tmp10 = tl.where(tmp8, tmp9, tmp5) tmp11 = triton_helpers.maximum(tmp7, tmp6) tmp13 = tmp12 > tmp11 tmp14 = tl.full([1, 1], 3, tl.int8) tmp15 = tl.where(tmp13, tmp14, tmp10) tmp16 = triton_helpers.maximum(tmp12, tmp11) tl.store(out_ptr0 + (x2 + 128 * y5), tmp15, xmask & ymask) tl.store(out_ptr1 + (y6 + 196 * x2 + 25088 * y4), tmp16, xmask & ymask) @triton.jit def triton_per_fused__log_softmax_5(in_ptr0, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 4 rnumel = 10 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, :] rmask = rindex < rnumel r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 10 * x0), rmask & xmask, other=0.0) tmp1 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(rmask & xmask, tmp1, float('-inf')) tmp4 = triton_helpers.max2(tmp3, 1)[:, None] tmp5 = tmp0 - tmp4 tmp6 = tl_math.exp(tmp5) tmp7 = tl.broadcast_to(tmp6, [XBLOCK, RBLOCK]) tmp9 = tl.where(rmask & xmask, tmp7, 0) tmp10 = tl.sum(tmp9, 1)[:, None] tmp11 = tl_math.log(tmp10) tmp12 = tmp5 - tmp11 tl.store(out_ptr2 + (r1 + 10 * x0), tmp12, rmask & 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) = args args.clear() assert_size_stride(primals_1, (32, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_2, (32,), (1,)) assert_size_stride(primals_3, (4, 1, 32, 32), (1024, 1024, 32, 1)) assert_size_stride(primals_4, (64, 32, 3, 3), (288, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) assert_size_stride(primals_6, (128, 64, 1, 1), (64, 1, 1, 1)) assert_size_stride(primals_7, (128,), (1,)) assert_size_stride(primals_8, (1024, 25088), (25088, 1)) assert_size_stride(primals_9, (1024,), (1,)) assert_size_stride(primals_10, (10, 1024), (1024, 1)) assert_size_stride(primals_11, (10,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 32, 3, 3), (288, 1, 96, 32), torch. float32) get_raw_stream(0) triton_poi_fused_0[grid(2048, 9)](primals_4, buf0, 2048, 9, XBLOCK= 16, YBLOCK=64, num_warps=4, num_stages=1) del primals_4 buf1 = 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(buf1, (4, 32, 30, 30), (28800, 900, 30, 1)) buf2 = empty_strided_cuda((4, 32, 30, 30), (28800, 1, 960, 32), torch.float32) triton_poi_fused_convolution_relu_1[grid(128, 900)](buf1, primals_2, buf2, 128, 900, XBLOCK=8, YBLOCK=128, num_warps=4, num_stages=1) del buf1 del primals_2 buf3 = extern_kernels.convolution(buf2, buf0, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf3, (4, 64, 28, 28), (50176, 1, 1792, 64)) buf4 = buf3 del buf3 triton_poi_fused_convolution_relu_2[grid(200704)](buf4, primals_5, 200704, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 buf5 = extern_kernels.convolution(buf4, primals_6, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf5, (4, 128, 28, 28), (100352, 1, 3584, 128)) buf6 = buf5 del buf5 triton_poi_fused_convolution_relu_3[grid(401408)](buf6, primals_7, 401408, XBLOCK=1024, num_warps=4, num_stages=1) del primals_7 buf7 = empty_strided_cuda((4, 128, 14, 14), (25088, 1, 1792, 128), torch.int8) buf8 = empty_strided_cuda((4, 128, 14, 14), (25088, 196, 14, 1), torch.float32) triton_poi_fused_max_pool2d_with_indices_4[grid(784, 128)](buf6, buf7, buf8, 784, 128, XBLOCK=128, YBLOCK=8, num_warps=4, num_stages=1) buf9 = empty_strided_cuda((4, 1024), (1024, 1), torch.float32) extern_kernels.addmm(primals_9, reinterpret_tensor(buf8, (4, 25088), (25088, 1), 0), reinterpret_tensor(primals_8, (25088, 1024), (1, 25088), 0), alpha=1, beta=1, out=buf9) del primals_9 buf10 = empty_strided_cuda((4, 10), (10, 1), torch.float32) extern_kernels.addmm(primals_11, buf9, reinterpret_tensor( primals_10, (1024, 10), (1, 1024), 0), alpha=1, beta=1, out=buf10) del primals_11 buf13 = empty_strided_cuda((4, 10), (10, 1), torch.float32) triton_per_fused__log_softmax_5[grid(4)](buf10, buf13, 4, 10, XBLOCK=1, num_warps=2, num_stages=1) del buf10 return (buf13, primals_1, primals_3, buf0, primals_6, buf2, buf4, buf6, buf7, reinterpret_tensor(buf8, (4, 25088), (25088, 1), 0), buf9, buf13, primals_10, primals_8) class mnist_modelNew(nn.Module): def __init__(self): super(mnist_modelNew, self).__init__() self.conv1 = nn.Conv2d(1, 32, 3, 1, 0) self.conv2 = nn.Conv2d(32, 64, 3, 1, 0) self.conv3 = nn.Conv2d(64, 128, 1, 1, 0) self.pool1 = nn.MaxPool2d(2, 2, 0) self.fc1 = nn.Linear(128 * 14 * 14, 1024) self.fc2 = nn.Linear(1024, 10) self.relu = nn.ReLU() 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.fc1.weight primals_9 = self.fc1.bias primals_10 = self.fc2.weight primals_11 = self.fc2.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]) return output[0]
Xenovortex/INN_Embedding_Classification
mnist_model
false
1,302
[ "MIT" ]
0
df31ec3dcf70780cae5140a69ffafdd64f218e5f
https://github.com/Xenovortex/INN_Embedding_Classification/tree/df31ec3dcf70780cae5140a69ffafdd64f218e5f
ConvGLU
import torch from torch import nn import torch.utils.data import torch.optim def str2act(txt): """Translates text to neural network activation""" return {'sigmoid': nn.Sigmoid(), 'relu': nn.ReLU(), 'none': nn. Sequential(), 'lrelu': nn.LeakyReLU(0.2), 'selu': nn.SELU()}[txt. lower()] class ConvGLU(nn.Module): """ A convGlu operation, used by the Degli paper's model. """ def __init__(self, in_ch, out_ch, kernel_size=(7, 7), padding=None, batchnorm=False, act='sigmoid', stride=None): super().__init__() if not padding: padding = kernel_size[0] // 2, kernel_size[1] // 2 if stride is None: self.conv = nn.Conv2d(in_ch, out_ch * 2, kernel_size, padding= padding) else: self.conv = nn.Conv2d(in_ch, out_ch * 2, kernel_size, padding= padding, stride=stride) self.weight = self.conv.weight self.bias = self.conv.bias if batchnorm: self.conv = nn.Sequential(self.conv, nn.BatchNorm2d(out_ch * 2)) self.sigmoid = str2act(act) def forward(self, x): x = self.conv(x) ch = x.shape[1] x = x[:, :ch // 2, ...] * self.sigmoid(x[:, ch // 2:, ...]) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_ch': 4, 'out_ch': 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 import nn import torch.utils.data import torch.optim 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_convolution_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 512 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 16 % 8 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) @triton.jit def triton_poi_fused_mul_sigmoid_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 x1 = xindex // 64 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 128 * x1), xmask) tmp1 = tl.load(in_ptr0 + (64 + x0 + 128 * x1), xmask) tmp2 = tl.sigmoid(tmp1) tmp3 = tmp0 * tmp2 tl.store(out_ptr0 + x2, tmp3, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (8, 4, 7, 7), (196, 49, 7, 1)) assert_size_stride(primals_2, (8,), (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=(3, 3), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 8, 4, 4), (128, 16, 4, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(512)](buf1, primals_2, 512, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_mul_sigmoid_1[grid(256)](buf1, buf2, 256, XBLOCK= 256, num_warps=4, num_stages=1) return buf2, primals_1, primals_3, buf1 def str2act(txt): """Translates text to neural network activation""" return {'sigmoid': nn.Sigmoid(), 'relu': nn.ReLU(), 'none': nn. Sequential(), 'lrelu': nn.LeakyReLU(0.2), 'selu': nn.SELU()}[txt. lower()] class ConvGLUNew(nn.Module): """ A convGlu operation, used by the Degli paper's model. """ def __init__(self, in_ch, out_ch, kernel_size=(7, 7), padding=None, batchnorm=False, act='sigmoid', stride=None): super().__init__() if not padding: padding = kernel_size[0] // 2, kernel_size[1] // 2 if stride is None: self.conv = nn.Conv2d(in_ch, out_ch * 2, kernel_size, padding= padding) else: self.conv = nn.Conv2d(in_ch, out_ch * 2, kernel_size, padding= padding, stride=stride) self.weight = self.conv.weight self.bias = self.conv.bias if batchnorm: self.conv = nn.Sequential(self.conv, nn.BatchNorm2d(out_ch * 2)) self.sigmoid = str2act(act) def forward(self, input_0): primals_1 = self.weight primals_2 = self.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
Zenodia/NeMo
ConvGLU
false
1,303
[ "Apache-2.0" ]
0
3c288d8a7caf667c95444c39434e3ebc5f53d911
https://github.com/Zenodia/NeMo/tree/3c288d8a7caf667c95444c39434e3ebc5f53d911
BertSelfAttention
from _paritybench_helpers import _mock_config import math import torch import torch.nn as nn class BertSelfAttention(nn.Module): def __init__(self, config): super(BertSelfAttention, self).__init__() if config.hidden_size % config.num_attention_heads != 0: raise ValueError( 'The hidden size (%d) is not a multiple of the number of attention heads (%d)' % (config.hidden_size, config.num_attention_heads)) self.num_attention_heads = config.num_attention_heads self.attention_head_size = int(config.hidden_size / config. num_attention_heads) self.all_head_size = (self.num_attention_heads * self. attention_head_size) self.query = nn.Linear(config.hidden_size, self.all_head_size) self.key = nn.Linear(config.hidden_size, self.all_head_size) self.value = nn.Linear(config.hidden_size, self.all_head_size) self.dropout = nn.Dropout(config.attention_probs_dropout_prob) def transpose_for_scores(self, x): new_x_shape = x.size()[:-1] + (self.num_attention_heads, self. attention_head_size) x = x.view(*new_x_shape) return x.permute(0, 2, 1, 3) def forward(self, hidden_states, attention_mask): mixed_query_layer = self.query(hidden_states) mixed_key_layer = self.key(hidden_states) mixed_value_layer = self.value(hidden_states) query_layer = self.transpose_for_scores(mixed_query_layer) key_layer = self.transpose_for_scores(mixed_key_layer) value_layer = self.transpose_for_scores(mixed_value_layer) attention_scores = torch.matmul(query_layer, key_layer.transpose(-1, -2)) attention_scores = attention_scores / math.sqrt(self. attention_head_size) attention_scores = attention_scores + attention_mask attention_probs = nn.Softmax(dim=-1)(attention_scores) attention_probs = self.dropout(attention_probs) context_layer = torch.matmul(attention_probs, value_layer) context_layer = context_layer.permute(0, 2, 1, 3).contiguous() new_context_layer_shape = context_layer.size()[:-2] + (self. all_head_size,) context_layer = context_layer.view(*new_context_layer_shape) return context_layer def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'config': _mock_config(hidden_size=4, num_attention_heads= 4, attention_probs_dropout_prob=0.5)}]
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 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_0(in_ptr0, in_ptr1, 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') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 1.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + (x2 + 4 * y3), tmp4, xmask & ymask) @triton.jit def triton_poi_fused_1(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, 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 + 4 * x2, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x2), 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 * x2), 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 * x2), 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 tmp26 = float('-inf') tmp27 = tmp2 == tmp26 tmp28 = tmp27 == 0 tmp29 = tmp28.to(tl.int64) tmp30 = tmp29 != 0 tmp31 = tmp5 == tmp26 tmp32 = tmp31 == 0 tmp33 = tmp32.to(tl.int64) tmp34 = tmp33 != 0 tmp35 = tmp30 | tmp34 tmp36 = tmp9 == tmp26 tmp37 = tmp36 == 0 tmp38 = tmp37.to(tl.int64) tmp39 = tmp38 != 0 tmp40 = tmp35 | tmp39 tmp41 = tmp13 == tmp26 tmp42 = tmp41 == 0 tmp43 = tmp42.to(tl.int64) tmp44 = tmp43 != 0 tmp45 = tmp40 | tmp44 tl.store(out_ptr0 + x2, tmp14, xmask) tl.store(out_ptr1 + x2, tmp25, xmask) tl.store(out_ptr2 + x2, tmp45, xmask) @triton.jit def triton_poi_fused_2(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, in_ptr3, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex // 4 x4 = xindex x5 = xindex % 64 tmp0 = tl.load(in_ptr0 + x3, xmask, eviction_policy='evict_last').to(tl .int1) tmp2 = tl.load(in_out_ptr0 + x4, xmask) tmp3 = tl.load(in_ptr1 + x5, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr2 + x3, xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr3 + x3, xmask, eviction_policy='evict_last') tmp1 = tmp0 == 0 tmp4 = tmp2 + tmp3 tmp6 = tmp4 - tmp5 tmp7 = tl_math.exp(tmp6) tmp9 = tmp7 / tmp8 tmp10 = 0.0 tmp11 = tl.where(tmp1, tmp10, tmp9) tl.store(in_out_ptr0 + x4, tmp11, xmask) @triton.jit def triton_poi_fused_3(in_ptr0, in_ptr1, 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') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + (x2 + 4 * y3), tmp2, xmask & ymask) @triton.jit def triton_poi_fused_clone_4(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) 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,), (1,)) assert_size_stride(primals_3, (4, 4, 4), (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), (16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf2) del primals_6 buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused_0[grid(16, 4)](buf0, primals_2, buf3, 16, 4, XBLOCK=4, YBLOCK=8, num_warps=1, num_stages=1) del primals_2 buf4 = reinterpret_tensor(buf0, (4, 4, 1, 4), (16, 4, 4, 1), 0) del buf0 triton_poi_fused_0[grid(16, 4)](buf1, primals_5, buf4, 16, 4, XBLOCK=4, YBLOCK=8, num_warps=1, num_stages=1) del primals_5 buf5 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf3, (16, 4, 1), (4, 1, 0), 0), reinterpret_tensor(buf4, (16, 1, 4), (4, 0, 1), 0), out=buf5) buf6 = reinterpret_tensor(buf1, (4, 4, 4, 1), (16, 4, 1, 64), 0) del buf1 buf7 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) buf8 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.bool) triton_poi_fused_1[grid(64)](buf5, primals_8, buf6, buf7, buf8, 64, XBLOCK=64, num_warps=1, num_stages=1) buf9 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused_2[grid(256)](buf9, buf8, primals_8, buf6, buf7, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf8 del primals_8 buf10 = reinterpret_tensor(buf7, (4, 4, 4, 1), (16, 4, 1, 1), 0) del buf7 triton_poi_fused_3[grid(16, 4)](buf2, primals_7, buf10, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del primals_7 buf11 = reinterpret_tensor(buf2, (16, 4, 1), (4, 1, 1), 0) del buf2 extern_kernels.bmm(reinterpret_tensor(buf9, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(buf10, (16, 4, 1), (4, 1, 0), 0), out=buf11) buf12 = reinterpret_tensor(buf6, (4, 4, 4, 1), (16, 4, 1, 1), 0) del buf6 triton_poi_fused_clone_4[grid(16, 4)](buf11, buf12, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del buf11 return reinterpret_tensor(buf12, (4, 4, 4), (16, 4, 1), 0 ), reinterpret_tensor(primals_3, (16, 4), (4, 1), 0 ), buf9, reinterpret_tensor(buf10, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf3, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf4, (16, 4, 1), (4, 1, 4), 0) class BertSelfAttentionNew(nn.Module): def __init__(self, config): super(BertSelfAttentionNew, self).__init__() if config.hidden_size % config.num_attention_heads != 0: raise ValueError( 'The hidden size (%d) is not a multiple of the number of attention heads (%d)' % (config.hidden_size, config.num_attention_heads)) self.num_attention_heads = config.num_attention_heads self.attention_head_size = int(config.hidden_size / config. num_attention_heads) self.all_head_size = (self.num_attention_heads * self. attention_head_size) self.query = nn.Linear(config.hidden_size, self.all_head_size) self.key = nn.Linear(config.hidden_size, self.all_head_size) self.value = nn.Linear(config.hidden_size, self.all_head_size) self.dropout = nn.Dropout(config.attention_probs_dropout_prob) def transpose_for_scores(self, x): new_x_shape = x.size()[:-1] + (self.num_attention_heads, self. attention_head_size) x = x.view(*new_x_shape) return x.permute(0, 2, 1, 3) def forward(self, input_0, input_1): primals_1 = self.query.weight primals_2 = self.query.bias primals_4 = self.key.weight primals_5 = self.key.bias primals_6 = self.value.weight primals_7 = self.value.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]) return output[0]
Andr3wis2Cool4School/AI-pro
BertSelfAttention
false
1,304
[ "MIT" ]
0
dfe5f5959bc187d899a86f13b84158c66f64d1cc
https://github.com/Andr3wis2Cool4School/AI-pro/tree/dfe5f5959bc187d899a86f13b84158c66f64d1cc
ResidualBlock_noBN
import torch import torch.nn as nn import torch.nn.functional as F import torch.nn.init as init def initialize_weights(net_l, scale=1): if not isinstance(net_l, list): net_l = [net_l] for net in net_l: for m in net.modules(): if isinstance(m, nn.Conv2d): init.kaiming_normal_(m.weight, a=0, mode='fan_in') m.weight.data *= scale if m.bias is not None: m.bias.data.zero_() elif isinstance(m, nn.Linear): init.kaiming_normal_(m.weight, a=0, mode='fan_in') m.weight.data *= scale if m.bias is not None: m.bias.data.zero_() elif isinstance(m, nn.BatchNorm2d): init.constant_(m.weight, 1) init.constant_(m.bias.data, 0.0) class ResidualBlock_noBN(nn.Module): """Residual block w/o BN ---Conv-ReLU-Conv-+- |________________| """ def __init__(self, nf=64): super(ResidualBlock_noBN, self).__init__() self.conv1 = nn.Conv2d(nf, nf, 3, 1, 1, bias=True) self.conv2 = nn.Conv2d(nf, nf, 3, 1, 1, bias=True) initialize_weights([self.conv1, self.conv2], 0.1) def forward(self, x): identity = x out = F.relu(self.conv1(x), inplace=True) out = self.conv2(out) return identity + out 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.nn.init as init assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_relu_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) x3 = xindex x1 = xindex // 4096 % 64 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_add_convolution_1(in_out_ptr0, in_ptr0, in_ptr1, 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 // 4096 % 64 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_out_ptr0 + x3, None) tmp2 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = tmp0 + tmp3 tl.store(in_out_ptr0 + x3, tmp4, None) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_2, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_3, (64,), (1,)) assert_size_stride(primals_4, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_1, primals_2, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 64, 64, 64), (262144, 4096, 64, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(1048576)](buf1, primals_3, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_3 buf2 = extern_kernels.convolution(buf1, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 64, 64, 64), (262144, 4096, 64, 1)) buf3 = buf2 del buf2 triton_poi_fused_add_convolution_1[grid(1048576)](buf3, primals_1, primals_5, 1048576, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 return buf3, primals_1, primals_2, primals_4, buf1 def initialize_weights(net_l, scale=1): if not isinstance(net_l, list): net_l = [net_l] for net in net_l: for m in net.modules(): if isinstance(m, nn.Conv2d): init.kaiming_normal_(m.weight, a=0, mode='fan_in') m.weight.data *= scale if m.bias is not None: m.bias.data.zero_() elif isinstance(m, nn.Linear): init.kaiming_normal_(m.weight, a=0, mode='fan_in') m.weight.data *= scale if m.bias is not None: m.bias.data.zero_() elif isinstance(m, nn.BatchNorm2d): init.constant_(m.weight, 1) init.constant_(m.bias.data, 0.0) class ResidualBlock_noBNNew(nn.Module): """Residual block w/o BN ---Conv-ReLU-Conv-+- |________________| """ def __init__(self, nf=64): super(ResidualBlock_noBNNew, self).__init__() self.conv1 = nn.Conv2d(nf, nf, 3, 1, 1, bias=True) self.conv2 = nn.Conv2d(nf, nf, 3, 1, 1, bias=True) initialize_weights([self.conv1, self.conv2], 0.1) def forward(self, input_0): primals_2 = self.conv1.weight primals_3 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
YingqiLiulll/scrips_for_SR
ResidualBlock_noBN
false
1,306
[ "MIT" ]
0
04fa6fdaf157e913d3e2521cd80315a10a2ccedc
https://github.com/YingqiLiulll/scrips_for_SR/tree/04fa6fdaf157e913d3e2521cd80315a10a2ccedc
AttentionPool2d
import math import torch import numpy as np import torch as th import torch.nn as nn def count_flops_attn(model, _x, y): """ A counter for the `thop` package to count the operations in an attention operation. Meant to be used like: macs, params = thop.profile( model, inputs=(inputs, timestamps), custom_ops={QKVAttention: QKVAttention.count_flops}, ) """ b, c, *spatial = y[0].shape num_spatial = int(np.prod(spatial)) matmul_ops = 2 * b * num_spatial ** 2 * c model.total_ops += th.DoubleTensor([matmul_ops]) def conv_nd(dims, *args, **kwargs): """ Create a 1D, 2D, or 3D convolution module. """ if dims == 1: return nn.Conv1d(*args, **kwargs) elif dims == 2: return nn.Conv2d(*args, **kwargs) elif dims == 3: return nn.Conv3d(*args, **kwargs) raise ValueError(f'unsupported dimensions: {dims}') class QKVAttention(nn.Module): """ A module which performs QKV attention and splits in a different order. """ def __init__(self, n_heads): super().__init__() self.n_heads = n_heads def forward(self, qkv): """ Apply QKV attention. :param qkv: an [N x (3 * H * C) x T] tensor of Qs, Ks, and Vs. :return: an [N x (H * C) x T] tensor after attention. """ bs, width, length = qkv.shape assert width % (3 * self.n_heads) == 0 ch = width // (3 * self.n_heads) q, k, v = qkv.chunk(3, dim=1) scale = 1 / math.sqrt(math.sqrt(ch)) weight = th.einsum('bct,bcs->bts', (q * scale).view(bs * self. n_heads, ch, length), (k * scale).view(bs * self.n_heads, ch, length)) weight = th.softmax(weight.float(), dim=-1).type(weight.dtype) a = th.einsum('bts,bcs->bct', weight, v.reshape(bs * self.n_heads, ch, length)) return a.reshape(bs, -1, length) @staticmethod def count_flops(model, _x, y): return count_flops_attn(model, _x, y) class AttentionPool2d(nn.Module): """ Adapted from CLIP: https://github.com/openai/CLIP/blob/main/clip/model.py """ def __init__(self, spacial_dim: 'int', embed_dim: 'int', num_heads_channels: 'int', output_dim: 'int'=None): super().__init__() self.positional_embedding = nn.Parameter(th.randn(embed_dim, spacial_dim ** 2 + 1) / embed_dim ** 0.5) self.qkv_proj = conv_nd(1, embed_dim, 3 * embed_dim, 1) self.c_proj = conv_nd(1, embed_dim, output_dim or embed_dim, 1) self.num_heads = embed_dim // num_heads_channels self.attention = QKVAttention(self.num_heads) def forward(self, x): b, c, *_spatial = x.shape x = x.reshape(b, c, -1) x = th.cat([x.mean(dim=-1, keepdim=True), x], dim=-1) x = x + self.positional_embedding[None, :, :] x = self.qkv_proj(x) x = self.attention(x) x = self.c_proj(x) return x[:, :, 0] def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'spacial_dim': 4, 'embed_dim': 4, 'num_heads_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._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import math as tl_math import math import numpy as np import torch as th 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_per_fused_mean_0(in_ptr0, out_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 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, 0) tmp4 = tl.sum(tmp3, 1)[:, None] tl.store(out_ptr0 + x0, tmp4, xmask) @triton.jit def triton_poi_fused_add_cat_1(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 272 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 17 x3 = xindex // 17 x4 = xindex % 68 x5 = xindex tmp15 = tl.load(in_ptr2 + x4, xmask, eviction_policy='evict_last') tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 1, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + x3, tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp6 = 16.0 tmp7 = tmp5 / tmp6 tmp8 = tl.full(tmp7.shape, 0.0, tmp7.dtype) tmp9 = tl.where(tmp4, tmp7, tmp8) tmp10 = tmp0 >= tmp3 tl.full([1], 17, tl.int64) tmp13 = tl.load(in_ptr1 + (16 * x3 + (-1 + x0)), tmp10 & xmask, eviction_policy='evict_last', other=0.0) tmp14 = tl.where(tmp4, tmp9, tmp13) tmp16 = tmp14 + tmp15 tl.store(out_ptr0 + x5, tmp16, xmask) @triton.jit def triton_poi_fused_mul_2(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 272 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex // 68 x3 = xindex % 68 x1 = xindex // 17 % 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (x3 + 204 * x2), xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.7071067811865475 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x4, tmp4, xmask) @triton.jit def triton_poi_fused_mul_3(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 272 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex // 68 x3 = xindex % 68 x1 = xindex // 17 % 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (68 + x3 + 204 * x2), xmask) tmp1 = tl.load(in_ptr1 + (4 + x1), xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.7071067811865475 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + x4, tmp4, xmask) @triton.jit def triton_per_fused__softmax_4(in_ptr0, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 68 rnumel = 17 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, :] rmask = rindex < rnumel r1 = rindex x0 = xindex tmp0 = tl.load(in_ptr0 + (r1 + 17 * x0), rmask & xmask, other=0.0) tmp1 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(rmask & xmask, tmp1, float('-inf')) tmp4 = triton_helpers.max2(tmp3, 1)[:, None] tmp5 = tmp0 - tmp4 tmp6 = tl_math.exp(tmp5) tmp7 = tl.broadcast_to(tmp6, [XBLOCK, RBLOCK]) tmp9 = tl.where(rmask & xmask, tmp7, 0) tmp10 = tl.sum(tmp9, 1)[:, None] tmp11 = tmp6 / tmp10 tl.store(out_ptr2 + (r1 + 17 * x0), tmp11, rmask & xmask) @triton.jit def triton_poi_fused_convolution_5(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 816 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 17 % 12 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) @triton.jit def triton_poi_fused_convolution_6(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 17 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 + 68 * y1), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 17 * y3), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_convolution_7(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 272 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 17 % 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, 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, 17), (17, 1)) assert_size_stride(primals_3, (12, 4, 1), (4, 1, 1)) assert_size_stride(primals_4, (12,), (1,)) assert_size_stride(primals_5, (4, 4, 1), (4, 1, 1)) assert_size_stride(primals_6, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) get_raw_stream(0) triton_per_fused_mean_0[grid(16)](primals_1, buf0, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) buf1 = empty_strided_cuda((4, 4, 17), (68, 17, 1), torch.float32) triton_poi_fused_add_cat_1[grid(272)](buf0, primals_1, primals_2, buf1, 272, XBLOCK=128, num_warps=4, num_stages=1) del buf0 del primals_1 del primals_2 buf2 = extern_kernels.convolution(buf1, primals_3, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf2, (4, 12, 17), (204, 17, 1)) buf3 = empty_strided_cuda((4, 4, 17), (68, 17, 1), torch.float32) triton_poi_fused_mul_2[grid(272)](buf2, primals_4, buf3, 272, XBLOCK=128, num_warps=4, num_stages=1) buf4 = empty_strided_cuda((4, 4, 17), (68, 17, 1), torch.float32) triton_poi_fused_mul_3[grid(272)](buf2, primals_4, buf4, 272, XBLOCK=256, num_warps=4, num_stages=1) buf5 = empty_strided_cuda((4, 17, 17), (289, 17, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf3, (4, 17, 4), (68, 1, 17), 0), buf4, out=buf5) buf8 = empty_strided_cuda((4, 17, 17), (289, 17, 1), torch.float32) triton_per_fused__softmax_4[grid(68)](buf5, buf8, 68, 17, XBLOCK=8, num_warps=2, num_stages=1) del buf5 buf9 = buf2 del buf2 triton_poi_fused_convolution_5[grid(816)](buf9, primals_4, 816, XBLOCK=256, num_warps=4, num_stages=1) del primals_4 buf10 = empty_strided_cuda((4, 17, 4), (68, 4, 1), torch.float32) extern_kernels.bmm(buf8, reinterpret_tensor(buf9, (4, 17, 4), (204, 1, 17), 136), out=buf10) buf11 = empty_strided_cuda((4, 4, 17), (68, 17, 1), torch.float32) triton_poi_fused_convolution_6[grid(16, 17)](buf10, buf11, 16, 17, XBLOCK=32, YBLOCK=16, num_warps=4, num_stages=1) buf12 = extern_kernels.convolution(buf11, primals_5, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf12, (4, 4, 17), (68, 17, 1)) del buf11 buf13 = buf12 del buf12 triton_poi_fused_convolution_7[grid(272)](buf13, primals_6, 272, XBLOCK=256, num_warps=4, num_stages=1) del primals_6 return reinterpret_tensor(buf13, (4, 4), (68, 17), 0 ), primals_3, primals_5, buf1, buf8, reinterpret_tensor(buf10, (4, 4, 17), (68, 1, 4), 0), reinterpret_tensor(buf9, (4, 4, 17), (204, 17, 1), 136), buf3, reinterpret_tensor(buf4, (4, 17, 4), (68, 1, 17), 0 ) def count_flops_attn(model, _x, y): """ A counter for the `thop` package to count the operations in an attention operation. Meant to be used like: macs, params = thop.profile( model, inputs=(inputs, timestamps), custom_ops={QKVAttention: QKVAttention.count_flops}, ) """ b, c, *spatial = y[0].shape num_spatial = int(np.prod(spatial)) matmul_ops = 2 * b * num_spatial ** 2 * c model.total_ops += th.DoubleTensor([matmul_ops]) def conv_nd(dims, *args, **kwargs): """ Create a 1D, 2D, or 3D convolution module. """ if dims == 1: return nn.Conv1d(*args, **kwargs) elif dims == 2: return nn.Conv2d(*args, **kwargs) elif dims == 3: return nn.Conv3d(*args, **kwargs) raise ValueError(f'unsupported dimensions: {dims}') class QKVAttention(nn.Module): """ A module which performs QKV attention and splits in a different order. """ def __init__(self, n_heads): super().__init__() self.n_heads = n_heads def forward(self, qkv): """ Apply QKV attention. :param qkv: an [N x (3 * H * C) x T] tensor of Qs, Ks, and Vs. :return: an [N x (H * C) x T] tensor after attention. """ bs, width, length = qkv.shape assert width % (3 * self.n_heads) == 0 ch = width // (3 * self.n_heads) q, k, v = qkv.chunk(3, dim=1) scale = 1 / math.sqrt(math.sqrt(ch)) weight = th.einsum('bct,bcs->bts', (q * scale).view(bs * self. n_heads, ch, length), (k * scale).view(bs * self.n_heads, ch, length)) weight = th.softmax(weight.float(), dim=-1).type(weight.dtype) a = th.einsum('bts,bcs->bct', weight, v.reshape(bs * self.n_heads, ch, length)) return a.reshape(bs, -1, length) @staticmethod def count_flops(model, _x, y): return count_flops_attn(model, _x, y) class AttentionPool2dNew(nn.Module): """ Adapted from CLIP: https://github.com/openai/CLIP/blob/main/clip/model.py """ def __init__(self, spacial_dim: 'int', embed_dim: 'int', num_heads_channels: 'int', output_dim: 'int'=None): super().__init__() self.positional_embedding = nn.Parameter(th.randn(embed_dim, spacial_dim ** 2 + 1) / embed_dim ** 0.5) self.qkv_proj = conv_nd(1, embed_dim, 3 * embed_dim, 1) self.c_proj = conv_nd(1, embed_dim, output_dim or embed_dim, 1) self.num_heads = embed_dim // num_heads_channels self.attention = QKVAttention(self.num_heads) def forward(self, input_0): primals_2 = self.positional_embedding primals_3 = self.qkv_proj.weight primals_4 = self.qkv_proj.bias primals_5 = self.c_proj.weight primals_6 = self.c_proj.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6]) return output[0]
ZGCTroy/guided-diffusion
AttentionPool2d
false
1,307
[ "MIT" ]
0
af987bb2b65db2875148a5466df79736ea5ae6a1
https://github.com/ZGCTroy/guided-diffusion/tree/af987bb2b65db2875148a5466df79736ea5ae6a1
MaxPoolBlock
import torch import torch.nn as nn class Block(nn.Module): def __init__(self): """Initialisation for a lower-level DeepLPF conv block :returns: N/A :rtype: N/A """ super(Block, self).__init__() def conv3x3(self, in_channels, out_channels, stride=1): """Represents a convolution of shape 3x3 :param in_channels: number of input channels :param out_channels: number of output channels :param stride: the convolution stride :returns: convolution function with the specified parameterisation :rtype: function """ return nn.Conv2d(in_channels, out_channels, kernel_size=3, stride= stride, padding=1, bias=True) class MaxPoolBlock(Block, nn.Module): def __init__(self): """Initialise function for the max pooling block :returns: N/A :rtype: N/A """ super(Block, self).__init__() self.max_pool = nn.MaxPool2d(kernel_size=2, stride=2) def forward(self, x): """ Forward function for the max pooling block :param x: Tensor representing the input BxCxWxH, where B is the batch size, C is the number of channels, W and H are the width and image height :returns: Tensor representing the output of the block :rtype: Tensor """ img_out = self.max_pool(x) return img_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.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_max_pool2d_with_indices_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 % 2 x1 = xindex // 2 x2 = xindex tmp0 = tl.load(in_ptr0 + (2 * x0 + 8 * x1), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr0 + (1 + 2 * x0 + 8 * x1), xmask, eviction_policy= 'evict_last') tmp3 = tl.load(in_ptr0 + (4 + 2 * x0 + 8 * x1), xmask, eviction_policy= 'evict_last') tmp5 = tl.load(in_ptr0 + (5 + 2 * x0 + 8 * x1), 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 + x2, tmp6, 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, 2, 2), (16, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_max_pool2d_with_indices_0[grid(64)](arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 return buf0, class Block(nn.Module): def __init__(self): """Initialisation for a lower-level DeepLPF conv block :returns: N/A :rtype: N/A """ super(Block, self).__init__() def conv3x3(self, in_channels, out_channels, stride=1): """Represents a convolution of shape 3x3 :param in_channels: number of input channels :param out_channels: number of output channels :param stride: the convolution stride :returns: convolution function with the specified parameterisation :rtype: function """ return nn.Conv2d(in_channels, out_channels, kernel_size=3, stride= stride, padding=1, bias=True) class MaxPoolBlockNew(Block, nn.Module): def __init__(self): """Initialise function for the max pooling block :returns: N/A :rtype: N/A """ super(Block, self).__init__() self.max_pool = nn.MaxPool2d(kernel_size=2, stride=2) def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
ZombaSY/DeepLPF
MaxPoolBlock
false
1,310
[ "BSD-3-Clause" ]
0
adce64ae01bc9e32f465a354cb1f6534f0d13597
https://github.com/ZombaSY/DeepLPF/tree/adce64ae01bc9e32f465a354cb1f6534f0d13597
NumericalFeaturesEmbedding
import torch import torch.utils.tensorboard import torch.utils.data import torch.distributed class NumericalFeaturesEmbedding(torch.nn.Module): """Transform a sequence of numerical feature vectors into a single vector. Currently, this module simply aggregates the features by averaging, although more elaborate aggregation schemes (e.g. RNN) could be chosen. """ def __init__(self, embedding_dim): super(NumericalFeaturesEmbedding, self).__init__() self.embedding_dim = embedding_dim def forward(self, embeddings): return embeddings.mean(axis=-2) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'embedding_dim': 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.utils.tensorboard import torch.utils.data import torch.distributed 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_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 % 4 x1 = xindex // 4 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 16 * x1), xmask) tmp1 = tl.load(in_ptr0 + (4 + x0 + 16 * x1), xmask) tmp3 = tl.load(in_ptr0 + (8 + x0 + 16 * x1), xmask) tmp5 = tl.load(in_ptr0 + (12 + x0 + 16 * x1), xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp7 = 4.0 tmp8 = tmp6 / 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), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_mean_0[grid(64)](arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 return buf0, class NumericalFeaturesEmbeddingNew(torch.nn.Module): """Transform a sequence of numerical feature vectors into a single vector. Currently, this module simply aggregates the features by averaging, although more elaborate aggregation schemes (e.g. RNN) could be chosen. """ def __init__(self, embedding_dim): super(NumericalFeaturesEmbeddingNew, self).__init__() self.embedding_dim = embedding_dim def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
JoeLambourne/SketchGraphs
NumericalFeaturesEmbedding
false
1,312
[ "MIT" ]
0
183c65f82d71d82c62b253092e9b7fa65846a3e6
https://github.com/JoeLambourne/SketchGraphs/tree/183c65f82d71d82c62b253092e9b7fa65846a3e6
BinaryLayer
import torch import torch.nn as nn class BinaryLayer(nn.Module): def forward(self, input): """Forward function for binary layer :param input: data :returns: sign of data :rtype: Tensor """ return torch.sign(input) def backward(self, grad_output): """Straight through estimator :param grad_output: gradient tensor :returns: truncated gradient tensor :rtype: Tensor """ input = self.saved_tensors grad_output[input > 1] = 0 grad_output[input < -1] = 0 return grad_output 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 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_sign_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], 0, tl.int32) tmp2 = tmp1 < tmp0 tmp3 = tmp2.to(tl.int8) tmp4 = tmp0 < tmp1 tmp5 = tmp4.to(tl.int8) tmp6 = tmp3 - tmp5 tmp7 = tmp6.to(tmp0.dtype) tl.store(out_ptr0 + x0, tmp7, 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_sign_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class BinaryLayerNew(nn.Module): def backward(self, grad_output): """Straight through estimator :param grad_output: gradient tensor :returns: truncated gradient tensor :rtype: Tensor """ input = self.saved_tensors grad_output[input > 1] = 0 grad_output[input < -1] = 0 return grad_output def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
ZombaSY/DeepLPF
BinaryLayer
false
1,314
[ "BSD-3-Clause" ]
0
adce64ae01bc9e32f465a354cb1f6534f0d13597
https://github.com/ZombaSY/DeepLPF/tree/adce64ae01bc9e32f465a354cb1f6534f0d13597
Critic
import torch import torch.nn as nn import torch.nn.functional as F class Critic(nn.Module): def __init__(self, numberOfInputs): super(Critic, self).__init__() self.fc1 = nn.Linear(numberOfInputs, 4096) self.fc2 = nn.Linear(4096, 2048) self.fc3 = nn.Linear(2048, 1024) self.fc4 = nn.Linear(1024, 512) self.fc5 = nn.Linear(512, 256) self.state_value = nn.Linear(256, 1) def forward(self, x): x = F.relu(self.fc1(x)) x = F.relu(self.fc2(x)) x = F.relu(self.fc3(x)) x = F.relu(self.fc4(x)) x = F.relu(self.fc5(x)) value = self.state_value(x) return value def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'numberOfInputs': 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 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): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 4096 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_1(in_out_ptr0, 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) x2 = xindex x0 = xindex % 2048 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_2(in_out_ptr0, 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) x2 = xindex x0 = xindex % 1024 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_3(in_out_ptr0, 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) x2 = xindex x0 = xindex % 512 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_4(in_out_ptr0, 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) 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 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, None) tl.store(out_ptr0 + x2, tmp6, None) 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, (4096, 4), (4, 1)) assert_size_stride(primals_2, (4096,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (2048, 4096), (4096, 1)) assert_size_stride(primals_5, (2048,), (1,)) assert_size_stride(primals_6, (1024, 2048), (2048, 1)) assert_size_stride(primals_7, (1024,), (1,)) assert_size_stride(primals_8, (512, 1024), (1024, 1)) assert_size_stride(primals_9, (512,), (1,)) assert_size_stride(primals_10, (256, 512), (512, 1)) assert_size_stride(primals_11, (256,), (1,)) assert_size_stride(primals_12, (1, 256), (256, 1)) assert_size_stride(primals_13, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4096), (4096, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4096), (1, 4), 0), out=buf0) del primals_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4096), (65536, 16384, 4096, 1), 0) del buf0 buf16 = empty_strided_cuda((4, 4, 4, 4096), (65536, 16384, 4096, 1), torch.bool) get_raw_stream(0) triton_poi_fused_relu_threshold_backward_0[grid(262144)](buf1, primals_2, buf16, 262144, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 2048), (2048, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf1, (64, 4096), (4096, 1), 0 ), reinterpret_tensor(primals_4, (4096, 2048), (1, 4096), 0), out=buf2) buf3 = reinterpret_tensor(buf2, (4, 4, 4, 2048), (32768, 8192, 2048, 1), 0) del buf2 buf15 = empty_strided_cuda((4, 4, 4, 2048), (32768, 8192, 2048, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(131072)](buf3, primals_5, buf15, 131072, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf4 = empty_strided_cuda((64, 1024), (1024, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf3, (64, 2048), (2048, 1), 0 ), reinterpret_tensor(primals_6, (2048, 1024), (1, 2048), 0), out=buf4) buf5 = reinterpret_tensor(buf4, (4, 4, 4, 1024), (16384, 4096, 1024, 1), 0) del buf4 buf14 = empty_strided_cuda((4, 4, 4, 1024), (16384, 4096, 1024, 1), torch.bool) triton_poi_fused_relu_threshold_backward_2[grid(65536)](buf5, primals_7, buf14, 65536, XBLOCK=512, num_warps=4, num_stages=1) del primals_7 buf6 = empty_strided_cuda((64, 512), (512, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf5, (64, 1024), (1024, 1), 0 ), reinterpret_tensor(primals_8, (1024, 512), (1, 1024), 0), out=buf6) buf7 = reinterpret_tensor(buf6, (4, 4, 4, 512), (8192, 2048, 512, 1), 0 ) del buf6 buf13 = empty_strided_cuda((4, 4, 4, 512), (8192, 2048, 512, 1), torch.bool) triton_poi_fused_relu_threshold_backward_3[grid(32768)](buf7, primals_9, buf13, 32768, XBLOCK=128, num_warps=4, num_stages=1) del primals_9 buf8 = empty_strided_cuda((64, 256), (256, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf7, (64, 512), (512, 1), 0), reinterpret_tensor(primals_10, (512, 256), (1, 512), 0), out=buf8) buf9 = reinterpret_tensor(buf8, (4, 4, 4, 256), (4096, 1024, 256, 1), 0 ) del buf8 buf12 = empty_strided_cuda((4, 4, 4, 256), (4096, 1024, 256, 1), torch.bool) triton_poi_fused_relu_threshold_backward_4[grid(16384)](buf9, primals_11, buf12, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_11 buf11 = empty_strided_cuda((64, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_13, reinterpret_tensor(buf9, (64, 256), (256, 1), 0), reinterpret_tensor(primals_12, (256, 1), (1, 256), 0), alpha=1, beta=1, out=buf11) del primals_13 return (reinterpret_tensor(buf11, (4, 4, 4, 1), (16, 4, 1, 1), 0), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(buf1, (64, 4096), (4096, 1), 0), reinterpret_tensor(buf3, (64, 2048), (2048, 1), 0), reinterpret_tensor(buf5, (64, 1024), (1024, 1), 0), reinterpret_tensor(buf7, (64, 512), (512, 1), 0), reinterpret_tensor(buf9, (64, 256), (256, 1), 0), primals_12, buf12, primals_10, buf13, primals_8, buf14, primals_6, buf15, primals_4, buf16 ) class CriticNew(nn.Module): def __init__(self, numberOfInputs): super(CriticNew, self).__init__() self.fc1 = nn.Linear(numberOfInputs, 4096) self.fc2 = nn.Linear(4096, 2048) self.fc3 = nn.Linear(2048, 1024) self.fc4 = nn.Linear(1024, 512) self.fc5 = nn.Linear(512, 256) self.state_value = nn.Linear(256, 1) def forward(self, input_0): primals_1 = self.fc1.weight primals_2 = self.fc1.bias primals_4 = self.fc2.weight primals_5 = self.fc2.bias primals_6 = self.fc3.weight primals_7 = self.fc3.bias primals_8 = self.fc4.weight primals_9 = self.fc4.bias primals_10 = self.fc5.weight primals_11 = self.fc5.bias primals_12 = self.state_value.weight primals_13 = self.state_value.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]) return output[0]
ZY-KK/panda
Critic
false
1,315
[ "MIT" ]
0
48fcbd65d563ef74aab2554be8de7662560c43da
https://github.com/ZY-KK/panda/tree/48fcbd65d563ef74aab2554be8de7662560c43da
FC2LayersShortcut
import torch import torch.nn as nn import torch.nn.functional as F class FC2LayersShortcut(nn.Module): def __init__(self, n_in, n_hidden, n_out, activation=F.relu): super(FC2LayersShortcut, self).__init__() self.fc1 = nn.Linear(n_in, n_hidden) self.fc2 = nn.Linear(n_hidden + n_in, n_out) self.activation = activation def forward(self, x): h = self.activation(self.fc1(x)) h = torch.cat((h, x), 1) x = self.fc2(h) return x def get_inputs(): return [torch.rand([4, 4])] def get_init_inputs(): return [[], {'n_in': 4, 'n_hidden': 4, 'n_out': 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 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_cat_0(in_ptr0, in_ptr1, in_ptr2, 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 = tl.load(in_ptr1 + x0, tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp7 = tmp5 + tmp6 tmp8 = tl.full([1], 0, tl.int32) tmp9 = triton_helpers.maximum(tmp8, tmp7) tmp10 = tl.full(tmp9.shape, 0.0, tmp9.dtype) tmp11 = tl.where(tmp4, tmp9, tmp10) tmp12 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp15 = tl.load(in_ptr2 + (4 * x1 + (-4 + x0)), tmp12 & xmask, eviction_policy='evict_last', other=0.0) tmp16 = tl.where(tmp4, tmp11, tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused_relu_threshold_backward_1(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_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + 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(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, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4), (4, 1)) assert_size_stride(primals_4, (4, 8), (8, 1)) assert_size_stride(primals_5, (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_3, reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = empty_strided_cuda((4, 8), (8, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(32)](buf0, primals_2, primals_3, buf1, 32, XBLOCK=32, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, buf1, reinterpret_tensor(primals_4, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf2) del primals_5 buf3 = empty_strided_cuda((4, 4), (4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(16)](buf0, primals_2, buf3, 16, XBLOCK=16, num_warps=1, num_stages=1) del buf0 del primals_2 return buf2, primals_3, buf1, primals_4, buf3 class FC2LayersShortcutNew(nn.Module): def __init__(self, n_in, n_hidden, n_out, activation=F.relu): super(FC2LayersShortcutNew, self).__init__() self.fc1 = nn.Linear(n_in, n_hidden) self.fc2 = nn.Linear(n_hidden + n_in, n_out) self.activation = activation def forward(self, input_0): primals_1 = self.fc1.weight primals_2 = self.fc1.bias primals_4 = self.fc2.weight primals_5 = self.fc2.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
ZhiangChen/vca
FC2LayersShortcut
false
1,316
[ "MIT" ]
0
22b7568ac1894a56e7e64443565f7e44e096d778
https://github.com/ZhiangChen/vca/tree/22b7568ac1894a56e7e64443565f7e44e096d778
EncoderImagePrecomp
import torch import numpy as np from collections import OrderedDict import torch.nn as nn import torch.nn.init def l2norm(x, dim=-1): return x / x.norm(2, dim=dim, keepdim=True).clamp(min=1e-06) class EncoderImagePrecomp(nn.Module): """ image encoder """ def __init__(self, img_dim, embed_size, no_imgnorm=False): super(EncoderImagePrecomp, self).__init__() self.embed_size = embed_size self.no_imgnorm = no_imgnorm self.fc = nn.Linear(img_dim, embed_size) self.init_weights() def init_weights(self): """ Xavier initialization for the fully connected layer """ r = np.sqrt(6.0) / np.sqrt(self.fc.in_features + self.fc.out_features) self.fc.weight.data.uniform_(-r, r) self.fc.bias.data.fill_(0) def forward(self, images): """ extract image feature vectors """ features = self.fc(images.float()) if not self.no_imgnorm: features = l2norm(features) return features def load_state_dict(self, state_dict): """ copies parameters, overwritting the default one to accept state_dict from Full model """ own_state = self.state_dict() new_state = OrderedDict() for name, param in state_dict.items(): if name in own_state: new_state[name] = param super(EncoderImagePrecomp, self).load_state_dict(new_state) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'img_dim': 4, 'embed_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 libdevice import numpy as np from collections import OrderedDict import torch.nn as nn import torch.nn.init 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_clamp_div_linalg_vector_norm_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') tmp3 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp2 = tmp1 * tmp1 tmp4 = tmp3 * tmp3 tmp5 = tmp2 + tmp4 tmp7 = tmp6 * tmp6 tmp8 = tmp5 + tmp7 tmp10 = tmp9 * tmp9 tmp11 = tmp8 + tmp10 tmp12 = libdevice.sqrt(tmp11) tmp13 = 1e-06 tmp14 = triton_helpers.maximum(tmp12, tmp13) tmp15 = tmp0 / tmp14 tl.store(out_ptr0 + x2, tmp15, 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, 4), (4, 1)) assert_size_stride(primals_3, (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_3, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), 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, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clamp_div_linalg_vector_norm_0[grid(256)](buf0, buf1, 256, XBLOCK=128, num_warps=4, num_stages=1) return buf1, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0), buf0 def l2norm(x, dim=-1): return x / x.norm(2, dim=dim, keepdim=True).clamp(min=1e-06) class EncoderImagePrecompNew(nn.Module): """ image encoder """ def __init__(self, img_dim, embed_size, no_imgnorm=False): super(EncoderImagePrecompNew, self).__init__() self.embed_size = embed_size self.no_imgnorm = no_imgnorm self.fc = nn.Linear(img_dim, embed_size) self.init_weights() def init_weights(self): """ Xavier initialization for the fully connected layer """ r = np.sqrt(6.0) / np.sqrt(self.fc.in_features + self.fc.out_features) self.fc.weight.data.uniform_(-r, r) self.fc.bias.data.fill_(0) def load_state_dict(self, state_dict): """ copies parameters, overwritting the default one to accept state_dict from Full model """ own_state = self.state_dict() new_state = OrderedDict() for name, param in state_dict.items(): if name in own_state: new_state[name] = param super(EncoderImagePrecompNew, self).load_state_dict(new_state) def forward(self, input_0): primals_2 = self.fc.weight primals_3 = self.fc.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
ZhouXing19/VGNSL_multilang
EncoderImagePrecomp
false
1,317
[ "MIT" ]
0
097ed7bf978dbff052075a26231984ade5522409
https://github.com/ZhouXing19/VGNSL_multilang/tree/097ed7bf978dbff052075a26231984ade5522409
InvConvNear
import torch from torch.nn import functional as F from torch import nn import torch.utils.data import torch.optim class InvConvNear(nn.Module): def __init__(self, channels, n_split=4, no_jacobian=False, **kwargs): super().__init__() assert n_split % 2 == 0 self.channels = channels self.n_split = n_split self.no_jacobian = no_jacobian w_init = torch.qr(torch.FloatTensor(self.n_split, self.n_split). normal_())[0] if torch.det(w_init) < 0: w_init[:, 0] = -1 * w_init[:, 0] self.weight = nn.Parameter(w_init) def forward(self, x, x_mask=None, reverse=False, **kwargs): b, c, t = x.size() assert c % self.n_split == 0 if x_mask is None: x_mask = 1 x_len = torch.ones((b,), dtype=x.dtype, device=x.device) * t else: x_len = torch.sum(x_mask, [1, 2]) x = x.view(b, 2, c // self.n_split, self.n_split // 2, t) x = x.permute(0, 1, 3, 2, 4).contiguous().view(b, self.n_split, c // self.n_split, t) if reverse: if hasattr(self, 'weight_inv'): weight = self.weight_inv else: weight = torch.inverse(self.weight.float()) logdet = None else: weight = self.weight if self.no_jacobian: logdet = 0 else: logdet = torch.logdet(self.weight) * (c / self.n_split) * x_len weight = weight.view(self.n_split, self.n_split, 1, 1) z = F.conv2d(x, weight) z = z.view(b, 2, self.n_split // 2, c // self.n_split, t) z = z.permute(0, 1, 3, 2, 4).contiguous().view(b, c, t) * x_mask return z, logdet def store_inverse(self): self.weight_inv = torch.inverse(self.weight.float()) def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'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 import nn import torch.utils.data import torch.optim 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_eq_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) tmp0 = tl.load(in_ptr0 + 0) tmp1 = tl.broadcast_to(tmp0, [XBLOCK]) tmp2 = -1.0 tmp3 = tmp1 == tmp2 tl.store(out_ptr0 + tl.full([XBLOCK], 0, tl.int32), tmp3, None) @triton.jit def triton_poi_fused_mul_scalar_tensor_where_1(in_ptr0, in_ptr1, 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 + 0).to(tl.int1) tmp1 = tl.broadcast_to(tmp0, [XBLOCK]) tmp2 = tl.load(in_ptr1 + 0) tmp3 = tl.broadcast_to(tmp2, [XBLOCK]) tmp4 = float('nan') tmp5 = tl.where(tmp1, tmp4, tmp3) tmp6 = 1.0 tmp7 = tmp5 * tmp6 tmp8 = 4.0 tmp9 = tmp7 * tmp8 tl.store(out_ptr0 + x0, tmp9, xmask) @triton.jit def triton_poi_fused_convolution_2(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 4 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 x1 = xindex y0 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * x1), xmask & ymask) tl.store(out_ptr0 + (x1 + 4 * y0), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_mul_3(in_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_out_ptr0 + x0, xmask) tmp1 = 1.0 tmp2 = tmp0 * tmp1 tl.store(in_out_ptr0 + x0, tmp2, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4), (1, 4)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = torch.ops.aten._linalg_slogdet.default(primals_2) buf1 = buf0[0] buf2 = buf0[1] buf3 = buf0[2] buf4 = buf0[3] del buf0 buf5 = empty_strided_cuda((), (), torch.bool) get_raw_stream(0) triton_poi_fused_eq_0[grid(1)](buf1, buf5, 1, XBLOCK=1, num_warps=1, num_stages=1) del buf1 buf6 = empty_strided_cuda((4,), (1,), torch.float32) triton_poi_fused_mul_scalar_tensor_where_1[grid(4)](buf5, buf2, buf6, 4, XBLOCK=4, num_warps=1, num_stages=1) del buf2 buf7 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.float32) triton_poi_fused_convolution_2[grid(4, 4)](primals_2, buf7, 4, 4, XBLOCK=4, YBLOCK=4, num_warps=1, num_stages=1) buf8 = extern_kernels.convolution(reinterpret_tensor(primals_1, (4, 4, 1, 4), (16, 4, 4, 1), 0), buf7, stride=(1, 1), padding=(0, 0 ), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf8, (4, 4, 1, 4), (16, 4, 4, 1)) del buf7 buf9 = reinterpret_tensor(buf8, (4, 4, 4), (16, 4, 1), 0) del buf8 triton_poi_fused_mul_3[grid(64)](buf9, 64, XBLOCK=64, num_warps=1, num_stages=1) return buf9, buf6, reinterpret_tensor(primals_1, (4, 4, 1, 4), (16, 4, 8, 1), 0), buf3, buf4, buf5, reinterpret_tensor(primals_2, (4, 4, 1, 1), (1, 4, 4, 4), 0) class InvConvNearNew(nn.Module): def __init__(self, channels, n_split=4, no_jacobian=False, **kwargs): super().__init__() assert n_split % 2 == 0 self.channels = channels self.n_split = n_split self.no_jacobian = no_jacobian w_init = torch.qr(torch.FloatTensor(self.n_split, self.n_split). normal_())[0] if torch.det(w_init) < 0: w_init[:, 0] = -1 * w_init[:, 0] self.weight = nn.Parameter(w_init) def store_inverse(self): self.weight_inv = torch.inverse(self.weight.float()) def forward(self, input_0): primals_2 = self.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0], output[1]
Zenodia/NeMo
InvConvNear
false
1,318
[ "Apache-2.0" ]
0
3c288d8a7caf667c95444c39434e3ebc5f53d911
https://github.com/Zenodia/NeMo/tree/3c288d8a7caf667c95444c39434e3ebc5f53d911
BCELosswithLogits
import torch import torch.nn as nn import torch.nn.functional as F class BCELosswithLogits(nn.Module): def __init__(self, pos_weight=1, reduction='mean'): super(BCELosswithLogits, self).__init__() self.pos_weight = pos_weight self.reduction = reduction def forward(self, logits, target): logits = F.sigmoid(logits) loss = -self.pos_weight * target * torch.log(logits) - (1 - target ) * torch.log(1 - logits) if self.reduction == 'mean': loss = loss.mean() elif self.reduction == 'sum': loss = loss.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 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_log_mean_mul_rsub_sigmoid_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) tmp3 = tl.load(in_ptr1 + r0, None) tmp1 = -1.0 tmp2 = tmp0 * tmp1 tmp4 = tl.sigmoid(tmp3) tmp5 = tl_math.log(tmp4) tmp6 = tmp2 * tmp5 tmp7 = 1.0 tmp8 = tmp7 - tmp0 tmp9 = tmp7 - tmp4 tmp10 = tl_math.log(tmp9) tmp11 = tmp8 * tmp10 tmp12 = tmp6 - tmp11 tmp13 = tl.broadcast_to(tmp12, [RBLOCK]) tmp15 = triton_helpers.promote_to_tensor(tl.sum(tmp13, 0)) tmp16 = 256.0 tmp17 = tmp15 / tmp16 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp17, 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_log_mean_mul_rsub_sigmoid_sub_0[grid(1)](buf1, arg1_1, arg0_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 return buf1, class BCELosswithLogitsNew(nn.Module): def __init__(self, pos_weight=1, reduction='mean'): super(BCELosswithLogitsNew, self).__init__() self.pos_weight = pos_weight self.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]
ZonghaiZhu/EZBM
BCELosswithLogits
false
1,319
[ "MIT" ]
0
b4f6fbd10598c79f144b778ef848554ac62a173a
https://github.com/ZonghaiZhu/EZBM/tree/b4f6fbd10598c79f144b778ef848554ac62a173a
GateLayer
import torch from torch import nn class GateLayer(nn.Module): def __init__(self, input_dim): super(GateLayer, self).__init__() self._norm_layer1 = nn.Linear(input_dim * 2, input_dim) self._norm_layer2 = nn.Linear(input_dim, 1) def forward(self, input1, input2): norm_input = self._norm_layer1(torch.cat([input1, input2], dim=-1)) gate = torch.sigmoid(self._norm_layer2(norm_input)) gated_emb = gate * input1 + (1 - gate) * input2 return gated_emb def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_dim': 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 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_cat_0(in_ptr0, in_ptr1, 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 % 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_1(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 x1 = xindex // 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr1 + x2, xmask) tmp6 = tl.load(in_ptr2 + x2, xmask) tmp1 = tl.sigmoid(tmp0) tmp3 = tmp1 * tmp2 tmp4 = 1.0 tmp5 = tmp4 - tmp1 tmp7 = tmp5 * tmp6 tmp8 = tmp3 + tmp7 tl.store(out_ptr0 + x2, tmp8, 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, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4, 8), (8, 1)) assert_size_stride(primals_4, (4,), (1,)) assert_size_stride(primals_5, (1, 4), (4, 1)) assert_size_stride(primals_6, (1,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 8), (128, 32, 8, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(512)](primals_1, primals_2, buf0, 512, XBLOCK=256, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_4, reinterpret_tensor(buf0, (64, 8), ( 8, 1), 0), reinterpret_tensor(primals_3, (8, 4), (1, 8), 0), alpha=1, beta=1, out=buf1) del primals_3 del primals_4 buf3 = empty_strided_cuda((64, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_6, buf1, reinterpret_tensor(primals_5, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf3) del primals_6 buf4 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_mul_rsub_sigmoid_1[grid(256)](buf3, primals_1, primals_2, buf4, 256, XBLOCK=128, num_warps=4, num_stages=1) return buf4, primals_1, primals_2, reinterpret_tensor(buf0, (64, 8), (8, 1), 0), buf1, buf3, primals_5 class GateLayerNew(nn.Module): def __init__(self, input_dim): super(GateLayerNew, self).__init__() self._norm_layer1 = nn.Linear(input_dim * 2, input_dim) self._norm_layer2 = nn.Linear(input_dim, 1) def forward(self, input_0, input_1): primals_3 = self._norm_layer1.weight primals_4 = self._norm_layer1.bias primals_5 = self._norm_layer2.weight primals_6 = self._norm_layer2.bias primals_1 = input_0 primals_2 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6]) return output[0]
Zilize/CRSLab
GateLayer
false
1,320
[ "MIT" ]
0
fb357d0dfb7d2cf7b67b892d98e52032a31ca564
https://github.com/Zilize/CRSLab/tree/fb357d0dfb7d2cf7b67b892d98e52032a31ca564
NormedLinear
import torch import torch.nn as nn import torch.nn.functional as F from torch.nn import Parameter class NormedLinear(nn.Module): def __init__(self, in_features, out_features): super(NormedLinear, self).__init__() self.weight = Parameter(torch.Tensor(in_features, out_features)) self.weight.data.uniform_(-1, 1).renorm_(2, 1, 1e-05).mul_(100000.0) def forward(self, x): out = F.normalize(x, dim=1).mm(F.normalize(self.weight, dim=0)) return out def get_inputs(): return [torch.rand([4, 4])] def get_init_inputs(): return [[], {'in_features': 4, 'out_features': 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.nn as nn from torch.nn import Parameter 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 = 16 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') tmp3 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp2 = tmp1 * tmp1 tmp4 = tmp3 * tmp3 tmp5 = tmp2 + tmp4 tmp7 = tmp6 * tmp6 tmp8 = tmp5 + tmp7 tmp10 = tmp9 * tmp9 tmp11 = tmp8 + tmp10 tmp12 = libdevice.sqrt(tmp11) tmp13 = 1e-12 tmp14 = triton_helpers.maximum(tmp12, tmp13) tmp15 = tmp0 / tmp14 tl.store(out_ptr0 + x2, tmp15, xmask) @triton.jit def triton_poi_fused_div_1(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_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (4 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (8 + x0), xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr0 + (12 + x0), xmask, eviction_policy='evict_last') tmp2 = tmp1 * tmp1 tmp4 = tmp3 * tmp3 tmp5 = tmp2 + tmp4 tmp7 = tmp6 * tmp6 tmp8 = tmp5 + tmp7 tmp10 = tmp9 * tmp9 tmp11 = tmp8 + tmp10 tmp12 = libdevice.sqrt(tmp11) tmp13 = 1e-12 tmp14 = triton_helpers.maximum(tmp12, tmp13) tmp15 = tmp0 / tmp14 tl.store(out_ptr0 + x2, tmp15, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4, 4), (4, 1)) assert_size_stride(primals_2, (4, 4), (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_div_0[grid(16)](primals_1, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_1 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused_div_1[grid(16)](primals_2, buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, buf1, out=buf2) del buf1 return buf2, primals_2, reinterpret_tensor(buf0, (4, 4), (1, 4), 0) class NormedLinearNew(nn.Module): def __init__(self, in_features, out_features): super(NormedLinearNew, self).__init__() self.weight = Parameter(torch.Tensor(in_features, out_features)) self.weight.data.uniform_(-1, 1).renorm_(2, 1, 1e-05).mul_(100000.0) def forward(self, input_0): primals_1 = self.weight primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]
ZonghaiZhu/EZBM
NormedLinear
false
1,321
[ "MIT" ]
0
b4f6fbd10598c79f144b778ef848554ac62a173a
https://github.com/ZonghaiZhu/EZBM/tree/b4f6fbd10598c79f144b778ef848554ac62a173a
RFDB
import torch import torch.nn as nn import torch.nn.functional as F class ESA(nn.Module): def __init__(self, num_feat=50, conv=nn.Conv2d, p=0.25): super(ESA, self).__init__() f = num_feat // 4 BSConvS_kwargs = {} if conv.__name__ == 'BSConvS': BSConvS_kwargs = {'p': p} self.conv1 = nn.Linear(num_feat, f) self.conv_f = nn.Linear(f, f) self.maxPooling = nn.MaxPool2d(kernel_size=7, stride=3) self.conv_max = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv2 = nn.Conv2d(f, f, 3, 2, 0) self.conv3 = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv3_ = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv4 = nn.Linear(f, num_feat) self.sigmoid = nn.Sigmoid() self.GELU = nn.GELU() def forward(self, input): x = input.permute(0, 2, 3, 1) c1_ = self.conv1(x) c1 = self.conv2(c1_.permute(0, 3, 1, 2)) v_max = self.maxPooling(c1) v_range = self.GELU(self.conv_max(v_max)) c3 = self.GELU(self.conv3(v_range)) c3 = self.conv3_(c3) c3 = F.interpolate(c3, (input.size(2), input.size(3)), mode= 'bilinear', align_corners=False) cf = self.conv_f(c1_) c4 = self.conv4(c3.permute(0, 2, 3, 1) + cf) m = self.sigmoid(c4.permute(0, 3, 1, 2)) return input * m class RFDB(nn.Module): def __init__(self, in_channels, out_channels, distillation_rate=0.25, conv=nn.Conv2d, p=0.25): super(RFDB, self).__init__() kwargs = {'padding': 1} if conv.__name__ == 'BSConvS': kwargs = {'p': p} self.dc = self.distilled_channels = in_channels // 2 self.rc = self.remaining_channels = in_channels self.c1_d = nn.Linear(in_channels, self.rc) self.c1_r = conv(in_channels, self.rc, kernel_size=3, **kwargs) self.c2_d = nn.Linear(self.remaining_channels, self.rc) self.c2_r = conv(self.remaining_channels, self.rc, kernel_size=3, **kwargs) self.c3_d = nn.Linear(self.remaining_channels, self.rc) self.c3_r = conv(self.remaining_channels, self.rc, kernel_size=3, **kwargs) self.c4 = conv(self.remaining_channels, in_channels, kernel_size=3, **kwargs) self.act = nn.GELU() self.alpha1 = nn.Parameter(torch.ones(1, in_channels)) self.alpha2 = nn.Parameter(torch.ones(1, in_channels)) self.alpha3 = nn.Parameter(torch.ones(1, in_channels)) self.alpha4 = nn.Parameter(torch.ones(1, in_channels)) self.esa = ESA(in_channels, conv) self.conv_out = nn.Linear(in_channels, out_channels) def forward(self, input): distilled_c1 = self.act(self.c1_d(input.permute(0, 2, 3, 1))) r_c1 = self.c1_r(input) r_c1 = self.act(r_c1 + input) distilled_c2 = self.act(self.c2_d(r_c1.permute(0, 2, 3, 1))) r_c2 = self.c2_r(r_c1) r_c2 = self.act(r_c2 + r_c1) distilled_c3 = self.act(self.c3_d(r_c2.permute(0, 2, 3, 1))) r_c3 = self.c3_r(r_c2) r_c3 = self.act(r_c3 + r_c2) r_c4 = self.act(self.c4(r_c3)) out = (distilled_c1 * self.alpha1 + distilled_c2 * self.alpha2 + distilled_c3 * self.alpha3 + r_c4.permute(0, 2, 3, 1) * self.alpha4 ) out_fused = self.esa(out.permute(0, 3, 1, 2)) out_fused = self.conv_out(out_fused.permute(0, 2, 3, 1)) return out_fused.permute(0, 3, 1, 2) + input def get_inputs(): return [torch.rand([4, 4, 64, 64])] 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._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice, math as tl_math 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_clone_0(in_ptr0, out_ptr0, ynumel, xnumel, YBLOCK: tl. constexpr, XBLOCK: tl.constexpr): xnumel = 4 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 % 4096 y1 = yindex // 4096 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4096 * x2 + 16384 * y1), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 4 * y3), tmp0, xmask) @triton.jit def triton_poi_fused_add_convolution_gelu_1(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 // 4096 % 4 tmp0 = tl.load(in_out_ptr0 + x3, None) tmp1 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x3, None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = 0.5 tmp6 = tmp4 * tmp5 tmp7 = 0.7071067811865476 tmp8 = tmp4 * tmp7 tmp9 = libdevice.erf(tmp8) tmp10 = 1.0 tmp11 = tmp9 + tmp10 tmp12 = tmp6 * tmp11 tl.store(in_out_ptr0 + x3, tmp2, None) tl.store(out_ptr0 + x3, tmp12, None) @triton.jit def triton_poi_fused_add_convolution_gelu_gelu_backward_2(in_ptr0, in_ptr1, in_ptr2, out_ptr0, out_ptr1, 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 // 4096 % 4 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + x3, None) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = 0.5 tmp6 = tmp4 * tmp5 tmp7 = 0.7071067811865476 tmp8 = tmp4 * tmp7 tmp9 = libdevice.erf(tmp8) tmp10 = 1.0 tmp11 = tmp9 + tmp10 tmp12 = tmp6 * tmp11 tmp13 = tmp11 * tmp5 tmp14 = tmp4 * tmp4 tmp15 = -0.5 tmp16 = tmp14 * tmp15 tmp17 = tl_math.exp(tmp16) tmp18 = 0.3989422804014327 tmp19 = tmp17 * tmp18 tmp20 = tmp4 * tmp19 tmp21 = tmp13 + tmp20 tl.store(out_ptr0 + x3, tmp12, None) tl.store(out_ptr1 + x3, tmp21, None) @triton.jit def triton_poi_fused_convolution_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) x3 = xindex x1 = xindex // 4096 % 4 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_add_gelu_mul_4(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, in_ptr6, in_ptr7, in_ptr8, in_ptr9, in_ptr10, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 4 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 x1 = xindex y0 = yindex y2 = yindex % 4096 y3 = yindex // 4096 tmp0 = tl.load(in_ptr0 + (x1 + 4 * y0), xmask, eviction_policy='evict_last' ) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp13 = tl.load(in_ptr3 + (x1 + 4 * y0), xmask, eviction_policy= 'evict_last') tmp14 = tl.load(in_ptr4 + x1, xmask, eviction_policy='evict_last') tmp21 = tl.load(in_ptr5 + x1, xmask, eviction_policy='evict_last') tmp24 = tl.load(in_ptr6 + (x1 + 4 * y0), xmask, eviction_policy= 'evict_last') tmp25 = tl.load(in_ptr7 + x1, xmask, eviction_policy='evict_last') tmp32 = tl.load(in_ptr8 + x1, xmask, eviction_policy='evict_last') tmp35 = tl.load(in_ptr9 + (y2 + 4096 * x1 + 16384 * y3), xmask, eviction_policy='evict_last') tmp41 = tl.load(in_ptr10 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.5 tmp4 = tmp2 * tmp3 tmp5 = 0.7071067811865476 tmp6 = tmp2 * tmp5 tmp7 = libdevice.erf(tmp6) tmp8 = 1.0 tmp9 = tmp7 + tmp8 tmp10 = tmp4 * tmp9 tmp12 = tmp10 * tmp11 tmp15 = tmp13 + tmp14 tmp16 = tmp15 * tmp3 tmp17 = tmp15 * tmp5 tmp18 = libdevice.erf(tmp17) tmp19 = tmp18 + tmp8 tmp20 = tmp16 * tmp19 tmp22 = tmp20 * tmp21 tmp23 = tmp12 + tmp22 tmp26 = tmp24 + tmp25 tmp27 = tmp26 * tmp3 tmp28 = tmp26 * tmp5 tmp29 = libdevice.erf(tmp28) tmp30 = tmp29 + tmp8 tmp31 = tmp27 * tmp30 tmp33 = tmp31 * tmp32 tmp34 = tmp23 + tmp33 tmp36 = tmp35 * tmp3 tmp37 = tmp35 * tmp5 tmp38 = libdevice.erf(tmp37) tmp39 = tmp38 + tmp8 tmp40 = tmp36 * tmp39 tmp42 = tmp40 * tmp41 tmp43 = tmp34 + tmp42 tl.debug_barrier() tl.store(in_out_ptr0 + (x1 + 4 * y0), tmp43, xmask) @triton.jit def triton_poi_fused_convolution_5(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl .constexpr): xnumel = 3844 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 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = tmp0 + tmp2 tl.store(in_out_ptr0 + x0, tmp3, xmask) @triton.jit def triton_poi_fused_convolution_gelu_6(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 196 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 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = tmp0 + tmp2 tmp4 = 0.5 tmp5 = tmp3 * tmp4 tmp6 = 0.7071067811865476 tmp7 = tmp3 * tmp6 tmp8 = libdevice.erf(tmp7) tmp9 = 1.0 tmp10 = tmp8 + tmp9 tmp11 = tmp5 * tmp10 tl.store(in_out_ptr0 + x0, tmp3, xmask) tl.store(out_ptr0 + x0, tmp11, xmask) @triton.jit def triton_poi_fused_convolution_gelu_7(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 100 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 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = tmp0 + tmp2 tmp4 = 0.5 tmp5 = tmp3 * tmp4 tmp6 = 0.7071067811865476 tmp7 = tmp3 * tmp6 tmp8 = libdevice.erf(tmp7) tmp9 = 1.0 tmp10 = tmp8 + tmp9 tmp11 = tmp5 * tmp10 tl.store(in_out_ptr0 + x0, tmp3, xmask) tl.store(out_ptr0 + x0, tmp11, xmask) @triton.jit def triton_poi_fused__to_copy_8(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 = x0 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 + tmp2 tmp4 = 0.046875 tmp5 = tmp3 * tmp4 tmp6 = tmp5 - tmp2 tmp7 = 0.0 tmp8 = triton_helpers.maximum(tmp6, tmp7) tmp9 = tmp8.to(tl.int32) tl.store(out_ptr0 + x0, tmp9, xmask) @triton.jit def triton_poi_fused_add_clamp_9(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 = x0 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 + tmp2 tmp4 = 0.046875 tmp5 = tmp3 * tmp4 tmp6 = tmp5 - tmp2 tmp7 = 0.0 tmp8 = triton_helpers.maximum(tmp6, tmp7) tmp9 = tmp8.to(tl.int32) tmp10 = tl.full([1], 1, tl.int64) tmp11 = tmp9 + tmp10 tmp12 = tl.full([1], 2, tl.int64) tmp13 = triton_helpers.minimum(tmp11, tmp12) tl.store(out_ptr0 + x0, tmp13, xmask) @triton.jit def triton_poi_fused__to_copy_add_arange_clamp_mul_sub_10(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 = x0 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 + tmp2 tmp4 = 0.046875 tmp5 = tmp3 * tmp4 tmp6 = tmp5 - tmp2 tmp7 = 0.0 tmp8 = triton_helpers.maximum(tmp6, tmp7) tmp9 = tmp8.to(tl.int32) tmp10 = tmp9.to(tl.float32) tmp11 = tmp8 - tmp10 tmp12 = triton_helpers.maximum(tmp11, tmp7) tmp13 = 1.0 tmp14 = triton_helpers.minimum(tmp12, tmp13) tl.store(out_ptr0 + x0, tmp14, xmask) @triton.jit def triton_poi_fused__unsafe_index_add_convolution_mul_sub_11(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, in_ptr6, in_ptr7, in_ptr8, in_ptr9, xnumel, XBLOCK: tl.constexpr): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x1 = xindex // 64 % 64 x0 = xindex % 64 x2 = xindex // 4096 x3 = xindex tmp0 = tl.load(in_ptr0 + x1, None, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + x0, None, eviction_policy='evict_last') tmp10 = tl.load(in_ptr3 + 0) tmp11 = tl.broadcast_to(tmp10, [XBLOCK]) tmp13 = tl.load(in_ptr4 + x0, None, eviction_policy='evict_last') tmp20 = tl.load(in_ptr5 + x0, None, eviction_policy='evict_last') tmp23 = tl.load(in_ptr6 + x1, None, eviction_policy='evict_last') tmp35 = tl.load(in_ptr7 + x1, None, eviction_policy='evict_last') tmp38 = tl.load(in_ptr8 + x3, None) tmp39 = tl.load(in_ptr9 + 0) tmp40 = tl.broadcast_to(tmp39, [XBLOCK]) tmp1 = tl.full([XBLOCK], 3, tl.int32) tmp2 = tmp0 + tmp1 tmp3 = tmp0 < 0 tmp4 = tl.where(tmp3, tmp2, tmp0) tmp6 = tmp5 + tmp1 tmp7 = tmp5 < 0 tmp8 = tl.where(tmp7, tmp6, tmp5) tmp9 = tl.load(in_ptr2 + (tmp8 + 3 * tmp4 + 9 * x2), None, eviction_policy='evict_last') tmp12 = tmp9 + tmp11 tmp14 = tmp13 + tmp1 tmp15 = tmp13 < 0 tmp16 = tl.where(tmp15, tmp14, tmp13) tmp17 = tl.load(in_ptr2 + (tmp16 + 3 * tmp4 + 9 * x2), None, eviction_policy='evict_last') tmp18 = tmp17 + tmp11 tmp19 = tmp18 - tmp12 tmp21 = tmp19 * tmp20 tmp22 = tmp12 + tmp21 tmp24 = tmp23 + tmp1 tmp25 = tmp23 < 0 tmp26 = tl.where(tmp25, tmp24, tmp23) tmp27 = tl.load(in_ptr2 + (tmp8 + 3 * tmp26 + 9 * x2), None, eviction_policy='evict_last') tmp28 = tmp27 + tmp11 tmp29 = tl.load(in_ptr2 + (tmp16 + 3 * tmp26 + 9 * x2), None, eviction_policy='evict_last') tmp30 = tmp29 + tmp11 tmp31 = tmp30 - tmp28 tmp32 = tmp31 * tmp20 tmp33 = tmp28 + tmp32 tmp34 = tmp33 - tmp22 tmp36 = tmp34 * tmp35 tmp37 = tmp22 + tmp36 tmp41 = tmp38 + tmp40 tmp42 = tmp37 + tmp41 tl.store(in_out_ptr0 + x3, tmp42, None) @triton.jit def triton_poi_fused_mul_sigmoid_12(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) x0 = xindex tmp0 = tl.load(in_ptr0 + x0, None) tmp1 = tl.load(in_ptr1 + x0, None) tmp2 = tl.sigmoid(tmp1) tmp3 = tmp0 * tmp2 tl.store(out_ptr0 + x0, tmp3, None) @triton.jit def triton_poi_fused_add_13(in_out_ptr0, in_ptr0, in_ptr1, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): xnumel = 4 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_out_ptr0 + (x2 + 4 * y3), xmask, eviction_policy= 'evict_last') tmp1 = tl.load(in_ptr0 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + (y0 + 4096 * x2 + 16384 * y1), xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tl.debug_barrier() tl.store(in_out_ptr0 + (x2 + 4 * y3), 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, primals_20, primals_21, primals_22, primals_23, primals_24, primals_25, primals_26, primals_27, primals_28, primals_29, primals_30, primals_31, primals_32, primals_33, primals_34, primals_35) = args args.clear() assert_size_stride(primals_1, (4, 4, 64, 64), (16384, 4096, 64, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4, 3, 3), (36, 9, 3, 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, 3, 3), (36, 9, 3, 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, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_13, (4,), (1,)) assert_size_stride(primals_14, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_15, (4,), (1,)) assert_size_stride(primals_16, (1, 4), (4, 1)) assert_size_stride(primals_17, (1, 4), (4, 1)) assert_size_stride(primals_18, (1, 4), (4, 1)) assert_size_stride(primals_19, (1, 4), (4, 1)) assert_size_stride(primals_20, (1, 4), (4, 1)) assert_size_stride(primals_21, (1,), (1,)) assert_size_stride(primals_22, (1, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_23, (1,), (1,)) assert_size_stride(primals_24, (1, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_25, (1,), (1,)) assert_size_stride(primals_26, (1, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_27, (1,), (1,)) assert_size_stride(primals_28, (1, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_29, (1,), (1,)) assert_size_stride(primals_30, (1, 1), (1, 1)) assert_size_stride(primals_31, (1,), (1,)) assert_size_stride(primals_32, (4, 1), (1, 1)) assert_size_stride(primals_33, (4,), (1,)) assert_size_stride(primals_34, (4, 4), (4, 1)) assert_size_stride(primals_35, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 64, 64, 4), (16384, 256, 4, 1), torch .float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(16384, 4)](primals_1, buf0, 16384, 4, XBLOCK=4, YBLOCK=256, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((16384, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf0, (16384, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = extern_kernels.convolution(primals_1, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 64, 64), (16384, 4096, 64, 1)) buf3 = buf2 del buf2 buf4 = empty_strided_cuda((4, 4, 64, 64), (16384, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_gelu_1[grid(65536)](buf3, primals_5, primals_1, buf4, 65536, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 buf5 = empty_strided_cuda((4, 64, 64, 4), (16384, 256, 4, 1), torch .float32) triton_poi_fused_clone_0[grid(16384, 4)](buf4, buf5, 16384, 4, XBLOCK=4, YBLOCK=256, num_warps=4, num_stages=1) buf6 = empty_strided_cuda((16384, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf5, (16384, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf6) buf7 = extern_kernels.convolution(buf4, primals_8, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf7, (4, 4, 64, 64), (16384, 4096, 64, 1)) buf8 = empty_strided_cuda((4, 4, 64, 64), (16384, 4096, 64, 1), torch.float32) buf46 = empty_strided_cuda((4, 4, 64, 64), (16384, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_gelu_gelu_backward_2[grid(65536)](buf7 , primals_9, buf4, buf8, buf46, 65536, XBLOCK=256, num_warps=4, num_stages=1) del primals_9 buf9 = reinterpret_tensor(buf7, (4, 64, 64, 4), (16384, 256, 4, 1), 0) del buf7 triton_poi_fused_clone_0[grid(16384, 4)](buf8, buf9, 16384, 4, XBLOCK=4, YBLOCK=256, num_warps=4, num_stages=1) buf10 = empty_strided_cuda((16384, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf9, (16384, 4), (4, 1), 0), reinterpret_tensor(primals_10, (4, 4), (1, 4), 0), out=buf10) buf11 = extern_kernels.convolution(buf8, primals_12, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf11, (4, 4, 64, 64), (16384, 4096, 64, 1)) buf12 = empty_strided_cuda((4, 4, 64, 64), (16384, 4096, 64, 1), torch.float32) buf45 = empty_strided_cuda((4, 4, 64, 64), (16384, 4096, 64, 1), torch.float32) triton_poi_fused_add_convolution_gelu_gelu_backward_2[grid(65536)]( buf11, primals_13, buf8, buf12, buf45, 65536, XBLOCK=256, num_warps=4, num_stages=1) del primals_13 buf13 = extern_kernels.convolution(buf12, primals_14, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf13, (4, 4, 64, 64), (16384, 4096, 64, 1)) buf14 = buf13 del buf13 triton_poi_fused_convolution_3[grid(65536)](buf14, primals_15, 65536, XBLOCK=256, num_warps=4, num_stages=1) del primals_15 buf15 = reinterpret_tensor(buf11, (4, 64, 64, 4), (16384, 256, 4, 1), 0 ) del buf11 buf16 = buf15 del buf15 triton_poi_fused_add_gelu_mul_4[grid(16384, 4)](buf16, buf1, primals_3, primals_16, buf6, primals_7, primals_17, buf10, primals_11, primals_18, buf14, primals_19, 16384, 4, XBLOCK=4, YBLOCK=256, num_warps=4, num_stages=1) buf18 = empty_strided_cuda((16384, 1), (1, 1), torch.float32) extern_kernels.addmm(primals_21, reinterpret_tensor(buf16, (16384, 4), (4, 1), 0), reinterpret_tensor(primals_20, (4, 1), (1, 4), 0), alpha=1, beta=1, out=buf18) del primals_21 buf19 = extern_kernels.convolution(reinterpret_tensor(buf18, (4, 1, 64, 64), (4096, 1, 64, 1), 0), primals_22, stride=(2, 2), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf19, (4, 1, 31, 31), (961, 1, 31, 1)) buf20 = buf19 del buf19 triton_poi_fused_convolution_5[grid(3844)](buf20, primals_23, 3844, XBLOCK=256, num_warps=4, num_stages=1) del primals_23 buf21 = torch.ops.aten.max_pool2d_with_indices.default(buf20, [7, 7 ], [3, 3]) buf22 = buf21[0] buf23 = buf21[1] del buf21 buf24 = extern_kernels.convolution(buf22, primals_24, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf24, (4, 1, 7, 7), (49, 1, 7, 1)) buf25 = buf24 del buf24 buf26 = empty_strided_cuda((4, 1, 7, 7), (49, 1, 7, 1), torch.float32) triton_poi_fused_convolution_gelu_6[grid(196)](buf25, primals_25, buf26, 196, XBLOCK=256, num_warps=4, num_stages=1) del primals_25 buf27 = extern_kernels.convolution(buf26, primals_26, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf27, (4, 1, 5, 5), (25, 1, 5, 1)) buf28 = buf27 del buf27 buf29 = empty_strided_cuda((4, 1, 5, 5), (25, 1, 5, 1), torch.float32) triton_poi_fused_convolution_gelu_7[grid(100)](buf28, primals_27, buf29, 100, XBLOCK=128, num_warps=4, num_stages=1) del primals_27 buf30 = extern_kernels.convolution(buf29, primals_28, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf30, (4, 1, 3, 3), (9, 1, 3, 1)) buf31 = empty_strided_cuda((64, 1), (1, 1), torch.int64) triton_poi_fused__to_copy_8[grid(64)](buf31, 64, XBLOCK=64, num_warps=1, num_stages=1) buf32 = empty_strided_cuda((64, 1), (1, 1), torch.int64) triton_poi_fused_add_clamp_9[grid(64)](buf32, 64, XBLOCK=64, num_warps=1, num_stages=1) buf33 = empty_strided_cuda((64,), (1,), torch.int64) triton_poi_fused__to_copy_8[grid(64)](buf33, 64, XBLOCK=64, num_warps=1, num_stages=1) buf34 = empty_strided_cuda((64,), (1,), torch.int64) triton_poi_fused_add_clamp_9[grid(64)](buf34, 64, XBLOCK=64, num_warps=1, num_stages=1) buf35 = empty_strided_cuda((64,), (1,), torch.float32) triton_poi_fused__to_copy_add_arange_clamp_mul_sub_10[grid(64)](buf35, 64, XBLOCK=64, num_warps=1, num_stages=1) buf37 = empty_strided_cuda((64, 1), (1, 1), torch.float32) triton_poi_fused__to_copy_add_arange_clamp_mul_sub_10[grid(64)](buf37, 64, XBLOCK=64, num_warps=1, num_stages=1) buf39 = empty_strided_cuda((16384, 1), (1, 1), torch.float32) extern_kernels.mm(buf18, primals_30, out=buf39) buf38 = empty_strided_cuda((4, 1, 64, 64), (4096, 16384, 64, 1), torch.float32) buf40 = reinterpret_tensor(buf38, (4, 64, 64, 1), (4096, 64, 1, 1), 0) del buf38 triton_poi_fused__unsafe_index_add_convolution_mul_sub_11[grid(16384)]( buf40, buf31, buf33, buf30, primals_29, buf34, buf35, buf32, buf37, buf39, primals_31, 16384, XBLOCK=256, num_warps=4, num_stages=1) del buf30 del buf39 del primals_29 del primals_31 buf41 = empty_strided_cuda((16384, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_33, reinterpret_tensor(buf40, (16384, 1), (1, 0), 0), reinterpret_tensor(primals_32, (1, 4), (1, 1), 0), alpha=1, beta=1, out=buf41) del primals_33 buf42 = empty_strided_cuda((4, 4, 64, 64), (16384, 1, 256, 4), torch.float32) triton_poi_fused_mul_sigmoid_12[grid(65536)](buf16, buf41, buf42, 65536, XBLOCK=256, num_warps=4, num_stages=1) buf43 = empty_strided_cuda((16384, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf42, (16384, 4), (4, 1), 0), reinterpret_tensor(primals_34, (4, 4), (1, 4), 0), out=buf43) buf44 = reinterpret_tensor(buf43, (4, 4, 64, 64), (16384, 1, 256, 4), 0 ) del buf43 triton_poi_fused_add_13[grid(16384, 4)](buf44, primals_35, primals_1, 16384, 4, XBLOCK=4, YBLOCK=128, num_warps=4, num_stages=1) del primals_35 return (buf44, primals_1, primals_3, primals_4, primals_7, primals_8, primals_11, primals_12, primals_14, primals_16, primals_17, primals_18, primals_19, primals_22, primals_24, primals_26, primals_28, reinterpret_tensor(buf0, (16384, 4), (4, 1), 0), buf1, buf3, buf4, reinterpret_tensor(buf5, (16384, 4), (4, 1), 0), buf6, buf8, reinterpret_tensor(buf9, (16384, 4), (4, 1), 0), buf10, buf12, buf14, reinterpret_tensor(buf16, (4, 4, 64, 64), (16384, 1, 256, 4), 0), buf18, buf20, buf22, buf23, buf25, buf26, buf28, buf29, buf31, buf32, buf33, buf34, buf35, buf37, reinterpret_tensor(buf40, (16384, 1), (1, 1), 0), buf41, reinterpret_tensor(buf42, (16384, 4), (4, 1), 0), primals_34, primals_32, primals_30, primals_20, buf45, primals_10, buf46, primals_6) class ESA(nn.Module): def __init__(self, num_feat=50, conv=nn.Conv2d, p=0.25): super(ESA, self).__init__() f = num_feat // 4 BSConvS_kwargs = {} if conv.__name__ == 'BSConvS': BSConvS_kwargs = {'p': p} self.conv1 = nn.Linear(num_feat, f) self.conv_f = nn.Linear(f, f) self.maxPooling = nn.MaxPool2d(kernel_size=7, stride=3) self.conv_max = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv2 = nn.Conv2d(f, f, 3, 2, 0) self.conv3 = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv3_ = conv(f, f, kernel_size=3, **BSConvS_kwargs) self.conv4 = nn.Linear(f, num_feat) self.sigmoid = nn.Sigmoid() self.GELU = nn.GELU() def forward(self, input): x = input.permute(0, 2, 3, 1) c1_ = self.conv1(x) c1 = self.conv2(c1_.permute(0, 3, 1, 2)) v_max = self.maxPooling(c1) v_range = self.GELU(self.conv_max(v_max)) c3 = self.GELU(self.conv3(v_range)) c3 = self.conv3_(c3) c3 = F.interpolate(c3, (input.size(2), input.size(3)), mode= 'bilinear', align_corners=False) cf = self.conv_f(c1_) c4 = self.conv4(c3.permute(0, 2, 3, 1) + cf) m = self.sigmoid(c4.permute(0, 3, 1, 2)) return input * m class RFDBNew(nn.Module): def __init__(self, in_channels, out_channels, distillation_rate=0.25, conv=nn.Conv2d, p=0.25): super(RFDBNew, self).__init__() kwargs = {'padding': 1} if conv.__name__ == 'BSConvS': kwargs = {'p': p} self.dc = self.distilled_channels = in_channels // 2 self.rc = self.remaining_channels = in_channels self.c1_d = nn.Linear(in_channels, self.rc) self.c1_r = conv(in_channels, self.rc, kernel_size=3, **kwargs) self.c2_d = nn.Linear(self.remaining_channels, self.rc) self.c2_r = conv(self.remaining_channels, self.rc, kernel_size=3, **kwargs) self.c3_d = nn.Linear(self.remaining_channels, self.rc) self.c3_r = conv(self.remaining_channels, self.rc, kernel_size=3, **kwargs) self.c4 = conv(self.remaining_channels, in_channels, kernel_size=3, **kwargs) self.act = nn.GELU() self.alpha1 = nn.Parameter(torch.ones(1, in_channels)) self.alpha2 = nn.Parameter(torch.ones(1, in_channels)) self.alpha3 = nn.Parameter(torch.ones(1, in_channels)) self.alpha4 = nn.Parameter(torch.ones(1, in_channels)) self.esa = ESA(in_channels, conv) self.conv_out = nn.Linear(in_channels, out_channels) def forward(self, input_0): primals_16 = self.alpha1 primals_17 = self.alpha2 primals_18 = self.alpha3 primals_19 = self.alpha4 primals_2 = self.c1_d.weight primals_3 = self.c1_d.bias primals_4 = self.c1_r.weight primals_5 = self.c1_r.bias primals_6 = self.c2_d.weight primals_7 = self.c2_d.bias primals_8 = self.c2_r.weight primals_9 = self.c2_r.bias primals_10 = self.c3_d.weight primals_11 = self.c3_d.bias primals_12 = self.c3_r.weight primals_13 = self.c3_r.bias primals_14 = self.c4.weight primals_15 = self.c4.bias primals_20 = self.esa.conv1.weight primals_21 = self.esa.conv1.bias primals_30 = self.esa.conv_f.weight primals_23 = self.esa.conv_f.bias primals_22 = self.esa.conv_max.weight primals_25 = self.esa.conv_max.bias primals_24 = self.esa.conv2.weight primals_27 = self.esa.conv2.bias primals_26 = self.esa.conv3.weight primals_29 = self.esa.conv3.bias primals_28 = self.esa.conv3_.weight primals_31 = self.esa.conv3_.bias primals_32 = self.esa.conv4.weight primals_33 = self.esa.conv4.bias primals_34 = self.conv_out.weight primals_35 = self.conv_out.bias primals_1 = 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, primals_20, primals_21, primals_22, primals_23, primals_24, primals_25, primals_26, primals_27, primals_28, primals_29, primals_30, primals_31, primals_32, primals_33, primals_34, primals_35]) return output[0]
YingqiLiulll/scrips_for_SR
RFDB
false
1,322
[ "MIT" ]
0
04fa6fdaf157e913d3e2521cd80315a10a2ccedc
https://github.com/YingqiLiulll/scrips_for_SR/tree/04fa6fdaf157e913d3e2521cd80315a10a2ccedc
GeneralizedFocalLoss
import torch import torch.utils.data from torch import nn class GeneralizedFocalLoss(nn.Module): def __init__(self, beta=2): super(GeneralizedFocalLoss, self).__init__() self.beta = beta def forward(self, prediction, target, cls_weights): cls_weights = cls_weights.unsqueeze(-1).unsqueeze(-1) shape = prediction.shape cls_weights = cls_weights.repeat(1, 1, shape[2], shape[3]) loss = 0.0 positive_index = target.eq(1).float() num_positive = positive_index.float().sum() scale_factor = torch.pow((target - prediction).abs(), self.beta) loss -= scale_factor * (target * torch.log(prediction) + (1 - target) * torch.log(1 - prediction)) * cls_weights num_positive = max(1.0, num_positive) loss = loss.sum() / num_positive return loss def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4]), torch.rand( [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.utils.data 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_per_fused__to_copy_abs_add_clamp_div_eq_log_mul_pow_repeat_rsub_sub_sum_0( in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, 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) r2 = rindex r1 = rindex // 16 tmp0 = tl.load(in_ptr0 + r2, None) tmp1 = tl.load(in_ptr1 + r2, None) tmp14 = tl.load(in_ptr2 + r1, None, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp3 = tl_math.abs(tmp2) tmp4 = tmp3 * tmp3 tmp5 = tl_math.log(tmp1) tmp6 = tmp0 * tmp5 tmp7 = 1.0 tmp8 = tmp7 - tmp0 tmp9 = tmp7 - tmp1 tmp10 = tl_math.log(tmp9) tmp11 = tmp8 * tmp10 tmp12 = tmp6 + tmp11 tmp13 = tmp4 * tmp12 tmp15 = tmp13 * tmp14 tmp16 = 0.0 tmp17 = tmp16 - tmp15 tmp18 = tl.broadcast_to(tmp17, [RBLOCK]) tmp20 = triton_helpers.promote_to_tensor(tl.sum(tmp18, 0)) tmp21 = tmp0 == tmp7 tmp22 = tmp21.to(tl.float32) tmp23 = tl.broadcast_to(tmp22, [RBLOCK]) tmp25 = triton_helpers.promote_to_tensor(tl.sum(tmp23, 0)) tmp26 = triton_helpers.maximum(tmp25, tmp7) tmp27 = tmp20 / tmp26 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp27, None) 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, 4, 4, 4), (64, 16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((), (), torch.float32) buf2 = buf0 del buf0 get_raw_stream(0) triton_per_fused__to_copy_abs_add_clamp_div_eq_log_mul_pow_repeat_rsub_sub_sum_0[ grid(1)](buf2, arg2_1, arg1_1, arg0_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 return buf2, class GeneralizedFocalLossNew(nn.Module): def __init__(self, beta=2): super(GeneralizedFocalLossNew, self).__init__() self.beta = beta def forward(self, input_0, input_1, input_2): arg1_1 = input_0 arg2_1 = input_1 arg0_1 = input_2 output = call([arg0_1, arg1_1, arg2_1]) return output[0]
ZhuokunYao/smoke
GeneralizedFocalLoss
false
1,323
[ "MIT" ]
0
d524fbe43b1aba6078c25d9aca7924b71a635e1d
https://github.com/ZhuokunYao/smoke/tree/d524fbe43b1aba6078c25d9aca7924b71a635e1d
ClsConvHead
import torch import torch.nn as nn import torch.nn.parallel class ClsConvHead(nn.Module): """Global average pooling + conv head for classification """ def __init__(self, input_dim, output_dim): super().__init__() self.avg_pool = nn.AdaptiveAvgPool2d((1, 1)) self.conv = nn.Conv2d(input_dim, output_dim, 1) def forward(self, x): x = self.avg_pool(x) x = self.conv(x) x = x.view(x.size(0), -1) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_dim': 4, 'output_dim': 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.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_per_fused_mean_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 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, 0) tmp4 = tl.sum(tmp3, 1)[:, None] tmp5 = 16.0 tmp6 = tmp4 / tmp5 tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp6, xmask) @triton.jit def triton_poi_fused_convolution_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 tl.store(in_out_ptr0 + x2, 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, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_3, (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_mean_0[grid(16)](buf1, primals_1, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del primals_1 buf2 = extern_kernels.convolution(buf1, primals_2, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 1, 1), (4, 1, 1, 1)) buf3 = reinterpret_tensor(buf2, (4, 4, 1, 1), (4, 1, 16, 16), 0) del buf2 triton_poi_fused_convolution_1[grid(16)](buf3, primals_3, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_3 return reinterpret_tensor(buf3, (4, 4), (4, 1), 0), primals_2, buf1 class ClsConvHeadNew(nn.Module): """Global average pooling + conv head for classification """ def __init__(self, input_dim, output_dim): super().__init__() self.avg_pool = nn.AdaptiveAvgPool2d((1, 1)) self.conv = nn.Conv2d(input_dim, output_dim, 1) def forward(self, input_0): primals_2 = self.conv.weight primals_3 = self.conv.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
a1004123217/pytorch-mobile
ClsConvHead
false
1,324
[ "MIT" ]
0
97974af3259a2073efbc334d57841efbd3eaadfb
https://github.com/a1004123217/pytorch-mobile/tree/97974af3259a2073efbc334d57841efbd3eaadfb
ConvBlock
import torch import torch.nn as nn class Block(nn.Module): def __init__(self): """Initialisation for a lower-level DeepLPF conv block :returns: N/A :rtype: N/A """ super(Block, self).__init__() def conv3x3(self, in_channels, out_channels, stride=1): """Represents a convolution of shape 3x3 :param in_channels: number of input channels :param out_channels: number of output channels :param stride: the convolution stride :returns: convolution function with the specified parameterisation :rtype: function """ return nn.Conv2d(in_channels, out_channels, kernel_size=3, stride= stride, padding=1, bias=True) class ConvBlock(Block, nn.Module): def __init__(self, num_in_channels, num_out_channels, stride=1): """Initialise function for the higher level convolution block :param in_channels: :param out_channels: :param stride: :param padding: :returns: :rtype: """ super(Block, self).__init__() self.conv = self.conv3x3(num_in_channels, num_out_channels, stride=2) self.lrelu = nn.LeakyReLU() def forward(self, x): """ Forward function for the higher level convolution block :param x: Tensor representing the input BxCxWxH, where B is the batch size, C is the number of channels, W and H are the width and image height :returns: Tensor representing the output of the block :rtype: Tensor """ img_out = self.lrelu(self.conv(x)) return img_out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_in_channels': 4, 'num_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 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_convolution_leaky_relu_0(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 x3 = xindex x1 = xindex // 4 % 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp5 = 0.01 tmp6 = tmp2 * tmp5 tmp7 = tl.where(tmp4, tmp2, tmp6) tl.store(out_ptr0 + x3, tmp4, xmask) tl.store(out_ptr1 + x3, tmp7, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 3, 3), (36, 9, 3, 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=(2, 2), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 2, 2), (16, 4, 2, 1)) buf1 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.bool) buf2 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_convolution_leaky_relu_0[grid(64)](buf0, primals_2, buf1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf0 del primals_2 return buf2, primals_1, primals_3, buf1 class Block(nn.Module): def __init__(self): """Initialisation for a lower-level DeepLPF conv block :returns: N/A :rtype: N/A """ super(Block, self).__init__() def conv3x3(self, in_channels, out_channels, stride=1): """Represents a convolution of shape 3x3 :param in_channels: number of input channels :param out_channels: number of output channels :param stride: the convolution stride :returns: convolution function with the specified parameterisation :rtype: function """ return nn.Conv2d(in_channels, out_channels, kernel_size=3, stride= stride, padding=1, bias=True) class ConvBlockNew(Block, nn.Module): def __init__(self, num_in_channels, num_out_channels, stride=1): """Initialise function for the higher level convolution block :param in_channels: :param out_channels: :param stride: :param padding: :returns: :rtype: """ super(Block, self).__init__() self.conv = self.conv3x3(num_in_channels, num_out_channels, stride=2) self.lrelu = nn.LeakyReLU() 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]
ZombaSY/DeepLPF
ConvBlock
false
1,325
[ "BSD-3-Clause" ]
0
adce64ae01bc9e32f465a354cb1f6534f0d13597
https://github.com/ZombaSY/DeepLPF/tree/adce64ae01bc9e32f465a354cb1f6534f0d13597
TorchMulScalar
import torch import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional class TorchMulScalar(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul_scalar(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 import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional 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 =128, num_warps=4, num_stages=1) del arg0_1 del arg1_1 return buf0, class TorchMulScalarNew(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, input_0, input_1): arg0_1 = input_0 arg1_1 = input_1 output = call([arg0_1, arg1_1]) return output[0]
a1004123217/pytorch-mobile
TorchMulScalar
false
1,326
[ "MIT" ]
0
97974af3259a2073efbc334d57841efbd3eaadfb
https://github.com/a1004123217/pytorch-mobile/tree/97974af3259a2073efbc334d57841efbd3eaadfb
SelfAttentionBatch
import torch from torch import nn import torch.nn.functional as F class SelfAttentionBatch(nn.Module): def __init__(self, dim, da, alpha=0.2, dropout=0.5): super(SelfAttentionBatch, self).__init__() self.dim = dim self.da = da self.alpha = alpha self.dropout = dropout self.a = nn.Parameter(torch.zeros(size=(self.dim, self.da)), requires_grad=True) self.b = nn.Parameter(torch.zeros(size=(self.da, 1)), requires_grad =True) nn.init.xavier_uniform_(self.a.data, gain=1.414) nn.init.xavier_uniform_(self.b.data, gain=1.414) def forward(self, h): e = torch.matmul(torch.tanh(torch.matmul(h, self.a)), self.b).squeeze( dim=1) attention = F.softmax(e, dim=0) return torch.matmul(attention, h) def get_inputs(): return [torch.rand([4, 4])] def get_init_inputs(): return [[], {'dim': 4, 'da': 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, 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_tanh_0(in_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_out_ptr0 + x0, xmask) tmp1 = libdevice.tanh(tmp0) tl.store(in_out_ptr0 + x0, tmp1, xmask) @triton.jit def triton_per_fused__softmax_1(in_ptr0, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 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.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = triton_helpers.max2(tmp1, 1)[:, None] tmp4 = tmp0 - tmp3 tmp5 = tl_math.exp(tmp4) tmp6 = tl.broadcast_to(tmp5, [XBLOCK, RBLOCK]) tmp8 = tl.sum(tmp6, 1)[:, None] tmp9 = tmp5 / tmp8 tl.store(out_ptr2 + tl.broadcast_to(r0, [XBLOCK, RBLOCK]), tmp9, None) 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, 4), (4, 1)) assert_size_stride(primals_3, (4, 1), (1, 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 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_tanh_0[grid(16)](buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 1), (1, 1), torch.float32) extern_kernels.mm(buf1, primals_3, out=buf2) buf5 = empty_strided_cuda((4,), (1,), torch.float32) triton_per_fused__softmax_1[grid(1)](buf2, buf5, 1, 4, XBLOCK=1, num_warps=2, num_stages=1) buf6 = empty_strided_cuda((1, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf5, (1, 4), (0, 1), 0), primals_2, out=buf6) del buf5 return reinterpret_tensor(buf6, (4,), (1,), 0 ), buf1, buf2, reinterpret_tensor(primals_2, (4, 4), (1, 4), 0 ), reinterpret_tensor(primals_3, (1, 4), (1, 1), 0) class SelfAttentionBatchNew(nn.Module): def __init__(self, dim, da, alpha=0.2, dropout=0.5): super(SelfAttentionBatchNew, self).__init__() self.dim = dim self.da = da self.alpha = alpha self.dropout = dropout self.a = nn.Parameter(torch.zeros(size=(self.dim, self.da)), requires_grad=True) self.b = nn.Parameter(torch.zeros(size=(self.da, 1)), requires_grad =True) nn.init.xavier_uniform_(self.a.data, gain=1.414) nn.init.xavier_uniform_(self.b.data, gain=1.414) def forward(self, input_0): primals_1 = self.a primals_3 = self.b primals_2 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
Zilize/CRSLab
SelfAttentionBatch
false
1,327
[ "MIT" ]
0
fb357d0dfb7d2cf7b67b892d98e52032a31ca564
https://github.com/Zilize/CRSLab/tree/fb357d0dfb7d2cf7b67b892d98e52032a31ca564
Swish
import torch import torch.nn as nn class Swish(nn.Module): def __init__(self): super(Swish, self).__init__() self.beta = nn.Parameter(torch.tensor(1.0)) def forward(self, x): return x * torch.sigmoid(self.beta * 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 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, 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 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = tmp2 * tmp0 tmp4 = tl.sigmoid(tmp3) tmp5 = tmp0 * tmp4 tl.store(out_ptr0 + x0, tmp5, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_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_mul_sigmoid_0[grid(256)](primals_2, primals_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) return buf0, primals_1, primals_2 class SwishNew(nn.Module): def __init__(self): super(SwishNew, self).__init__() self.beta = nn.Parameter(torch.tensor(1.0)) def forward(self, input_0): primals_1 = self.beta primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]
a07458666/UncertaintyFlow
Swish
false
1,328
[ "MIT" ]
0
cef2512901d4e27bb22fc3997522cd47c03b569c
https://github.com/a07458666/UncertaintyFlow/tree/cef2512901d4e27bb22fc3997522cd47c03b569c
MultiHeadAttention
import math import torch from torch import nn import torch.utils.data import torch.optim class MultiHeadAttention(nn.Module): """ Multi-head scaled dot-product attention layer. Args: hidden_size: size of the embeddings in the model, also known as d_model num_attention_heads: number of heads in multi-head attention attn_score_dropout: probability of dropout applied to attention scores attn_layer_dropout: probability of dropout applied to the output of the whole layer, but before layer normalization """ def __init__(self, hidden_size, num_attention_heads, attn_score_dropout =0.0, attn_layer_dropout=0.0): super().__init__() if hidden_size % num_attention_heads != 0: raise ValueError( 'The hidden size (%d) is not a multiple of the number of attention heads (%d)' % (hidden_size, num_attention_heads)) self.hidden_size = hidden_size self.num_attention_heads = num_attention_heads self.attn_head_size = int(hidden_size / num_attention_heads) self.attn_scale = math.sqrt(math.sqrt(self.attn_head_size)) self.query_net = nn.Linear(hidden_size, hidden_size) self.key_net = nn.Linear(hidden_size, hidden_size) self.value_net = nn.Linear(hidden_size, hidden_size) self.out_projection = nn.Linear(hidden_size, hidden_size) self.attn_dropout = nn.Dropout(attn_score_dropout) self.layer_dropout = nn.Dropout(attn_layer_dropout) def transpose_for_scores(self, x): new_x_shape = x.size()[:-1] + (self.num_attention_heads, self. attn_head_size) x = x.view(*new_x_shape) return x.permute(0, 2, 1, 3) def forward(self, queries, keys, values, attention_mask): query = self.query_net(queries) key = self.key_net(keys) value = self.value_net(values) query = self.transpose_for_scores(query) / self.attn_scale key = self.transpose_for_scores(key) / self.attn_scale value = self.transpose_for_scores(value) attention_scores = torch.matmul(query, key.transpose(-1, -2)) if attention_mask is not None: attention_scores = attention_scores + attention_mask attention_probs = torch.softmax(attention_scores, dim=-1) attention_probs = self.attn_dropout(attention_probs) context = torch.matmul(attention_probs, value) context = context.permute(0, 2, 1, 3).contiguous() new_context_shape = context.size()[:-2] + (self.hidden_size,) context = context.view(*new_context_shape) output_states = self.out_projection(context) output_states = self.layer_dropout(output_states) return output_states def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'hidden_size': 4, 'num_attention_heads': 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 math from torch import nn import torch.utils.data import torch.optim 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_div_0(in_ptr0, in_ptr1, 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') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 1.0 tmp4 = tmp2 * tmp3 tl.store(out_ptr0 + (x2 + 4 * y3), tmp4, xmask & ymask) @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 x2 = xindex x0 = xindex % 16 tmp0 = tl.load(in_ptr0 + 4 * x2, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (1 + 4 * x2), 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 * x2), 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 * x2), 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 + x2, tmp14, xmask) tl.store(out_ptr1 + x2, 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 x3 = xindex x4 = xindex % 64 x5 = xindex // 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x4, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + x5, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr2 + x5, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tmp5 = tl_math.exp(tmp4) tmp7 = tmp5 / tmp6 tl.store(in_out_ptr0 + x3, tmp7, xmask) @triton.jit def triton_poi_fused_clone_3(in_ptr0, in_ptr1, 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') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + (x2 + 4 * y3), tmp2, xmask & ymask) @triton.jit def triton_poi_fused_clone_4(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) 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, (4, 4), (4, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4), (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), (16, 4, 1)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) assert_size_stride(primals_9, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_10, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_11, (4, 4), (4, 1)) assert_size_stride(primals_12, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_6, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_9, (16, 4), (4, 1), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), out=buf2) del primals_7 buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_div_0[grid(16, 4)](buf0, primals_2, buf3, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del primals_2 buf4 = reinterpret_tensor(buf0, (4, 4, 1, 4), (16, 4, 4, 1), 0) del buf0 triton_poi_fused_clone_div_0[grid(16, 4)](buf1, primals_5, buf4, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del primals_5 buf5 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf3, (16, 4, 1), (4, 1, 0), 0), reinterpret_tensor(buf4, (16, 1, 4), (4, 0, 1), 0), out=buf5) buf6 = reinterpret_tensor(buf1, (4, 4, 4, 1), (16, 4, 1, 64), 0) del buf1 buf7 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) triton_poi_fused__softmax_add_1[grid(64)](buf5, primals_10, buf6, buf7, 64, XBLOCK=64, num_warps=1, num_stages=1) buf8 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused__softmax_add_2[grid(256)](buf8, primals_10, buf6, buf7, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_10 buf9 = reinterpret_tensor(buf7, (4, 4, 4, 1), (16, 4, 1, 1), 0) del buf7 triton_poi_fused_clone_3[grid(16, 4)](buf2, primals_8, buf9, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del primals_8 buf10 = reinterpret_tensor(buf2, (16, 4, 1), (4, 1, 1), 0) del buf2 extern_kernels.bmm(reinterpret_tensor(buf8, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(buf9, (16, 4, 1), (4, 1, 0), 0), out=buf10) buf11 = reinterpret_tensor(buf6, (4, 4, 4, 1), (16, 4, 1, 1), 0) del buf6 triton_poi_fused_clone_4[grid(16, 4)](buf10, buf11, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf12 = reinterpret_tensor(buf10, (16, 4), (4, 1), 0) del buf10 extern_kernels.addmm(primals_12, reinterpret_tensor(buf11, (16, 4), (4, 1), 0), reinterpret_tensor(primals_11, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf12) del primals_12 return reinterpret_tensor(buf12, (4, 4, 4), (16, 4, 1), 0 ), reinterpret_tensor(primals_3, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_6, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_9, (16, 4), (4, 1), 0 ), buf8, reinterpret_tensor(buf11, (16, 4), (4, 1), 0 ), primals_11, reinterpret_tensor(buf9, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf3, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf4, (16, 4, 1), (4, 1, 4), 0) class MultiHeadAttentionNew(nn.Module): """ Multi-head scaled dot-product attention layer. Args: hidden_size: size of the embeddings in the model, also known as d_model num_attention_heads: number of heads in multi-head attention attn_score_dropout: probability of dropout applied to attention scores attn_layer_dropout: probability of dropout applied to the output of the whole layer, but before layer normalization """ def __init__(self, hidden_size, num_attention_heads, attn_score_dropout =0.0, attn_layer_dropout=0.0): super().__init__() if hidden_size % num_attention_heads != 0: raise ValueError( 'The hidden size (%d) is not a multiple of the number of attention heads (%d)' % (hidden_size, num_attention_heads)) self.hidden_size = hidden_size self.num_attention_heads = num_attention_heads self.attn_head_size = int(hidden_size / num_attention_heads) self.attn_scale = math.sqrt(math.sqrt(self.attn_head_size)) self.query_net = nn.Linear(hidden_size, hidden_size) self.key_net = nn.Linear(hidden_size, hidden_size) self.value_net = nn.Linear(hidden_size, hidden_size) self.out_projection = nn.Linear(hidden_size, hidden_size) self.attn_dropout = nn.Dropout(attn_score_dropout) self.layer_dropout = nn.Dropout(attn_layer_dropout) def transpose_for_scores(self, x): new_x_shape = x.size()[:-1] + (self.num_attention_heads, self. attn_head_size) x = x.view(*new_x_shape) return x.permute(0, 2, 1, 3) def forward(self, input_0, input_1, input_2, input_3): primals_1 = self.query_net.weight primals_2 = self.query_net.bias primals_4 = self.key_net.weight primals_5 = self.key_net.bias primals_7 = self.value_net.weight primals_8 = self.value_net.bias primals_11 = self.out_projection.weight primals_12 = self.out_projection.bias primals_3 = input_0 primals_6 = input_1 primals_9 = input_2 primals_10 = input_3 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]
Zenodia/NeMo
MultiHeadAttention
false
1,329
[ "Apache-2.0" ]
0
3c288d8a7caf667c95444c39434e3ebc5f53d911
https://github.com/Zenodia/NeMo/tree/3c288d8a7caf667c95444c39434e3ebc5f53d911
LambdaLayer
import torch import torch.nn as nn import torch.nn.functional as F class LambdaLayer(nn.Module): def __init__(self, planes): super(LambdaLayer, self).__init__() self.planes = planes def forward(self, x): return F.pad(x[:, :, ::2, ::2], (0, 0, 0, 0, self.planes // 4, self .planes // 4), 'constant', 0) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'planes': 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 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_constant_pad_nd_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 96 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x2 = xindex // 4 % 6 x0 = xindex % 2 x3 = xindex // 24 x5 = xindex // 2 % 12 x6 = xindex tmp0 = -1 + x2 tmp1 = tl.full([1], 0, tl.int64) tmp2 = tmp0 >= tmp1 tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tmp2 & tmp4 tmp6 = tl.load(in_ptr0 + (-16 + 2 * x0 + 8 * x5 + 64 * x3), tmp5 & xmask, eviction_policy='evict_last', other=0.0) tl.store(out_ptr0 + x6, tmp6, 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, 6, 2, 2), (24, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_constant_pad_nd_0[grid(96)](arg0_1, buf0, 96, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class LambdaLayerNew(nn.Module): def __init__(self, planes): super(LambdaLayerNew, self).__init__() self.planes = planes def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
ZonghaiZhu/EZBM
LambdaLayer
false
1,330
[ "MIT" ]
0
b4f6fbd10598c79f144b778ef848554ac62a173a
https://github.com/ZonghaiZhu/EZBM/tree/b4f6fbd10598c79f144b778ef848554ac62a173a
AttentionVasvani
import torch from torch import nn class AttentionVasvani(nn.Module): def __init__(self, encoder_dim=128, decoder_dim=128): super(AttentionVasvani, self).__init__() def forward(self, k, q): x = torch.sum(k * q, dim=1, keepdim=True) x /= torch.sqrt(torch.norm(k, p=1, dim=1, keepdim=True)) 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, 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_div_linalg_vector_norm_mul_sqrt_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 tmp15 = tl_math.abs(tmp0) tmp16 = tl_math.abs(tmp3) tmp17 = tmp15 + tmp16 tmp18 = tl_math.abs(tmp7) tmp19 = tmp17 + tmp18 tmp20 = tl_math.abs(tmp11) tmp21 = tmp19 + tmp20 tmp22 = libdevice.sqrt(tmp21) tmp23 = tmp14 / tmp22 tl.store(out_ptr0 + x2, tmp23, 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, 1, 4, 4), (16, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_div_linalg_vector_norm_mul_sqrt_sum_0[grid(64)](arg0_1 , arg1_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 del arg1_1 return buf0, class AttentionVasvaniNew(nn.Module): def __init__(self, encoder_dim=128, decoder_dim=128): super(AttentionVasvaniNew, 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]
a1247418/MT18_LH_human-sleep-classification
AttentionVasvani
false
1,333
[ "MIT" ]
0
c4a40571390aaa14b1cc8a458100e21252fe05d2
https://github.com/a1247418/MT18_LH_human-sleep-classification/tree/c4a40571390aaa14b1cc8a458100e21252fe05d2
LocalResponseNormLayer
import torch import torch.nn as nn import torch.nn.functional as F class LocalResponseNormLayer(nn.Module): def forward(self, tensor, size=5, alpha=9.999999747378752e-05, beta= 0.75, k=1.0): return F.local_response_norm(tensor, size=size, alpha=alpha, beta= beta, k=k) 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 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_add_avg_pool3d_constant_pad_nd_div_mul_pow_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 x1 = xindex // 16 % 4 x3 = xindex tmp48 = tl.load(in_ptr0 + x3, xmask) tmp0 = -2 + x1 tmp1 = tl.full([1], 0, tl.int64) tmp2 = tmp0 >= tmp1 tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tmp2 & tmp4 tmp6 = tl.load(in_ptr0 + (-32 + x3), tmp5 & xmask, other=0.0) tmp7 = tmp6 * tmp6 tmp8 = tl.full(tmp7.shape, 0.0, tmp7.dtype) tmp9 = tl.where(tmp5, tmp7, tmp8) tmp10 = -1 + x1 tmp11 = tmp10 >= tmp1 tmp12 = tmp10 < tmp3 tmp13 = tmp11 & tmp12 tmp14 = tl.load(in_ptr0 + (-16 + x3), tmp13 & xmask, other=0.0) tmp15 = tmp14 * tmp14 tmp16 = tl.full(tmp15.shape, 0.0, tmp15.dtype) tmp17 = tl.where(tmp13, tmp15, tmp16) tmp18 = tmp17 + tmp9 tmp19 = x1 tmp20 = tmp19 >= tmp1 tmp21 = tmp19 < tmp3 tmp22 = tmp20 & tmp21 tmp23 = tl.load(in_ptr0 + x3, tmp22 & xmask, other=0.0) tmp24 = tmp23 * tmp23 tmp25 = tl.full(tmp24.shape, 0.0, tmp24.dtype) tmp26 = tl.where(tmp22, tmp24, tmp25) tmp27 = tmp26 + tmp18 tmp28 = 1 + x1 tmp29 = tmp28 >= tmp1 tmp30 = tmp28 < tmp3 tmp31 = tmp29 & tmp30 tmp32 = tl.load(in_ptr0 + (16 + x3), tmp31 & xmask, other=0.0) tmp33 = tmp32 * tmp32 tmp34 = tl.full(tmp33.shape, 0.0, tmp33.dtype) tmp35 = tl.where(tmp31, tmp33, tmp34) tmp36 = tmp35 + tmp27 tmp37 = 2 + x1 tmp38 = tmp37 >= tmp1 tmp39 = tmp37 < tmp3 tmp40 = tmp38 & tmp39 tmp41 = tl.load(in_ptr0 + (32 + x3), tmp40 & xmask, other=0.0) tmp42 = tmp41 * tmp41 tmp43 = tl.full(tmp42.shape, 0.0, tmp42.dtype) tmp44 = tl.where(tmp40, tmp42, tmp43) tmp45 = tmp44 + tmp36 tmp46 = 0.2 tmp47 = tmp45 * tmp46 tmp49 = 9.999999747378752e-05 tmp50 = tmp47 * tmp49 tmp51 = 1.0 tmp52 = tmp50 + tmp51 tmp53 = 0.75 tmp54 = libdevice.pow(tmp52, tmp53) tmp55 = tmp48 / tmp54 tl.store(in_out_ptr0 + x3, tmp55, 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, 1, 4, 4, 4), (64, 64, 16, 4, 1), torch.float32) buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 get_raw_stream(0) triton_poi_fused_add_avg_pool3d_constant_pad_nd_div_mul_pow_0[grid(256) ](buf1, arg0_1, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf1, class LocalResponseNormLayerNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a-kore/lucent
LocalResponseNormLayer
false
1,334
[ "Apache-2.0" ]
0
6b2b4dfea45c36c99e16f9923104a532df80e0a8
https://github.com/a-kore/lucent/tree/6b2b4dfea45c36c99e16f9923104a532df80e0a8
HSigmoid
import torch import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional class TorchAddScalar(nn.Module): """ Wrapper around torch.add so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.add_func = FloatFunctional() def forward(self, x, y): return self.add_func.add_scalar(x, y) class TorchMulScalar(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul_scalar(x, y) class HSigmoid(nn.Module): def __init__(self): super().__init__() self.relu = nn.ReLU6(inplace=True) self.add_scalar = TorchAddScalar() self.mul_scalar = TorchMulScalar() def forward(self, x): return self.mul_scalar(self.relu(self.add_scalar(x, 3.0)), 1.0 / 6.0) 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 import triton_helpers import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional 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_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 = 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_hardtanh_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class TorchAddScalar(nn.Module): """ Wrapper around torch.add so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.add_func = FloatFunctional() def forward(self, x, y): return self.add_func.add_scalar(x, y) class TorchMulScalar(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul_scalar(x, y) class HSigmoidNew(nn.Module): def __init__(self): super().__init__() self.relu = nn.ReLU6(inplace=True) self.add_scalar = TorchAddScalar() self.mul_scalar = TorchMulScalar() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a1004123217/pytorch-mobile
HSigmoid
false
1,335
[ "MIT" ]
0
97974af3259a2073efbc334d57841efbd3eaadfb
https://github.com/a1004123217/pytorch-mobile/tree/97974af3259a2073efbc334d57841efbd3eaadfb
BinaryClassifier
import torch import torch.nn as nn import torch.nn.functional as F import torch.utils.data class BinaryClassifier(nn.Module): """ Define a neural network that performs binary classification. The network should accept your number of features as input, and produce a single sigmoid value, that can be rounded to a label: 0 or 1, as output. Notes on training: To train a binary classifier in PyTorch, use BCELoss. BCELoss is binary cross entropy loss, documentation: https://pytorch.org/docs/stable/nn.html#torch.nn.BCELoss """ def __init__(self, input_features, hidden_dim, output_dim): """ Initialize the model by setting up linear layers. Use the input parameters to help define the layers of your model. :param input_features: the number of input features in your training/test data :param hidden_dim: helps define the number of nodes in the hidden layer(s) :param output_dim: the number of outputs you want to produce """ super(BinaryClassifier, self).__init__() self.input_dim = input_features self.fc1 = nn.Linear(self.input_dim, hidden_dim) self.fc2 = nn.Linear(hidden_dim, hidden_dim) self.fc3 = nn.Linear(hidden_dim, output_dim) self.dropout = nn.Dropout(0.25) self.sig = nn.Sigmoid() def forward(self, x): """ Perform a forward pass of our model on input features, x. :param x: A batch of input features of size (batch_size, input_features) :return: A single, sigmoid-activated value as output """ x = x.view(-1, self.input_dim) x = F.relu(self.fc1(x)) x = self.dropout(x) x = F.relu(self.fc2(x)) x = self.dropout(x) x = self.fc3(x) return self.sig(x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_features': 4, 'hidden_dim': 4, 'output_dim': 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 import torch.utils.data 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_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) @triton.jit def triton_poi_fused_sigmoid_1(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.sigmoid(tmp2) tl.store(in_out_ptr0 + x2, tmp3, 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((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 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_relu_0[grid(256)](buf1, primals_3, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(buf1, reinterpret_tensor(primals_4, (4, 4), (1, 4 ), 0), out=buf2) buf3 = buf2 del buf2 triton_poi_fused_relu_0[grid(256)](buf3, primals_5, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 buf4 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(buf3, reinterpret_tensor(primals_6, (4, 4), (1, 4 ), 0), out=buf4) buf5 = buf4 del buf4 triton_poi_fused_sigmoid_1[grid(256)](buf5, primals_7, 256, XBLOCK= 128, num_warps=4, num_stages=1) del primals_7 return buf5, reinterpret_tensor(primals_1, (64, 4), (4, 1), 0 ), buf1, buf3, buf5, primals_6, primals_4 class BinaryClassifierNew(nn.Module): """ Define a neural network that performs binary classification. The network should accept your number of features as input, and produce a single sigmoid value, that can be rounded to a label: 0 or 1, as output. Notes on training: To train a binary classifier in PyTorch, use BCELoss. BCELoss is binary cross entropy loss, documentation: https://pytorch.org/docs/stable/nn.html#torch.nn.BCELoss """ def __init__(self, input_features, hidden_dim, output_dim): """ Initialize the model by setting up linear layers. Use the input parameters to help define the layers of your model. :param input_features: the number of input features in your training/test data :param hidden_dim: helps define the number of nodes in the hidden layer(s) :param output_dim: the number of outputs you want to produce """ super(BinaryClassifierNew, self).__init__() self.input_dim = input_features self.fc1 = nn.Linear(self.input_dim, hidden_dim) self.fc2 = nn.Linear(hidden_dim, hidden_dim) self.fc3 = nn.Linear(hidden_dim, output_dim) self.dropout = nn.Dropout(0.25) self.sig = nn.Sigmoid() def forward(self, input_0): primals_2 = self.fc1.weight primals_3 = self.fc1.bias primals_4 = self.fc2.weight primals_5 = self.fc2.bias primals_6 = self.fc3.weight primals_7 = self.fc3.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7]) return output[0]
ZombieSocrates/ml-udacity-case-studies
BinaryClassifier
false
1,336
[ "MIT" ]
0
e4552a11276dc7564c51dac86ae854ca92a88659
https://github.com/ZombieSocrates/ml-udacity-case-studies/tree/e4552a11276dc7564c51dac86ae854ca92a88659
Actor
import torch import torch.nn as nn import torch.nn.functional as F class Actor(nn.Module): def __init__(self, numberOfInputs, numberOfOutputs): super(Actor, self).__init__() self.fc1 = nn.Linear(numberOfInputs, 4096) self.fc2 = nn.Linear(4096, 2048) self.fc3 = nn.Linear(2048, 1024) self.fc4 = nn.Linear(1024, 512) self.fc5 = nn.Linear(512, 256) self.action_head = nn.Linear(256, numberOfOutputs) def forward(self, x): x = F.relu(self.fc1(x)) x = F.relu(self.fc2(x)) x = F.relu(self.fc3(x)) x = F.relu(self.fc4(x)) x = F.relu(self.fc5(x)) action_prob = F.softmax(self.action_head(x), dim=1) return action_prob def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'numberOfInputs': 4, 'numberOfOutputs': 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 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): xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] tl.full([XBLOCK], True, tl.int1) x2 = xindex x0 = xindex % 4096 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_1(in_out_ptr0, 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) x2 = xindex x0 = xindex % 2048 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_2(in_out_ptr0, 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) x2 = xindex x0 = xindex % 1024 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_3(in_out_ptr0, 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) x2 = xindex x0 = xindex % 512 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) tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tl.store(in_out_ptr0 + x2, tmp4, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused_relu_threshold_backward_4(in_out_ptr0, 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) 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 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, None) tl.store(out_ptr0 + x2, tmp6, None) @triton.jit def triton_poi_fused__softmax_5(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__softmax_6(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 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x3, tmp8, 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, (4096, 4), (4, 1)) assert_size_stride(primals_2, (4096,), (1,)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_4, (2048, 4096), (4096, 1)) assert_size_stride(primals_5, (2048,), (1,)) assert_size_stride(primals_6, (1024, 2048), (2048, 1)) assert_size_stride(primals_7, (1024,), (1,)) assert_size_stride(primals_8, (512, 1024), (1024, 1)) assert_size_stride(primals_9, (512,), (1,)) assert_size_stride(primals_10, (256, 512), (512, 1)) assert_size_stride(primals_11, (256,), (1,)) assert_size_stride(primals_12, (4, 256), (256, 1)) assert_size_stride(primals_13, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4096), (4096, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4096), (1, 4), 0), out=buf0) del primals_1 buf1 = reinterpret_tensor(buf0, (4, 4, 4, 4096), (65536, 16384, 4096, 1), 0) del buf0 buf17 = empty_strided_cuda((4, 4, 4, 4096), (65536, 16384, 4096, 1), torch.bool) get_raw_stream(0) triton_poi_fused_relu_threshold_backward_0[grid(262144)](buf1, primals_2, buf17, 262144, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 2048), (2048, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf1, (64, 4096), (4096, 1), 0 ), reinterpret_tensor(primals_4, (4096, 2048), (1, 4096), 0), out=buf2) buf3 = reinterpret_tensor(buf2, (4, 4, 4, 2048), (32768, 8192, 2048, 1), 0) del buf2 buf16 = empty_strided_cuda((4, 4, 4, 2048), (32768, 8192, 2048, 1), torch.bool) triton_poi_fused_relu_threshold_backward_1[grid(131072)](buf3, primals_5, buf16, 131072, XBLOCK=512, num_warps=8, num_stages=1) del primals_5 buf4 = empty_strided_cuda((64, 1024), (1024, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf3, (64, 2048), (2048, 1), 0 ), reinterpret_tensor(primals_6, (2048, 1024), (1, 2048), 0), out=buf4) buf5 = reinterpret_tensor(buf4, (4, 4, 4, 1024), (16384, 4096, 1024, 1), 0) del buf4 buf15 = empty_strided_cuda((4, 4, 4, 1024), (16384, 4096, 1024, 1), torch.bool) triton_poi_fused_relu_threshold_backward_2[grid(65536)](buf5, primals_7, buf15, 65536, XBLOCK=512, num_warps=4, num_stages=1) del primals_7 buf6 = empty_strided_cuda((64, 512), (512, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf5, (64, 1024), (1024, 1), 0 ), reinterpret_tensor(primals_8, (1024, 512), (1, 1024), 0), out=buf6) buf7 = reinterpret_tensor(buf6, (4, 4, 4, 512), (8192, 2048, 512, 1), 0 ) del buf6 buf14 = empty_strided_cuda((4, 4, 4, 512), (8192, 2048, 512, 1), torch.bool) triton_poi_fused_relu_threshold_backward_3[grid(32768)](buf7, primals_9, buf14, 32768, XBLOCK=128, num_warps=4, num_stages=1) del primals_9 buf8 = empty_strided_cuda((64, 256), (256, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf7, (64, 512), (512, 1), 0), reinterpret_tensor(primals_10, (512, 256), (1, 512), 0), out=buf8) buf9 = reinterpret_tensor(buf8, (4, 4, 4, 256), (4096, 1024, 256, 1), 0 ) del buf8 buf13 = empty_strided_cuda((4, 4, 4, 256), (4096, 1024, 256, 1), torch.bool) triton_poi_fused_relu_threshold_backward_4[grid(16384)](buf9, primals_11, buf13, 16384, XBLOCK=256, num_warps=4, num_stages=1) del primals_11 buf10 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_13, reinterpret_tensor(buf9, (64, 256), (256, 1), 0), reinterpret_tensor(primals_12, (256, 4), (1, 256), 0), alpha=1, beta=1, out=buf10) del primals_13 buf11 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_5[grid(256)](buf10, buf11, 256, XBLOCK= 128, num_warps=4, num_stages=1) buf12 = reinterpret_tensor(buf10, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf10 triton_poi_fused__softmax_6[grid(256)](buf11, buf12, 256, XBLOCK= 256, num_warps=4, num_stages=1) del buf11 return (buf12, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(buf1, (64, 4096), (4096, 1), 0), reinterpret_tensor(buf3, (64, 2048), (2048, 1), 0), reinterpret_tensor(buf5, (64, 1024), (1024, 1), 0), reinterpret_tensor(buf7, (64, 512), (512, 1), 0), reinterpret_tensor(buf9, (64, 256), (256, 1), 0), buf12, primals_12, buf13, primals_10, buf14, primals_8, buf15, primals_6, buf16, primals_4, buf17) class ActorNew(nn.Module): def __init__(self, numberOfInputs, numberOfOutputs): super(ActorNew, self).__init__() self.fc1 = nn.Linear(numberOfInputs, 4096) self.fc2 = nn.Linear(4096, 2048) self.fc3 = nn.Linear(2048, 1024) self.fc4 = nn.Linear(1024, 512) self.fc5 = nn.Linear(512, 256) self.action_head = nn.Linear(256, numberOfOutputs) def forward(self, input_0): primals_1 = self.fc1.weight primals_2 = self.fc1.bias primals_4 = self.fc2.weight primals_5 = self.fc2.bias primals_6 = self.fc3.weight primals_7 = self.fc3.bias primals_8 = self.fc4.weight primals_9 = self.fc4.bias primals_10 = self.fc5.weight primals_11 = self.fc5.bias primals_12 = self.action_head.weight primals_13 = self.action_head.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]) return output[0]
ZY-KK/panda
Actor
false
1,337
[ "MIT" ]
0
48fcbd65d563ef74aab2554be8de7662560c43da
https://github.com/ZY-KK/panda/tree/48fcbd65d563ef74aab2554be8de7662560c43da
HSwish
import torch import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional class TorchAddScalar(nn.Module): """ Wrapper around torch.add so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.add_func = FloatFunctional() def forward(self, x, y): return self.add_func.add_scalar(x, y) class TorchMultiply(nn.Module): """Wrapper around torch.mul so that all ops can be found at build""" def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul(x, y) class TorchMulScalar(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul_scalar(x, y) class HSigmoid(nn.Module): def __init__(self): super().__init__() self.relu = nn.ReLU6(inplace=True) self.add_scalar = TorchAddScalar() self.mul_scalar = TorchMulScalar() def forward(self, x): return self.mul_scalar(self.relu(self.add_scalar(x, 3.0)), 1.0 / 6.0) class HSwish(nn.Module): def __init__(self): super().__init__() self.hsig = HSigmoid() self.mul = TorchMultiply() def forward(self, x): return self.mul(x, self.hsig(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 import torch.nn as nn import torch.nn.parallel from torch.nn.quantized.modules import FloatFunctional 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_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 = 0.16666666666666666 tmp8 = tmp6 * tmp7 tmp9 = tmp0 * 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_hardtanh_mul_0[grid(256)](arg0_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) del arg0_1 return buf0, class TorchAddScalar(nn.Module): """ Wrapper around torch.add so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.add_func = FloatFunctional() def forward(self, x, y): return self.add_func.add_scalar(x, y) class TorchMultiply(nn.Module): """Wrapper around torch.mul so that all ops can be found at build""" def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul(x, y) class TorchMulScalar(nn.Module): """Wrapper around torch.mul so that all ops can be found at build y must be a scalar, needed for quantization """ def __init__(self): super().__init__() self.mul_func = FloatFunctional() def forward(self, x, y): return self.mul_func.mul_scalar(x, y) class HSigmoid(nn.Module): def __init__(self): super().__init__() self.relu = nn.ReLU6(inplace=True) self.add_scalar = TorchAddScalar() self.mul_scalar = TorchMulScalar() def forward(self, x): return self.mul_scalar(self.relu(self.add_scalar(x, 3.0)), 1.0 / 6.0) class HSwishNew(nn.Module): def __init__(self): super().__init__() self.hsig = HSigmoid() self.mul = TorchMultiply() def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a1004123217/pytorch-mobile
HSwish
false
1,338
[ "MIT" ]
0
97974af3259a2073efbc334d57841efbd3eaadfb
https://github.com/a1004123217/pytorch-mobile/tree/97974af3259a2073efbc334d57841efbd3eaadfb
MSERegularizedLoss
from torch.nn import Module import torch import torch as tc import torch.nn.functional as F from torch.nn.modules.module import Module class MSERegularizedLoss(Module): def __init__(self, alpha=1): super(MSERegularizedLoss, self).__init__() self.alpha = alpha def forward(self, weights, prediction, target): mse = F.mse_loss(prediction, target) reg = tc.sum(tc.pow(weights, 2)) return mse + self.alpha * reg 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 [[], {}]
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.nn import Module from torch.nn.modules.module import Module 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_mse_loss_mul_pow_sum_0(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, 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) tmp7 = tl.load(in_ptr2 + r0, None) tmp2 = tmp0 - tmp1 tmp3 = tmp2 * tmp2 tmp4 = tl.broadcast_to(tmp3, [RBLOCK]) tmp6 = triton_helpers.promote_to_tensor(tl.sum(tmp4, 0)) tmp8 = tmp7 * tmp7 tmp9 = tl.broadcast_to(tmp8, [RBLOCK]) tmp11 = triton_helpers.promote_to_tensor(tl.sum(tmp9, 0)) tmp12 = 256.0 tmp13 = tmp6 / tmp12 tmp14 = 1.0 tmp15 = tmp11 * tmp14 tmp16 = tmp13 + tmp15 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp16, None) 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((), (), torch.float32) buf2 = buf0 del buf0 get_raw_stream(0) triton_per_fused_add_mse_loss_mul_pow_sum_0[grid(1)](buf2, arg1_1, arg0_1, arg2_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 return buf2, class MSERegularizedLossNew(Module): def __init__(self, alpha=1): super(MSERegularizedLossNew, self).__init__() self.alpha = alpha 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]
aalto-intelligent-robotics/mc-dropout-notebooks
MSERegularizedLoss
false
1,339
[ "MIT" ]
0
fc174c05166061eb21d4c5816c519828c8e72916
https://github.com/aalto-intelligent-robotics/mc-dropout-notebooks/tree/fc174c05166061eb21d4c5816c519828c8e72916
CompositeActivation
import torch class CompositeActivation(torch.nn.Module): def forward(self, x): x = torch.atan(x) return torch.cat([x / 0.67, x * x / 0.6], 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.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_cat_0(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 x1 = xindex // 16 % 8 x0 = xindex % 16 x2 = xindex // 128 x3 = xindex tmp0 = x1 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (x0 + 16 * x1 + 64 * x2), tmp4 & xmask, other=0.0) tmp6 = libdevice.atan(tmp5) tmp7 = 1.4925373134328357 tmp8 = tmp6 * tmp7 tmp9 = tl.full(tmp8.shape, 0.0, tmp8.dtype) tmp10 = tl.where(tmp4, tmp8, tmp9) tmp11 = tmp0 >= tmp3 tl.full([1], 8, tl.int64) tmp14 = tl.load(in_ptr0 + (x0 + 16 * (-4 + x1) + 64 * x2), tmp11 & xmask, other=0.0) tmp15 = libdevice.atan(tmp14) tmp16 = tmp15 * tmp15 tmp17 = 1.6666666666666667 tmp18 = tmp16 * tmp17 tmp19 = tl.full(tmp18.shape, 0.0, tmp18.dtype) tmp20 = tl.where(tmp11, tmp18, tmp19) tmp21 = tl.where(tmp4, tmp10, tmp20) tl.store(out_ptr0 + x3, tmp21, 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, 8, 4, 4), (128, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_cat_0[grid(512)](arg0_1, buf0, 512, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf0, class CompositeActivationNew(torch.nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a-kore/lucent
CompositeActivation
false
1,340
[ "Apache-2.0" ]
0
6b2b4dfea45c36c99e16f9923104a532df80e0a8
https://github.com/a-kore/lucent/tree/6b2b4dfea45c36c99e16f9923104a532df80e0a8
Upsample
import torch import torch.nn as nn class Upsample(nn.Module): def __init__(self, factor): super(Upsample, self).__init__() self.factor = factor def forward(self, x): x = nn.functional.interpolate(x, scale_factor=self.factor, mode= 'bilinear', align_corners=False) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'factor': 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 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__to_copy__unsafe_index_add_arange_clamp_mul_sub_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) x1 = xindex // 16 % 16 x0 = xindex % 16 x2 = xindex // 256 x3 = xindex tmp0 = x1 tmp1 = tmp0.to(tl.float32) tmp2 = 0.5 tmp3 = tmp1 + tmp2 tmp4 = 0.25 tmp5 = tmp3 * tmp4 tmp6 = tmp5 - tmp2 tmp7 = 0.0 tmp8 = triton_helpers.maximum(tmp6, tmp7) tmp9 = tmp8.to(tl.int32) tmp10 = tl.full([1], 1, tl.int64) tmp11 = tmp9 + tmp10 tmp12 = tl.full([1], 3, tl.int64) tmp13 = triton_helpers.minimum(tmp11, tmp12) tmp14 = x0 tmp15 = tmp14.to(tl.float32) tmp16 = tmp15 + tmp2 tmp17 = tmp16 * tmp4 tmp18 = tmp17 - tmp2 tmp19 = triton_helpers.maximum(tmp18, tmp7) tmp20 = tmp19.to(tl.int32) tmp21 = tmp20 + tmp10 tmp22 = triton_helpers.minimum(tmp21, tmp12) tmp23 = tl.load(in_ptr0 + (tmp22 + 4 * tmp13 + 16 * x2), None, eviction_policy='evict_last') tmp24 = tl.load(in_ptr0 + (tmp20 + 4 * tmp13 + 16 * x2), None, eviction_policy='evict_last') tmp25 = tmp23 - tmp24 tmp26 = tmp20.to(tl.float32) tmp27 = tmp19 - tmp26 tmp28 = triton_helpers.maximum(tmp27, tmp7) tmp29 = 1.0 tmp30 = triton_helpers.minimum(tmp28, tmp29) tmp31 = tmp25 * tmp30 tmp32 = tl.load(in_ptr0 + (tmp20 + 4 * tmp9 + 16 * x2), None, eviction_policy='evict_last') tmp33 = tl.load(in_ptr0 + (tmp22 + 4 * tmp9 + 16 * x2), None, eviction_policy='evict_last') tmp34 = tmp33 - tmp32 tmp35 = tmp34 * tmp30 tmp36 = tmp32 + tmp35 tmp37 = tmp24 + tmp31 tmp38 = tmp37 - tmp36 tmp39 = tmp9.to(tl.float32) tmp40 = tmp8 - tmp39 tmp41 = triton_helpers.maximum(tmp40, tmp7) tmp42 = triton_helpers.minimum(tmp41, tmp29) tmp43 = tmp38 * tmp42 tmp44 = tmp36 + tmp43 tl.store(in_out_ptr0 + x3, tmp44, 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((4, 4, 16, 16), (1024, 256, 16, 1), torch .float32) buf2 = buf0 del buf0 buf3 = buf2 del buf2 get_raw_stream(0) triton_poi_fused__to_copy__unsafe_index_add_arange_clamp_mul_sub_0[grid (4096)](buf3, arg0_1, 4096, XBLOCK=128, num_warps=4, num_stages=1) del arg0_1 return buf3, class UpsampleNew(nn.Module): def __init__(self, factor): super(UpsampleNew, self).__init__() self.factor = factor def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a3ahmad/DDPM
Upsample
false
1,341
[ "MIT" ]
0
180440740cb82c2b4e7e0b06a0d8e662b5aa3f05
https://github.com/a3ahmad/DDPM/tree/180440740cb82c2b4e7e0b06a0d8e662b5aa3f05
UpSample
import torch import torch.nn as nn class UpSample(nn.Module): def __init__(self, n_channels, factor=2): super(UpSample, self).__init__() out_channels = n_channels * factor * factor self.proj = nn.Conv2d(n_channels, out_channels, 1, 1, 0) self.up = nn.PixelShuffle(factor) self.init_weight() def forward(self, x): x = self.proj(x) x = self.up(x) return x def init_weight(self): nn.init.xavier_normal_(self.proj.weight, gain=1.0) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'n_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 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_pixel_shuffle_0(in_ptr0, in_ptr1, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 512 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 x5 = xindex y0 = yindex % 4 y1 = yindex // 4 % 2 y2 = yindex // 8 % 4 y6 = yindex // 32 y3 = yindex // 32 % 4 y7 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 4 * y2 + 16 * x5 + 32 * y1 + 64 * y6), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + (x5 + 2 * y1 + 4 * y3), xmask & ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tl.store(out_ptr0 + (x5 + 2 * y7), tmp2, xmask & ymask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (16, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_2, (16,), (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=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 16, 4, 4), (256, 16, 4, 1)) buf1 = empty_strided_cuda((4, 4, 4, 2, 4, 2), (256, 64, 16, 8, 2, 1 ), torch.float32) get_raw_stream(0) triton_poi_fused_pixel_shuffle_0[grid(512, 2)](buf0, primals_2, buf1, 512, 2, XBLOCK=2, YBLOCK=256, num_warps=4, num_stages=1) del buf0 del primals_2 return reinterpret_tensor(buf1, (4, 4, 8, 8), (256, 64, 8, 1), 0 ), primals_1, primals_3 class UpSampleNew(nn.Module): def __init__(self, n_channels, factor=2): super(UpSampleNew, self).__init__() out_channels = n_channels * factor * factor self.proj = nn.Conv2d(n_channels, out_channels, 1, 1, 0) self.up = nn.PixelShuffle(factor) self.init_weight() def init_weight(self): nn.init.xavier_normal_(self.proj.weight, gain=1.0) def forward(self, input_0): primals_1 = self.proj.weight primals_2 = self.proj.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
aa10402tw/RealTime-Segmentation
UpSample
false
1,342
[ "MIT" ]
0
8c5cf13cd5570c48fa7bae9e6ec014989450889d
https://github.com/aa10402tw/RealTime-Segmentation/tree/8c5cf13cd5570c48fa7bae9e6ec014989450889d
Attention
import torch import torch.nn.functional as F import torch.nn as nn def new_parameter(*size): out = nn.Parameter(torch.FloatTensor(*size)) torch.nn.init.xavier_normal_(out) return out class Attention(nn.Module): def __init__(self, attention_size): super(Attention, self).__init__() self.attention = new_parameter(attention_size, 1) def forward(self, x_in): attention_score = torch.matmul(x_in, self.attention).squeeze() attention_score = F.softmax(attention_score, dim=0).view(x_in.size( 0), x_in.size(1), 1) scored_x = x_in * attention_score condensed_x = torch.sum(scored_x, dim=1) return condensed_x def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'attention_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 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__softmax_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 x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (4 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (8 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (12 + 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_1(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_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (4 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (8 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (12 + 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) @triton.jit def triton_poi_fused_mul_sum_2(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 x0 = xindex % 4 x1 = xindex // 4 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 16 * x1), xmask) tmp1 = tl.load(in_ptr1 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr0 + (4 + x0 + 16 * x1), xmask) tmp4 = tl.load(in_ptr1 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (8 + x0 + 16 * x1), xmask) tmp8 = tl.load(in_ptr1 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr0 + (12 + x0 + 16 * x1), xmask) tmp12 = tl.load(in_ptr1 + (3 + 4 * x1), 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 tl.store(out_ptr0 + x2, tmp14, xmask) def call(args): primals_1, primals_2 = args args.clear() assert_size_stride(primals_1, (4, 1), (1, 1)) assert_size_stride(primals_2, (4, 4, 4), (16, 4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 1), (1, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_2, (16, 4), (4, 1), 0), primals_1, out=buf0) del primals_1 buf1 = empty_strided_cuda((4, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(16)](buf0, buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_poi_fused__softmax_1[grid(16)](buf1, buf2, 16, XBLOCK=16, num_warps=1, num_stages=1) buf3 = buf1 del buf1 triton_poi_fused_mul_sum_2[grid(16)](primals_2, buf2, buf3, 16, XBLOCK=16, num_warps=1, num_stages=1) del buf2 return buf3, primals_2, buf0 def new_parameter(*size): out = nn.Parameter(torch.FloatTensor(*size)) torch.nn.init.xavier_normal_(out) return out class AttentionNew(nn.Module): def __init__(self, attention_size): super(AttentionNew, self).__init__() self.attention = new_parameter(attention_size, 1) def forward(self, input_0): primals_1 = self.attention primals_2 = input_0 output = call([primals_1, primals_2]) return output[0]
aaronbae/acl2020-dialogue-coherence-assessment
Attention
false
1,343
[ "MIT" ]
0
98142558b2f80ace390d6b583a3242a373803a85
https://github.com/aaronbae/acl2020-dialogue-coherence-assessment/tree/98142558b2f80ace390d6b583a3242a373803a85
MaxPool2dLayer
import torch import torch.nn as nn import torch.nn.functional as F class MaxPool2dLayer(nn.Module): def forward(self, tensor, kernel_size=(3, 3), stride=(1, 1), padding=0, ceil_mode=False): return F.max_pool2d(tensor, kernel_size, stride=stride, padding= padding, ceil_mode=ceil_mode) 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.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_max_pool2d_with_indices_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 % 2 x1 = xindex // 2 % 2 x2 = xindex // 4 x3 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 4 * x1 + 16 * x2), xmask) tmp1 = tl.load(in_ptr0 + (1 + x0 + 4 * x1 + 16 * x2), xmask) tmp3 = tl.load(in_ptr0 + (2 + x0 + 4 * x1 + 16 * x2), xmask) tmp5 = tl.load(in_ptr0 + (4 + x0 + 4 * x1 + 16 * x2), xmask) tmp7 = tl.load(in_ptr0 + (5 + x0 + 4 * x1 + 16 * x2), xmask) tmp9 = tl.load(in_ptr0 + (6 + x0 + 4 * x1 + 16 * x2), xmask) tmp11 = tl.load(in_ptr0 + (8 + x0 + 4 * x1 + 16 * x2), xmask) tmp13 = tl.load(in_ptr0 + (9 + x0 + 4 * x1 + 16 * x2), xmask) tmp15 = tl.load(in_ptr0 + (10 + x0 + 4 * x1 + 16 * x2), xmask) tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp3, tmp2) tmp6 = triton_helpers.maximum(tmp5, tmp4) tmp8 = triton_helpers.maximum(tmp7, tmp6) tmp10 = triton_helpers.maximum(tmp9, tmp8) tmp12 = triton_helpers.maximum(tmp11, tmp10) tmp14 = triton_helpers.maximum(tmp13, tmp12) tmp16 = triton_helpers.maximum(tmp15, tmp14) tl.store(out_ptr0 + x3, tmp16, 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, 2, 2), (16, 4, 2, 1), torch.float32) get_raw_stream(0) triton_poi_fused_max_pool2d_with_indices_0[grid(64)](arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 return buf0, class MaxPool2dLayerNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
a-kore/lucent
MaxPool2dLayer
false
1,344
[ "Apache-2.0" ]
0
6b2b4dfea45c36c99e16f9923104a532df80e0a8
https://github.com/a-kore/lucent/tree/6b2b4dfea45c36c99e16f9923104a532df80e0a8
LocalNet
import torch import torch.nn as nn class LocalNet(nn.Module): def forward(self, x_in): """Double convolutional block :param x_in: image features :returns: image features :rtype: Tensor """ x = self.lrelu(self.conv1(self.refpad(x_in))) x = self.lrelu(self.conv2(self.refpad(x))) return x def __init__(self, in_channels=16, out_channels=64): """Double convolutional block :param in_channels: number of input channels :param out_channels: number of output channels :returns: N/A :rtype: N/A """ super(LocalNet, self).__init__() self.conv1 = nn.Conv2d(in_channels, out_channels, 3, 1, 0, 1) self.conv2 = nn.Conv2d(out_channels, out_channels, 3, 1, 0, 1) self.lrelu = nn.LeakyReLU() self.refpad = nn.ReflectionPad2d(1) def get_inputs(): return [torch.rand([4, 16, 4, 4])] 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.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_reflection_pad2d_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 2304 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 6 x1 = xindex // 6 % 6 x2 = xindex // 36 x3 = xindex tmp0 = tl.load(in_ptr0 + (15 + -1 * tl_math.abs(-3 + tl_math.abs(-1 + x0)) + -4 * tl_math.abs(-3 + tl_math.abs(-1 + x1)) + 16 * x2), xmask, eviction_policy='evict_last') tl.store(out_ptr0 + x3, tmp0, xmask) @triton.jit def triton_poi_fused_convolution_leaky_relu_1(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 // 16 % 64 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tl.store(out_ptr0 + x3, tmp4, None) @triton.jit def triton_poi_fused_convolution_leaky_relu_reflection_pad2d_2(in_ptr0, in_ptr1, in_ptr2, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 9216 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 6 x1 = xindex // 6 % 6 x4 = xindex // 36 x2 = xindex // 36 % 64 x5 = xindex tmp0 = tl.load(in_ptr0 + (15 + -1 * tl_math.abs(-3 + tl_math.abs(-1 + x0)) + -4 * tl_math.abs(-3 + tl_math.abs(-1 + x1)) + 16 * x4), xmask, eviction_policy='evict_last').to(tl.int1) tmp1 = tl.load(in_ptr1 + (15 + -1 * tl_math.abs(-3 + tl_math.abs(-1 + x0)) + -4 * tl_math.abs(-3 + tl_math.abs(-1 + x1)) + 16 * x4), xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr2 + x2, xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = 0.01 tmp5 = tmp3 * tmp4 tmp6 = tl.where(tmp0, tmp3, tmp5) tl.store(out_ptr0 + x5, tmp6, xmask) @triton.jit def triton_poi_fused_convolution_leaky_relu_3(in_ptr0, in_ptr1, out_ptr0, out_ptr1, 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 // 16 % 64 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp5 = 0.01 tmp6 = tmp2 * tmp5 tmp7 = tl.where(tmp4, tmp2, tmp6) tl.store(out_ptr0 + x3, tmp4, None) tl.store(out_ptr1 + x3, tmp7, None) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 16, 4, 4), (256, 16, 4, 1)) assert_size_stride(primals_2, (64, 16, 3, 3), (144, 9, 3, 1)) assert_size_stride(primals_3, (64,), (1,)) assert_size_stride(primals_4, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 16, 6, 6), (576, 36, 6, 1), torch.float32 ) get_raw_stream(0) triton_poi_fused_reflection_pad2d_0[grid(2304)](primals_1, buf0, 2304, XBLOCK=128, num_warps=4, num_stages=1) del primals_1 buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 64, 4, 4), (1024, 16, 4, 1)) buf2 = empty_strided_cuda((4, 64, 4, 4), (1024, 16, 4, 1), torch.bool) triton_poi_fused_convolution_leaky_relu_1[grid(4096)](buf1, primals_3, buf2, 4096, XBLOCK=128, num_warps=4, num_stages=1) buf3 = empty_strided_cuda((4, 64, 6, 6), (2304, 36, 6, 1), torch. float32) triton_poi_fused_convolution_leaky_relu_reflection_pad2d_2[grid(9216)]( buf2, buf1, primals_3, buf3, 9216, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 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, 4, 4), (1024, 16, 4, 1)) buf5 = empty_strided_cuda((4, 64, 4, 4), (1024, 16, 4, 1), torch.bool) buf6 = buf1 del buf1 triton_poi_fused_convolution_leaky_relu_3[grid(4096)](buf4, primals_5, buf5, buf6, 4096, XBLOCK=256, num_warps=4, num_stages=1) del buf4 del primals_5 return buf6, primals_2, primals_4, buf0, buf2, buf3, buf5 class LocalNetNew(nn.Module): def __init__(self, in_channels=16, out_channels=64): """Double convolutional block :param in_channels: number of input channels :param out_channels: number of output channels :returns: N/A :rtype: N/A """ super(LocalNetNew, self).__init__() self.conv1 = nn.Conv2d(in_channels, out_channels, 3, 1, 0, 1) self.conv2 = nn.Conv2d(out_channels, out_channels, 3, 1, 0, 1) self.lrelu = nn.LeakyReLU() self.refpad = nn.ReflectionPad2d(1) def forward(self, input_0): primals_2 = self.conv1.weight primals_3 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
ZombaSY/DeepLPF
LocalNet
false
1,345
[ "BSD-3-Clause" ]
0
adce64ae01bc9e32f465a354cb1f6534f0d13597
https://github.com/ZombaSY/DeepLPF/tree/adce64ae01bc9e32f465a354cb1f6534f0d13597
InvConv
import torch import numpy as np import torch.nn as nn import torch.nn.functional as F import torch.optim class InvConv(nn.Module): """Invertible 1x1 Convolution for 2D inputs. Originally described in Glow (https://arxiv.org/abs/1807.03039). Does not support LU-decomposed version. Args: num_channels (int): Number of channels in the input and output. """ def __init__(self, num_channels): super(InvConv, self).__init__() self.num_channels = num_channels w_init = np.random.randn(num_channels, num_channels) w_init = np.linalg.qr(w_init)[0].astype(np.float32) self.weight = nn.Parameter(torch.from_numpy(w_init)) def forward(self, x, sldj, reverse=False): ldj = torch.slogdet(self.weight)[1] * x.size(2) * x.size(3) if reverse: weight = torch.inverse(self.weight.double()).float() sldj = sldj - ldj else: weight = self.weight sldj = sldj + ldj weight = weight.view(self.num_channels, self.num_channels, 1, 1) z = F.conv2d(x, weight) return z, sldj def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_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 numpy as np import torch.nn as nn import torch.optim 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_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 + 0) tmp2 = tl.broadcast_to(tmp1, [XBLOCK]) tmp3 = 4.0 tmp4 = tmp2 * tmp3 tmp5 = tmp4 * tmp3 tmp6 = tmp0 + tmp5 tl.store(out_ptr0 + x0, tmp6, 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, 4, 4, 4), (64, 16, 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 = torch.ops.aten._linalg_slogdet.default(primals_1) buf2 = buf0[1] buf3 = buf0[2] buf4 = buf0[3] del buf0 buf5 = 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_3, buf2, buf5, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf2 del primals_3 buf6 = extern_kernels.convolution(primals_2, reinterpret_tensor( primals_1, (4, 4, 1, 1), (4, 1, 1, 1), 0), stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf6, (4, 4, 4, 4), (64, 16, 4, 1)) return buf6, buf5, primals_2, buf3, buf4, reinterpret_tensor(primals_1, (4, 4, 1, 1), (4, 1, 1, 1), 0) class InvConvNew(nn.Module): """Invertible 1x1 Convolution for 2D inputs. Originally described in Glow (https://arxiv.org/abs/1807.03039). Does not support LU-decomposed version. Args: num_channels (int): Number of channels in the input and output. """ def __init__(self, num_channels): super(InvConvNew, self).__init__() self.num_channels = num_channels w_init = np.random.randn(num_channels, num_channels) w_init = np.linalg.qr(w_init)[0].astype(np.float32) self.weight = nn.Parameter(torch.from_numpy(w_init)) def forward(self, input_0, input_1): primals_1 = self.weight primals_2 = input_0 primals_3 = input_1 output = call([primals_1, primals_2, primals_3]) return output[0], output[1]
a-heintz/Flow-based-RelativeStateEstimation
InvConv
false
1,346
[ "MIT" ]
0
9633fd74323db1206969186c2d2caa7a766e1948
https://github.com/a-heintz/Flow-based-RelativeStateEstimation/tree/9633fd74323db1206969186c2d2caa7a766e1948
DiceLoss
import torch from torch import nn class DiceLoss(nn.Module): def __init__(self): super(DiceLoss, self).__init__() def forward(self, predict, target): N = target.size(0) smooth = 1 predict_flat = predict.view(N, -1) target_flat = target.view(N, -1) intersection = (predict_flat * target_flat).sum(1) union = predict_flat.sum(1) + target_flat.sum(1) loss = (2 * intersection + smooth) / (union + smooth) loss = 1 - loss.sum() / N 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 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_per_fused_mul_sum_0(in_ptr0, in_ptr1, out_ptr0, out_ptr1, out_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 4 RBLOCK: tl.constexpr = 64 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 + 64 * x0), xmask, other=0.0) tmp1 = tl.load(in_ptr1 + (r1 + 64 * 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_mul_rsub_sum_1(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 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 = 1.0 tmp4 = tmp2 + tmp3 tmp7 = tmp5 + tmp6 tmp8 = tmp7 + tmp3 tmp9 = tmp4 / tmp8 tmp10 = tl.broadcast_to(tmp9, [XBLOCK, RBLOCK]) tmp12 = tl.sum(tmp10, 1)[:, None] tmp13 = 0.25 tmp14 = tmp12 * tmp13 tmp15 = tmp3 - tmp14 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp15, 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,), (1,), torch.float32) buf1 = empty_strided_cuda((4,), (1,), torch.float32) buf2 = empty_strided_cuda((4,), (1,), torch.float32) get_raw_stream(0) triton_per_fused_mul_sum_0[grid(4)](arg1_1, arg0_1, buf0, buf1, buf2, 4, 64, 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_mul_rsub_sum_1[grid(1)](buf4, buf0, buf1, buf2, 1, 4, XBLOCK=1, num_warps=2, num_stages=1) del buf0 del buf1 del buf2 return buf4, class DiceLossNew(nn.Module): def __init__(self): super(DiceLossNew, 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]
abc008/MT-Brain-Network
DiceLoss
false
1,347
[ "MIT" ]
0
a823722d4d3211c955bc1370bd8399d27c6640f4
https://github.com/abc008/MT-Brain-Network/tree/a823722d4d3211c955bc1370bd8399d27c6640f4
GLU
import torch from torch import nn class GLU(nn.Module): def __init__(self, input_num): super(GLU, self).__init__() self.sigmoid = nn.Sigmoid() self.linear = nn.Linear(input_num, input_num) def forward(self, x): lin = self.linear(x.permute(0, 2, 3, 1)) lin = lin.permute(0, 3, 1, 2) sig = self.sigmoid(x) res = lin * sig return res def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_num': 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 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_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 x2 = xindex y0 = yindex % 16 y1 = yindex // 16 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 16 * x2 + 64 * y1), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 4 * y3), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_mul_sigmoid_1(in_out_ptr0, in_ptr0, in_ptr1, 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 x2 = xindex y3 = yindex y0 = yindex % 16 y1 = yindex // 16 tmp0 = tl.load(in_out_ptr0 + (x2 + 4 * y3), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + x2, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + (y0 + 16 * x2 + 64 * y1), xmask & ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp4 = tl.sigmoid(tmp3) tmp5 = tmp2 * tmp4 tl.debug_barrier() tl.store(in_out_ptr0 + (x2 + 4 * y3), tmp5, xmask & ymask) 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, 4), (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_clone_0[grid(64, 4)](primals_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf0, (64, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 1, 16, 4), 0) del buf1 triton_poi_fused_mul_sigmoid_1[grid(64, 4)](buf2, primals_3, primals_1, 64, 4, XBLOCK=4, YBLOCK=64, num_warps=4, num_stages=1) del primals_3 return buf2, primals_1, reinterpret_tensor(buf0, (64, 4), (4, 1), 0) class GLUNew(nn.Module): def __init__(self, input_num): super(GLUNew, self).__init__() self.sigmoid = nn.Sigmoid() self.linear = nn.Linear(input_num, input_num) def forward(self, input_0): primals_2 = self.linear.weight primals_3 = self.linear.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
aagnone3/dc19t2
GLU
false
1,348
[ "Apache-2.0" ]
0
cc7baf2a8fe73d28c224f0bf68b5355efd96c24f
https://github.com/aagnone3/dc19t2/tree/cc7baf2a8fe73d28c224f0bf68b5355efd96c24f
SqueezeExcite
import torch import torch.nn as nn import torch.nn.parallel import torch.nn.functional as F def _make_divisible(v, divisor, min_value=None): """ This function is taken from the original tf repo. It ensures that all layers have a channel number that is divisible by 8 It can be seen here: https://github.com/tensorflow/models/blob/master/research/slim/nets/mobilenet/mobilenet.py """ if min_value is None: min_value = divisor new_v = max(min_value, int(v + divisor / 2) // divisor * divisor) if new_v < 0.9 * v: new_v += divisor return new_v def hard_sigmoid(x, inplace: 'bool'=False): if inplace: return x.add_(3.0).clamp_(0.0, 6.0).div_(6.0) else: return F.relu6(x + 3.0) / 6.0 class SqueezeExcite(nn.Module): def __init__(self, in_chs, se_ratio=0.25, reduced_base_chs=None, act_layer=nn.ReLU, gate_fn=hard_sigmoid, divisor=4, **_): super(SqueezeExcite, self).__init__() self.gate_fn = gate_fn reduced_chs = _make_divisible((reduced_base_chs or in_chs) * se_ratio, divisor) self.avg_pool = nn.AdaptiveAvgPool2d(1) self.conv_reduce = nn.Conv2d(in_chs, reduced_chs, 1, bias=True) self.act1 = act_layer(inplace=True) self.conv_expand = nn.Conv2d(reduced_chs, in_chs, 1, bias=True) def forward(self, x): x_se = self.avg_pool(x) x_se = self.conv_reduce(x_se) x_se = self.act1(x_se) x_se = self.conv_expand(x_se) x = x * self.gate_fn(x_se) return x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_chs': 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 import torch.nn.parallel 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_per_fused_mean_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 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, 0) tmp4 = tl.sum(tmp3, 1)[:, None] tmp5 = 16.0 tmp6 = tmp4 / tmp5 tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp6, xmask) @triton.jit def triton_poi_fused_convolution_relu_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.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_convolution_div_hardtanh_mul_2(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 x4 = xindex // 16 x1 = xindex // 16 % 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + x4, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = 3.0 tmp5 = tmp3 + tmp4 tmp6 = 0.0 tmp7 = triton_helpers.maximum(tmp5, tmp6) tmp8 = 6.0 tmp9 = triton_helpers.minimum(tmp7, tmp8) tmp10 = 0.16666666666666666 tmp11 = tmp9 * tmp10 tmp12 = tmp0 * tmp11 tl.store(out_ptr0 + x3, tmp12, xmask) @triton.jit def triton_poi_fused_add_convolution_hardtanh_backward_3(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_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 3.0 tmp4 = tmp2 + tmp3 tmp5 = 0.0 tmp6 = tmp4 <= tmp5 tmp7 = 6.0 tmp8 = tmp4 >= tmp7 tmp9 = tmp6 | tmp8 tl.store(out_ptr0 + x2, tmp9, 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, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4, 1, 1), (4, 1, 1, 1)) assert_size_stride(primals_5, (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_mean_0[grid(16)](buf1, primals_1, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) buf2 = extern_kernels.convolution(buf1, primals_2, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 4, 1, 1), (4, 1, 1, 1)) buf3 = buf2 del buf2 triton_poi_fused_convolution_relu_1[grid(16)](buf3, primals_3, 16, XBLOCK=16, num_warps=1, num_stages=1) del primals_3 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, 4, 1, 1), (4, 1, 1, 1)) buf5 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_convolution_div_hardtanh_mul_2[grid(256)]( primals_1, buf4, primals_5, buf5, 256, XBLOCK=128, num_warps=4, num_stages=1) buf6 = empty_strided_cuda((4, 4, 1, 1), (4, 1, 1, 1), torch.bool) triton_poi_fused_add_convolution_hardtanh_backward_3[grid(16)](buf4, primals_5, buf6, 16, XBLOCK=16, num_warps=1, num_stages=1) del buf4 del primals_5 return buf5, primals_1, primals_2, primals_4, buf1, buf3, buf6 def _make_divisible(v, divisor, min_value=None): """ This function is taken from the original tf repo. It ensures that all layers have a channel number that is divisible by 8 It can be seen here: https://github.com/tensorflow/models/blob/master/research/slim/nets/mobilenet/mobilenet.py """ if min_value is None: min_value = divisor new_v = max(min_value, int(v + divisor / 2) // divisor * divisor) if new_v < 0.9 * v: new_v += divisor return new_v def hard_sigmoid(x, inplace: 'bool'=False): if inplace: return x.add_(3.0).clamp_(0.0, 6.0).div_(6.0) else: return F.relu6(x + 3.0) / 6.0 class SqueezeExciteNew(nn.Module): def __init__(self, in_chs, se_ratio=0.25, reduced_base_chs=None, act_layer=nn.ReLU, gate_fn=hard_sigmoid, divisor=4, **_): super(SqueezeExciteNew, self).__init__() self.gate_fn = gate_fn reduced_chs = _make_divisible((reduced_base_chs or in_chs) * se_ratio, divisor) self.avg_pool = nn.AdaptiveAvgPool2d(1) self.conv_reduce = nn.Conv2d(in_chs, reduced_chs, 1, bias=True) self.act1 = act_layer(inplace=True) self.conv_expand = nn.Conv2d(reduced_chs, in_chs, 1, bias=True) def forward(self, input_0): primals_2 = self.conv_reduce.weight primals_3 = self.conv_reduce.bias primals_4 = self.conv_expand.weight primals_5 = self.conv_expand.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
a1004123217/pytorch-mobile
SqueezeExcite
false
1,349
[ "MIT" ]
0
97974af3259a2073efbc334d57841efbd3eaadfb
https://github.com/a1004123217/pytorch-mobile/tree/97974af3259a2073efbc334d57841efbd3eaadfb
SpeakNet
import math import torch import torch.nn as nn import torch.optim def xavier_init(module): """ Xavier initializer for module parameters. """ for parameter in module.parameters(): if len(parameter.data.shape) == 1: parameter.data.fill_(0) else: fan_in = parameter.data.size(0) fan_out = parameter.data.size(1) parameter.data.normal_(0, math.sqrt(2 / (fan_in + fan_out))) class SpeakNet(nn.Module): """ Module for speaking a token based on current state. In ``forward``: Return a probability distribution of utterances of tokens. """ def __init__(self, state_size, out_size): super().__init__() self.net = nn.Linear(state_size, out_size) self.softmax = nn.Softmax() xavier_init(self) def forward(self, state): out_distr = self.softmax(self.net(state)) return out_distr def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'state_size': 4, 'out_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 import math import torch.nn as nn import torch.optim 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 = 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__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 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x3, tmp8, 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__softmax_0[grid(256)](buf0, buf1, 256, XBLOCK=128, num_warps=4, num_stages=1) buf2 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 triton_poi_fused__softmax_1[grid(256)](buf1, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf1 return buf2, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), buf2 def xavier_init(module): """ Xavier initializer for module parameters. """ for parameter in module.parameters(): if len(parameter.data.shape) == 1: parameter.data.fill_(0) else: fan_in = parameter.data.size(0) fan_out = parameter.data.size(1) parameter.data.normal_(0, math.sqrt(2 / (fan_in + fan_out))) class SpeakNetNew(nn.Module): """ Module for speaking a token based on current state. In ``forward``: Return a probability distribution of utterances of tokens. """ def __init__(self, state_size, out_size): super().__init__() self.net = nn.Linear(state_size, out_size) self.softmax = nn.Softmax() xavier_init(self) def forward(self, input_0): primals_1 = self.net.weight primals_2 = self.net.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
aaronmueller/discourse-hw3
SpeakNet
false
1,350
[ "MIT" ]
0
93313a2ce83fde9480914384be52ec9160e967af
https://github.com/aaronmueller/discourse-hw3/tree/93313a2ce83fde9480914384be52ec9160e967af
StochasticPool2D
import torch import torch.nn as nn import torch.nn.functional as F from torch.nn.modules.utils import _pair class StochasticPool2D(nn.Module): """ Args: kernel_size : size of the pooling kernel stride : pool stride Note: valid padding is implemented """ def __init__(self, kernel_size=3, stride=1, training=True): super(StochasticPool2D, self).__init__() self.k = _pair(kernel_size) self.stride = _pair(stride) self.training = training def forward(self, x, training=True): x = x.unfold(2, self.k[0], self.stride[0]).unfold(3, self.k[1], self.stride[1]) x = x.contiguous().view(x.size()[:4] + (-1,)) activ = F.relu(x) prob = torch.div(activ, activ.sum(dim=-1).unsqueeze_(-1)) prob[prob != prob] = 1 idx = torch.distributions.categorical.Categorical(prob).sample() out = x.gather(-1, idx.unsqueeze(-1)) out = out.sum(dim=-1) 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.nn as nn from torch.nn.modules.utils import _pair 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_div_index_put_lift_fresh_relu_sum_0(in_ptr0, out_ptr3, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 64 rnumel = 9 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, :] rmask = rindex < rnumel r3 = rindex x0 = xindex % 2 x1 = xindex // 2 % 2 x2 = xindex // 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 4 * x1 + 4 * (r3 // 3) + 16 * x2 + r3 % 3), rmask & xmask, other=0.0) tmp1 = tl.full([1, 1], 0, tl.int32) tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp3 = tl.broadcast_to(tmp2, [XBLOCK, RBLOCK]) tmp5 = tl.where(rmask & xmask, tmp3, 0) tmp6 = tl.sum(tmp5, 1)[:, None] tmp7 = tmp2 / tmp6 tmp8 = tmp7 != tmp7 tmp9 = 1.0 tmp10 = tl.where(tmp8, tmp9, tmp7) tmp11 = tl.broadcast_to(tmp10, [XBLOCK, RBLOCK]) tmp13 = tl.where(rmask & xmask, tmp11, 0) tmp14 = tl.sum(tmp13, 1)[:, None] tmp15 = tmp10 / tmp14 tl.store(out_ptr3 + (r3 + 9 * x4), tmp15, rmask & xmask) @triton.jit def triton_poi_fused_gather_sum_1(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 x3 = xindex x0 = xindex % 2 x1 = xindex // 2 % 2 x2 = xindex // 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.full([XBLOCK], 9, tl.int32) tmp2 = tmp0 + tmp1 tmp3 = tmp0 < 0 tmp4 = tl.where(tmp3, tmp2, tmp0) tl.device_assert((0 <= tmp4) & (tmp4 < 9) | ~xmask, 'index out of bounds: 0 <= tmp4 < 9') tmp6 = tl.load(in_ptr1 + (x0 + 4 * x1 + 4 * (tmp4 // 3 % 3) + 16 * x2 + tmp4 % 3), xmask) tl.store(out_ptr0 + x3, tmp6, 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) buf3 = empty_strided_cuda((4, 4, 2, 2, 9), (144, 36, 18, 9, 1), torch.float32) get_raw_stream(0) triton_per_fused_div_index_put_lift_fresh_relu_sum_0[grid(64)](arg0_1, buf3, 64, 9, XBLOCK=1, num_warps=2, num_stages=1) buf4 = torch.ops.aten.multinomial.default(reinterpret_tensor(buf3, (64, 9), (9, 1), 0), 1, True) del buf3 buf5 = buf4 del buf4 buf6 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.float32) triton_poi_fused_gather_sum_1[grid(64)](buf5, arg0_1, buf6, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 del buf5 return buf6, class StochasticPool2DNew(nn.Module): """ Args: kernel_size : size of the pooling kernel stride : pool stride Note: valid padding is implemented """ def __init__(self, kernel_size=3, stride=1, training=True): super(StochasticPool2DNew, self).__init__() self.k = _pair(kernel_size) self.stride = _pair(stride) self.training = training def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
abhishek30-ml/Multiple-Deep-Network-Learning
StochasticPool2D
false
1,351
[ "MIT" ]
0
adf705c004cc8a1e517eeed99e7030acb476dfd9
https://github.com/abhishek30-ml/Multiple-Deep-Network-Learning/tree/adf705c004cc8a1e517eeed99e7030acb476dfd9
AvgPool2d
from torch.nn import Module import torch import torch as th class AvgPool2d(Module): """ This class is the beginning of an exact python port of the torch.nn.AvgPool2d module. Because PySyft cannot hook into layers which are implemented in C++, our special functionalities (such as encrypted computation) do not work with torch.nn.AvgPool2d and so we must have python ports available for all layer types which we seek to use. Note that this module has been tested to ensure that it outputs the exact output values that the main module outputs in the same order that the main module does. However, there is often some rounding error of unknown origin, usually less than 1e-6 in magnitude. This module has not yet been tested with GPUs but should work out of the box. """ def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False, count_include_pad=True, divisor_override=None): """For information on the constructor arguments, please see PyTorch's documentation in torch.nn.AvgPool2d""" super().__init__() assert padding == 0 assert ceil_mode is False assert count_include_pad is True assert divisor_override is None if stride is None: stride = kernel_size self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode self.count_include_pad = count_include_pad self.divisor_override = divisor_override self._one_over_kernel_size = 1 / (self.kernel_size * self.kernel_size) def forward(self, data): batch_size, out_channels, rows, cols = data.shape kernel_results = [] for i in range(0, rows - self.kernel_size + 1, self.stride): for j in range(0, cols - self.kernel_size + 1, self.stride): kernel_out = data[:, :, i:i + self.kernel_size, j:j + self. kernel_size].sum((2, 3)) * self._one_over_kernel_size kernel_results.append(kernel_out.unsqueeze(2)) pred = th.cat(kernel_results, axis=2).view(batch_size, out_channels, int(rows / self.stride), int(cols / self.stride)) return pred def get_inputs(): return [torch.rand([4, 4, 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.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_per_fused_mul_sum_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 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, 0) tmp4 = tl.sum(tmp3, 1)[:, None] tmp5 = 0.0625 tmp6 = tmp4 * tmp5 tl.debug_barrier() tl.store(in_out_ptr0 + x0, tmp6, 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, 1), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_mul_sum_0[grid(16)](buf1, arg0_1, 16, 16, XBLOCK=1, num_warps=2, num_stages=1) del arg0_1 return reinterpret_tensor(buf1, (4, 4, 1, 1), (4, 1, 1, 1), 0), class AvgPool2dNew(Module): """ This class is the beginning of an exact python port of the torch.nn.AvgPool2d module. Because PySyft cannot hook into layers which are implemented in C++, our special functionalities (such as encrypted computation) do not work with torch.nn.AvgPool2d and so we must have python ports available for all layer types which we seek to use. Note that this module has been tested to ensure that it outputs the exact output values that the main module outputs in the same order that the main module does. However, there is often some rounding error of unknown origin, usually less than 1e-6 in magnitude. This module has not yet been tested with GPUs but should work out of the box. """ def __init__(self, kernel_size, stride=None, padding=0, ceil_mode=False, count_include_pad=True, divisor_override=None): """For information on the constructor arguments, please see PyTorch's documentation in torch.nn.AvgPool2d""" super().__init__() assert padding == 0 assert ceil_mode is False assert count_include_pad is True assert divisor_override is None if stride is None: stride = kernel_size self.kernel_size = kernel_size self.stride = stride self.padding = padding self.ceil_mode = ceil_mode self.count_include_pad = count_include_pad self.divisor_override = divisor_override self._one_over_kernel_size = 1 / (self.kernel_size * self.kernel_size) def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
abogaziah/PySyft
AvgPool2d
false
1,352
[ "Apache-2.0" ]
0
812dc6f350261793c67a928786fc081158f22a76
https://github.com/abogaziah/PySyft/tree/812dc6f350261793c67a928786fc081158f22a76
ResidualBlock
import torch import torch.nn as nn class ResidualBlock(nn.Module): def __init__(self, in_channels): super(ResidualBlock, self).__init__() self.conv1 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) def forward(self, x): out = nn.ReLU()(x) out = self.conv1(out) out = nn.ReLU()(out) out = self.conv2(out) return out + x def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_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._inductor.runtime import triton_helpers 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_relu_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], 0, tl.int32) tmp2 = triton_helpers.maximum(tmp1, tmp0) tl.store(out_ptr0 + x0, tmp2, xmask) @triton.jit def triton_poi_fused_convolution_relu_1(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 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') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x3, tmp4, xmask) @triton.jit def triton_poi_fused_add_convolution_2(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 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') tmp3 = tl.load(in_ptr1 + x3, xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tl.store(in_out_ptr0 + x3, tmp4, 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, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_3, (4,), (1,)) assert_size_stride(primals_4, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_5, (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_relu_0[grid(256)](primals_1, buf0, 256, XBLOCK=256, num_warps=4, num_stages=1) buf1 = extern_kernels.convolution(buf0, primals_2, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 4, 4, 4), (64, 16, 4, 1)) buf2 = buf1 del buf1 triton_poi_fused_convolution_relu_1[grid(256)](buf2, primals_3, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 buf3 = extern_kernels.convolution(buf2, primals_4, stride=(1, 1), padding=(1, 1), 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 triton_poi_fused_add_convolution_2[grid(256)](buf4, primals_5, primals_1, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_1 del primals_5 return buf4, primals_2, primals_4, buf0, buf2 class ResidualBlockNew(nn.Module): def __init__(self, in_channels): super(ResidualBlockNew, self).__init__() self.conv1 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) def forward(self, input_0): primals_2 = self.conv1.weight primals_3 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
abhay97ps/visual-control-ppo-procgen
ResidualBlock
false
1,353
[ "MIT" ]
0
765fe1ddb289d384abddc4df8eb865379c8da76a
https://github.com/abhay97ps/visual-control-ppo-procgen/tree/765fe1ddb289d384abddc4df8eb865379c8da76a
Attention
import math import torch from torch import nn from torch.nn import functional as F import torch.utils.data def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class Attention(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal def forward(self, query, key, value, padding=None): dot_products = matmul(query, key.transpose(1, 2)) if query.dim() == 3 and self.causal: tri = key.new_ones((key.size(1), key.size(1))).triu(1) * INF dot_products.sub_(tri.unsqueeze(0)) if padding is not None: if dot_products.dim() == 3: dot_products.masked_fill_(padding.unsqueeze(1).expand_as( dot_products), -INF) else: dot_products.masked_fill_(padding, -INF) return matmul(self.dropout(F.softmax(dot_products / self.scale, dim =-1)), value) 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 [[], {'d_key': 4, 'dropout_ratio': 0.5, 'causal': 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 math from torch import nn import torch.utils.data 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, xnumel, XBLOCK: tl.constexpr): xnumel = 256 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 4 x1 = xindex // 4 % 4 x2 = xindex // 16 % 4 x3 = xindex // 64 x4 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 4 * x2 + 16 * x1 + 64 * x3), xmask) tl.store(out_ptr0 + x4, tmp0, 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) 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 = 0.5 tmp16 = tmp14 * tmp15 tmp17 = tl_math.exp(tmp16) tl.store(out_ptr0 + x2, tmp17, xmask) @triton.jit def triton_poi_fused__softmax_2(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, 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_clone_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(arg1_1, (16, 4, 4), (16, 4, 1 ), 0), reinterpret_tensor(buf0, (16, 4, 4), (16, 4, 1), 0), out =buf1) del arg1_1 buf2 = buf0 del buf0 triton_poi_fused__softmax_1[grid(256)](buf1, buf2, 256, XBLOCK=256, num_warps=4, num_stages=1) buf3 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused__softmax_2[grid(256)](buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) buf4 = reinterpret_tensor(buf2, (16, 4, 4), (16, 4, 1), 0) del buf2 extern_kernels.bmm(reinterpret_tensor(buf3, (16, 4, 4), (16, 4, 1), 0), reinterpret_tensor(arg2_1, (16, 4, 4), (16, 4, 1), 0), out=buf4 ) del arg2_1 del buf3 return reinterpret_tensor(buf4, (4, 4, 4, 4), (64, 16, 4, 1), 0), def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class AttentionNew(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal 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]
abhinavrangarajan/genienlp
Attention
false
1,354
[ "BSD-3-Clause" ]
0
ba121274b3365739ce9e5a8facc9a2904149b9c7
https://github.com/abhinavrangarajan/genienlp/tree/ba121274b3365739ce9e5a8facc9a2904149b9c7
LinearAttentionBlock
import torch import torch.nn as nn import torch.nn.functional as F class LinearAttentionBlock(nn.Module): def __init__(self, in_features): super(LinearAttentionBlock, self).__init__() self.op = nn.Conv2d(in_channels=in_features, out_channels=1, kernel_size=1, padding=0, bias=False) def forward(self, l, g): N, C, W, H = l.size() c = self.op(l + g) a = F.softmax(c.view(N, 1, -1), dim=2).view(N, 1, W, H) g = torch.mul(a.expand_as(l), l) g = g.view(N, C, -1).sum(dim=2) return c.view(N, 1, W, H), g def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_features': 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 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) @triton.jit def triton_per_fused__softmax_1(in_ptr0, out_ptr0, out_ptr1, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 4 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.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, float('-inf')) tmp4 = triton_helpers.max2(tmp3, 1)[:, None] tmp5 = tmp0 - tmp4 tmp6 = tl_math.exp(tmp5) tmp7 = tl.broadcast_to(tmp6, [XBLOCK, RBLOCK]) tmp9 = tl.where(xmask, tmp7, 0) tmp10 = tl.sum(tmp9, 1)[:, None] tl.store(out_ptr0 + x0, tmp4, xmask) tl.store(out_ptr1 + x0, tmp10, xmask) @triton.jit def triton_per_fused_sum_2(in_ptr0, in_ptr1, in_ptr2, in_ptr3, out_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) r2 = rindex x1 = xindex // 4 x3 = xindex tmp0 = tl.load(in_ptr0 + (r2 + 16 * x1), xmask, eviction_policy= 'evict_last', other=0.0) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr3 + (r2 + 16 * x3), xmask, other=0.0) tmp2 = tmp0 - tmp1 tmp3 = tl_math.exp(tmp2) tmp5 = tmp3 / tmp4 tmp7 = tmp5 * tmp6 tmp8 = tl.broadcast_to(tmp7, [XBLOCK, RBLOCK]) tmp10 = tl.where(xmask, tmp8, 0) tmp11 = tl.sum(tmp10, 1)[:, None] tl.store(out_ptr0 + x3, tmp11, 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, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (1, 4, 1, 1), (4, 1, 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_add_0[grid(256)](primals_1, primals_2, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf1 = extern_kernels.convolution(buf0, primals_3, stride=(1, 1), padding=(0, 0), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf1, (4, 1, 4, 4), (16, 16, 4, 1)) buf2 = empty_strided_cuda((4, 1, 1), (1, 1, 1), torch.float32) buf3 = empty_strided_cuda((4, 1, 1), (1, 1, 1), torch.float32) triton_per_fused__softmax_1[grid(4)](buf1, buf2, buf3, 4, 16, XBLOCK=1, num_warps=2, num_stages=1) buf4 = empty_strided_cuda((4, 4), (4, 1), torch.float32) triton_per_fused_sum_2[grid(16)](buf1, buf2, buf3, primals_1, buf4, 16, 16, XBLOCK=8, num_warps=2, num_stages=1) return buf1, buf4, primals_1, primals_3, buf0, buf1, buf2, buf3 class LinearAttentionBlockNew(nn.Module): def __init__(self, in_features): super(LinearAttentionBlockNew, self).__init__() self.op = nn.Conv2d(in_channels=in_features, out_channels=1, kernel_size=1, padding=0, bias=False) def forward(self, input_0, input_1): primals_3 = self.op.weight primals_1 = input_0 primals_2 = input_1 output = call([primals_1, primals_2, primals_3]) return output[0], output[1]
abhay97ps/visual-control-ppo-procgen
LinearAttentionBlock
false
1,355
[ "MIT" ]
0
765fe1ddb289d384abddc4df8eb865379c8da76a
https://github.com/abhay97ps/visual-control-ppo-procgen/tree/765fe1ddb289d384abddc4df8eb865379c8da76a
SirenLayer
import torch import numpy as np from torch import nn class SirenLayer(nn.Module): def __init__(self, in_f, out_f, w0=30, is_first=False, is_last=False): super().__init__() self.in_f = in_f self.w0 = w0 self.linear = nn.Linear(in_f, out_f) self.is_first = is_first self.is_last = is_last self.init_weights() def init_weights(self): b = 1 / self.in_f if self.is_first else np.sqrt(6 / self.in_f ) / self.w0 with torch.no_grad(): self.linear.weight.uniform_(-b, b) def forward(self, x, **kwargs): x = self.linear(x) return x if self.is_last else torch.sin(self.w0 * x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'in_f': 4, 'out_f': 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 math as tl_math import numpy as np 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_mul_sin_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 = 30.0 tmp2 = tmp0 * tmp1 tmp3 = tl_math.sin(tmp2) tl.store(out_ptr0 + x0, tmp3, 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_mul_sin_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 SirenLayerNew(nn.Module): def __init__(self, in_f, out_f, w0=30, is_first=False, is_last=False): super().__init__() self.in_f = in_f self.w0 = w0 self.linear = nn.Linear(in_f, out_f) self.is_first = is_first self.is_last = is_last self.init_weights() def init_weights(self): b = 1 / self.in_f if self.is_first else np.sqrt(6 / self.in_f ) / self.w0 with torch.no_grad(): self.linear.weight.uniform_(-b, b) 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]
abrilcf/pixel-nerf
SirenLayer
false
1,356
[ "BSD-2-Clause" ]
0
9a6a8ab6c39ec01d52df3bf4c03830f7162cc679
https://github.com/abrilcf/pixel-nerf/tree/9a6a8ab6c39ec01d52df3bf4c03830f7162cc679
ContextGating
import torch from torch import nn class ContextGating(nn.Module): def __init__(self, input_num): super(ContextGating, self).__init__() self.sigmoid = nn.Sigmoid() self.linear = nn.Linear(input_num, input_num) def forward(self, x): lin = self.linear(x.permute(0, 2, 3, 1)) lin = lin.permute(0, 3, 1, 2) sig = self.sigmoid(lin) res = x * sig return res def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_num': 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 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_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 x2 = xindex y0 = yindex % 16 y1 = yindex // 16 y3 = yindex tmp0 = tl.load(in_ptr0 + (y0 + 16 * x2 + 64 * y1), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x2 + 4 * y3), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_mul_sigmoid_1(in_ptr0, in_ptr1, in_ptr2, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 16 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 y3 = yindex y0 = yindex % 4 y1 = yindex // 4 tmp0 = tl.load(in_ptr0 + (x2 + 16 * y3), xmask & ymask) tmp1 = tl.load(in_ptr1 + (y0 + 4 * x2 + 64 * y1), xmask & ymask) tmp2 = tl.load(in_ptr2 + y0, ymask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = tl.sigmoid(tmp3) tmp5 = tmp0 * tmp4 tl.store(out_ptr0 + (x2 + 16 * y3), tmp5, xmask & ymask) 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, 4), (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_clone_0[grid(64, 4)](primals_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf0, (64, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf1) del primals_2 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_mul_sigmoid_1[grid(16, 16)](primals_1, buf1, primals_3, buf2, 16, 16, XBLOCK=16, YBLOCK=16, num_warps=4, num_stages=1) return buf2, primals_1, primals_3, reinterpret_tensor(buf0, (64, 4), (4, 1), 0), buf1 class ContextGatingNew(nn.Module): def __init__(self, input_num): super(ContextGatingNew, self).__init__() self.sigmoid = nn.Sigmoid() self.linear = nn.Linear(input_num, input_num) def forward(self, input_0): primals_2 = self.linear.weight primals_3 = self.linear.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
aagnone3/dc19t2
ContextGating
false
1,357
[ "Apache-2.0" ]
0
cc7baf2a8fe73d28c224f0bf68b5355efd96c24f
https://github.com/aagnone3/dc19t2/tree/cc7baf2a8fe73d28c224f0bf68b5355efd96c24f
MultiHead
import math import torch from torch import nn from torch.nn import functional as F import torch.utils.data def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class Attention(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal def forward(self, query, key, value, padding=None): dot_products = matmul(query, key.transpose(1, 2)) if query.dim() == 3 and self.causal: tri = key.new_ones((key.size(1), key.size(1))).triu(1) * INF dot_products.sub_(tri.unsqueeze(0)) if padding is not None: if dot_products.dim() == 3: dot_products.masked_fill_(padding.unsqueeze(1).expand_as( dot_products), -INF) else: dot_products.masked_fill_(padding, -INF) return matmul(self.dropout(F.softmax(dot_products / self.scale, dim =-1)), value) class Linear(nn.Linear): def forward(self, x): size = x.size() return super().forward(x.contiguous().view(-1, size[-1])).view(* size[:-1], -1) class MultiHead(nn.Module): def __init__(self, d_key, d_value, n_heads, dropout_ratio, causal=False): super().__init__() self.attention = Attention(d_key, dropout_ratio, causal=causal) self.wq = Linear(d_key, d_key, bias=False) self.wk = Linear(d_key, d_key, bias=False) self.wv = Linear(d_value, d_value, bias=False) self.n_heads = n_heads def forward(self, query, key, value, padding=None): query, key, value = self.wq(query), self.wk(key), self.wv(value) query, key, value = (x.chunk(self.n_heads, -1) for x in (query, key, value)) return torch.cat([self.attention(q, k, v, padding=padding) for q, k, v in zip(query, key, value)], -1) def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4]) ] def get_init_inputs(): return [[], {'d_key': 4, 'd_value': 4, 'n_heads': 4, 'dropout_ratio': 0.5}]
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 math from torch import nn from torch.nn import functional as F import torch.utils.data 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 = 0.5 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) @triton.jit def triton_poi_fused_cat_2(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 x0 = xindex % 4 x1 = xindex // 4 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 1, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + x1, 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 + x1, 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 + x1, tmp14 & xmask, eviction_policy= 'evict_last', other=0.0) tmp16 = tmp0 >= tmp12 tl.full([1], 4, tl.int64) tmp19 = tl.load(in_ptr3 + x1, 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 + x2, tmp22, 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), (16, 4, 1)) assert_size_stride(primals_2, (4, 4), (4, 1)) assert_size_stride(primals_3, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_4, (4, 4), (4, 1)) assert_size_stride(primals_5, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_6, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (16, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf0) del primals_2 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_5, (16, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf2) del primals_6 buf3 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 0), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 0), out=buf3) buf4 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(64)](buf3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) buf5 = buf3 del buf3 triton_poi_fused__softmax_1[grid(64)](buf4, buf5, 64, XBLOCK=64, num_warps=1, num_stages=1) buf6 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf5, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 0), out=buf6) buf7 = buf4 del buf4 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 1), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 1), out=buf7) buf8 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf7, buf8, 64, XBLOCK=64, num_warps=1, num_stages=1) buf9 = buf7 del buf7 triton_poi_fused__softmax_1[grid(64)](buf8, buf9, 64, XBLOCK=64, num_warps=1, num_stages=1) buf10 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf9, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 1), out=buf10) buf11 = buf8 del buf8 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 2), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 2), out=buf11) buf12 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf11, buf12, 64, XBLOCK=64, num_warps=1, num_stages=1) buf13 = buf11 del buf11 triton_poi_fused__softmax_1[grid(64)](buf12, buf13, 64, XBLOCK=64, num_warps=1, num_stages=1) buf14 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf13, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 2), out=buf14) buf15 = buf12 del buf12 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 3), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 3), out=buf15) buf16 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf15, buf16, 64, XBLOCK=64, num_warps=1, num_stages=1) buf17 = buf15 del buf15 triton_poi_fused__softmax_1[grid(64)](buf16, buf17, 64, XBLOCK=64, num_warps=1, num_stages=1) buf18 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf17, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 3), out=buf18) buf19 = buf16 del buf16 triton_poi_fused_cat_2[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(primals_1, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_3, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_5, (16, 4), (4, 1), 0 ), buf5, buf9, buf13, buf17, reinterpret_tensor(buf2, (4, 1, 4), ( 16, 1, 4), 3), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 3 ), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 3 ), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 2 ), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 2 ), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 2 ), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 1 ), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 1 ), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 1 ), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 0 ), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 0 ), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 0) def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class Attention(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal def forward(self, query, key, value, padding=None): dot_products = matmul(query, key.transpose(1, 2)) if query.dim() == 3 and self.causal: tri = key.new_ones((key.size(1), key.size(1))).triu(1) * INF dot_products.sub_(tri.unsqueeze(0)) if padding is not None: if dot_products.dim() == 3: dot_products.masked_fill_(padding.unsqueeze(1).expand_as( dot_products), -INF) else: dot_products.masked_fill_(padding, -INF) return matmul(self.dropout(F.softmax(dot_products / self.scale, dim =-1)), value) class Linear(nn.Linear): def forward(self, x): size = x.size() return super().forward(x.contiguous().view(-1, size[-1])).view(* size[:-1], -1) class MultiHeadNew(nn.Module): def __init__(self, d_key, d_value, n_heads, dropout_ratio, causal=False): super().__init__() self.attention = Attention(d_key, dropout_ratio, causal=causal) self.wq = Linear(d_key, d_key, bias=False) self.wk = Linear(d_key, d_key, bias=False) self.wv = Linear(d_value, d_value, bias=False) self.n_heads = n_heads def forward(self, input_0, input_1, input_2): primals_2 = self.wq.weight primals_4 = self.wk.weight primals_6 = self.wv.weight primals_1 = input_0 primals_3 = input_1 primals_5 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6]) return output[0]
abhinavrangarajan/genienlp
MultiHead
false
1,358
[ "BSD-3-Clause" ]
0
ba121274b3365739ce9e5a8facc9a2904149b9c7
https://github.com/abhinavrangarajan/genienlp/tree/ba121274b3365739ce9e5a8facc9a2904149b9c7
Net1
import torch import torch.nn as nn import torch.nn.functional as F import torch.utils.data import torch.utils.data.distributed class Net1(nn.Module): def __init__(self): super(Net1, self).__init__() self.conv1 = nn.Conv2d(1, 32, 3, 1) self.conv2 = nn.Conv2d(32, 64, 3, 1) def forward(self, x): x = self.conv1(x) x = F.relu(x) x = self.conv2(x) x = F.relu(x) x = F.max_pool2d(x, 2) x = torch.flatten(x, 1) return x 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 from torch._inductor.runtime import triton_helpers import torch.nn as nn import torch.utils.data import torch.utils.data.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_convolution_relu_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 492032 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 3844 % 32 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, 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 + x3, tmp4, xmask) @triton.jit def triton_poi_fused_convolution_relu_1(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 // 3600 % 64 x0 = xindex % 3600 x4 = xindex // 3600 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(out_ptr0 + (x0 + 3616 * x4), tmp4, None) @triton.jit def triton_poi_fused_max_pool2d_with_indices_2(in_ptr0, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 230400 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x0 = xindex % 30 x1 = xindex // 30 % 30 x2 = xindex // 900 x3 = xindex tmp0 = tl.load(in_ptr0 + (2 * x0 + 120 * x1 + 3616 * x2), xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (1 + 2 * x0 + 120 * x1 + 3616 * x2), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr0 + (60 + 2 * x0 + 120 * x1 + 3616 * x2), xmask, eviction_policy='evict_last') tmp12 = tl.load(in_ptr0 + (61 + 2 * x0 + 120 * x1 + 3616 * x2), xmask, eviction_policy='evict_last') tmp2 = tmp1 > tmp0 tmp3 = tl.full([1], 1, tl.int8) tmp4 = tl.full([1], 0, tl.int8) tmp5 = tl.where(tmp2, tmp3, tmp4) tmp6 = triton_helpers.maximum(tmp1, tmp0) tmp8 = tmp7 > tmp6 tmp9 = tl.full([1], 2, tl.int8) tmp10 = tl.where(tmp8, tmp9, tmp5) tmp11 = triton_helpers.maximum(tmp7, tmp6) tmp13 = tmp12 > tmp11 tmp14 = tl.full([1], 3, tl.int8) tmp15 = tl.where(tmp13, tmp14, tmp10) tmp16 = triton_helpers.maximum(tmp12, tmp11) tl.store(out_ptr0 + x3, tmp15, xmask) tl.store(out_ptr1 + x3, tmp16, xmask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (32, 1, 3, 3), (9, 9, 3, 1)) assert_size_stride(primals_2, (32,), (1,)) assert_size_stride(primals_3, (4, 1, 64, 64), (4096, 4096, 64, 1)) assert_size_stride(primals_4, (64, 32, 3, 3), (288, 9, 3, 1)) assert_size_stride(primals_5, (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, 32, 62, 62), (123008, 3844, 62, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(492032)](buf1, primals_2, 492032, XBLOCK=512, num_warps=8, num_stages=1) del primals_2 buf2 = extern_kernels.convolution(buf1, primals_4, 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, 60, 60), (230400, 3600, 60, 1)) buf3 = empty_strided_cuda((4, 64, 60, 60), (231424, 3616, 60, 1), torch.float32) triton_poi_fused_convolution_relu_1[grid(921600)](buf2, primals_5, buf3, 921600, XBLOCK=1024, num_warps=4, num_stages=1) del buf2 del primals_5 buf4 = empty_strided_cuda((4, 64, 30, 30), (57600, 900, 30, 1), torch.int8) buf5 = empty_strided_cuda((4, 64, 30, 30), (57600, 900, 30, 1), torch.float32) triton_poi_fused_max_pool2d_with_indices_2[grid(230400)](buf3, buf4, buf5, 230400, XBLOCK=512, num_warps=8, num_stages=1) return reinterpret_tensor(buf5, (4, 57600), (57600, 1), 0 ), primals_1, primals_3, primals_4, buf1, buf3, buf4 class Net1New(nn.Module): def __init__(self): super(Net1New, self).__init__() self.conv1 = nn.Conv2d(1, 32, 3, 1) self.conv2 = nn.Conv2d(32, 64, 3, 1) 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_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
abhinavs95/deep-learning-containers
Net1
false
1,359
[ "Apache-2.0" ]
0
bd1cb70a8cd1cbb5d39bc825fc7ab9f53ebf9f89
https://github.com/abhinavs95/deep-learning-containers/tree/bd1cb70a8cd1cbb5d39bc825fc7ab9f53ebf9f89
WeightedL2
import torch import torch.nn as nn class WeightedL2(nn.Module): def __init__(self): super(WeightedL2, self).__init__() def forward(self, x, target, w): return torch.sum(w * (x - target) ** 2) 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 [[], {}]
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.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_mul_pow_sub_sum_0(in_ptr0, in_ptr1, in_ptr2, out_ptr0, 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 = tl.load(in_ptr2 + r0, None) tmp3 = tmp1 - tmp2 tmp4 = tmp3 * tmp3 tmp5 = tmp0 * tmp4 tmp6 = tl.broadcast_to(tmp5, [RBLOCK]) tmp8 = triton_helpers.promote_to_tensor(tl.sum(tmp6, 0)) tl.store(out_ptr0 + tl.full([1], 0, tl.int32), tmp8, None) 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((), (), torch.float32) get_raw_stream(0) triton_per_fused_mul_pow_sub_sum_0[grid(1)](arg2_1, arg0_1, arg1_1, buf0, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 return buf0, class WeightedL2New(nn.Module): def __init__(self): super(WeightedL2New, self).__init__() 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]
acrosson/dl
WeightedL2
false
1,360
[ "MIT" ]
0
94e68533b38f53f09e9bef460ba96fa389fc8eb4
https://github.com/acrosson/dl/tree/94e68533b38f53f09e9bef460ba96fa389fc8eb4
CustomGruCell
import torch import numpy as np import torch.nn as nn class CustomGruCell(nn.Module): """ A forward only GRU cell. Input should be: (sequence length x batch size x input_size). The output is the output of the final forward call. It's not clear if it would be possible to use the output from each cell in a Plan because of the assumptions of 2D tensors in backprop. """ def __init__(self, input_size, hidden_size, bias=True): super(CustomGruCell, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.fc_ir = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hr = nn.Linear(hidden_size, hidden_size, bias=bias) self.fc_iz = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hz = nn.Linear(hidden_size, hidden_size, bias=bias) self.fc_in = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hn = nn.Linear(hidden_size, hidden_size, bias=bias) self.init_parameters() def init_parameters(self): std = 1.0 / np.sqrt(self.hidden_size) for w in self.parameters(): w.data.uniform_(-std, std) def forward(self, x, h): i_r = self.fc_ir(x) h_r = self.fc_hr(h) i_z = self.fc_iz(x) h_z = self.fc_hz(h) i_n = self.fc_in(x) h_n = self.fc_hn(h) resetgate = (i_r + h_r).sigmoid() inputgate = (i_z + h_z).sigmoid() newgate = (i_n + resetgate * h_n).tanh() hy = newgate + inputgate * (h - newgate) return hy def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, '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 numpy as np 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_add_mul_sigmoid_sub_tanh_0(in_out_ptr0, in_out_ptr1, in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, in_ptr6, in_ptr7, in_ptr8, 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') tmp3 = tl.load(in_ptr1 + x2, xmask) tmp4 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp8 = tl.load(in_out_ptr1 + x2, xmask) tmp9 = tl.load(in_ptr3 + x0, xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr4 + x2, xmask) tmp12 = tl.load(in_ptr5 + x0, xmask, eviction_policy='evict_last') tmp16 = tl.load(in_ptr6 + x2, xmask) tmp17 = tl.load(in_ptr7 + x2, xmask) tmp21 = tl.load(in_ptr8 + x2, xmask) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp6 = tmp2 + tmp5 tmp7 = tl.sigmoid(tmp6) tmp10 = tmp8 + tmp9 tmp13 = tmp11 + tmp12 tmp14 = tmp10 + tmp13 tmp15 = tl.sigmoid(tmp14) tmp18 = tmp7 * tmp17 tmp19 = tmp16 + tmp18 tmp20 = libdevice.tanh(tmp19) tmp22 = tmp21 - tmp20 tmp23 = tmp15 * tmp22 tmp24 = tmp20 + tmp23 tl.store(in_out_ptr0 + x2, tmp7, xmask) tl.store(in_out_ptr1 + x2, tmp15, xmask) tl.store(out_ptr0 + x2, tmp24, 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) = 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, 4), (64, 16, 4, 1)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) assert_size_stride(primals_9, (4, 4), (4, 1)) assert_size_stride(primals_10, (4,), (1,)) assert_size_stride(primals_11, (4, 4), (4, 1)) assert_size_stride(primals_12, (4,), (1,)) assert_size_stride(primals_13, (4, 4), (4, 1)) assert_size_stride(primals_14, (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 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_6, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), out=buf2) del primals_7 buf3 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_6, (64, 4), (4, 1), 0), reinterpret_tensor(primals_9, (4, 4), (1, 4), 0), out=buf3) del primals_9 buf4 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_12, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_11, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf4) del primals_11 del primals_12 buf5 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_14, reinterpret_tensor(primals_6, (64, 4), (4, 1), 0), reinterpret_tensor(primals_13, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf5) del primals_13 del primals_14 buf6 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 buf7 = reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf2 buf8 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_mul_sigmoid_sub_tanh_0[grid(256)](buf6, buf7, primals_2, buf1, primals_5, primals_8, buf3, primals_10, buf4, buf5, primals_6, buf8, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf1 del buf3 del primals_10 del primals_2 del primals_5 del primals_8 return buf8, primals_6, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), buf4, buf5, buf6, buf7 class CustomGruCellNew(nn.Module): """ A forward only GRU cell. Input should be: (sequence length x batch size x input_size). The output is the output of the final forward call. It's not clear if it would be possible to use the output from each cell in a Plan because of the assumptions of 2D tensors in backprop. """ def __init__(self, input_size, hidden_size, bias=True): super(CustomGruCellNew, self).__init__() self.input_size = input_size self.hidden_size = hidden_size self.fc_ir = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hr = nn.Linear(hidden_size, hidden_size, bias=bias) self.fc_iz = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hz = nn.Linear(hidden_size, hidden_size, bias=bias) self.fc_in = nn.Linear(input_size, hidden_size, bias=bias) self.fc_hn = nn.Linear(hidden_size, hidden_size, bias=bias) self.init_parameters() def init_parameters(self): std = 1.0 / np.sqrt(self.hidden_size) for w in self.parameters(): w.data.uniform_(-std, std) def forward(self, input_0, input_1): primals_1 = self.fc_ir.weight primals_2 = self.fc_ir.bias primals_4 = self.fc_hr.weight primals_5 = self.fc_hr.bias primals_7 = self.fc_iz.weight primals_8 = self.fc_iz.bias primals_9 = self.fc_hz.weight primals_10 = self.fc_hz.bias primals_11 = self.fc_in.weight primals_12 = self.fc_in.bias primals_13 = self.fc_hn.weight primals_14 = self.fc_hn.bias primals_3 = input_0 primals_6 = 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, primals_13, primals_14]) return output[0]
abogaziah/PySyft
CustomGruCell
false
1,361
[ "Apache-2.0" ]
0
812dc6f350261793c67a928786fc081158f22a76
https://github.com/abogaziah/PySyft/tree/812dc6f350261793c67a928786fc081158f22a76
ImpalaBlock
import torch import torch.nn as nn class ResidualBlock(nn.Module): def __init__(self, in_channels): super(ResidualBlock, self).__init__() self.conv1 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) def forward(self, x): out = nn.ReLU()(x) out = self.conv1(out) out = nn.ReLU()(out) out = self.conv2(out) return out + x class ImpalaBlock(nn.Module): def __init__(self, in_channels, out_channels): super(ImpalaBlock, self).__init__() self.conv = nn.Conv2d(in_channels=in_channels, out_channels= out_channels, kernel_size=3, stride=1, padding=1) self.res1 = ResidualBlock(out_channels) self.res2 = ResidualBlock(out_channels) def forward(self, x): x = self.conv(x) x = nn.MaxPool2d(kernel_size=3, stride=2, padding=1)(x) x = self.res1(x) x = self.res2(x) return x 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._inductor.runtime import triton_helpers 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_convolution_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 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') tmp2 = tmp0 + tmp1 tl.store(in_out_ptr0 + x3, tmp2, xmask) @triton.jit def triton_poi_fused_max_pool2d_with_indices_relu_1(in_ptr0, out_ptr0, out_ptr1, out_ptr2, xnumel, XBLOCK: tl.constexpr): xnumel = 64 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 2 % 2 x0 = xindex % 2 x4 = xindex // 2 x3 = xindex tmp0 = -1 + 2 * x1 tmp1 = tl.full([1], 0, tl.int64) tmp2 = tmp0 >= tmp1 tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tmp2 & tmp4 tmp6 = -1 + 2 * x0 tmp7 = tmp6 >= tmp1 tmp8 = tmp6 < tmp3 tmp9 = tmp7 & tmp8 tmp10 = tmp5 & tmp9 tmp11 = tl.load(in_ptr0 + (-5 + 2 * x0 + 8 * x4), tmp10 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp12 = 2 * x0 tmp13 = tmp12 >= tmp1 tmp14 = tmp12 < tmp3 tmp15 = tmp13 & tmp14 tmp16 = tmp5 & tmp15 tmp17 = tl.load(in_ptr0 + (-4 + 2 * x0 + 8 * x4), tmp16 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp18 = triton_helpers.maximum(tmp17, tmp11) tmp19 = 1 + 2 * x0 tmp20 = tmp19 >= tmp1 tmp21 = tmp19 < tmp3 tmp22 = tmp20 & tmp21 tmp23 = tmp5 & tmp22 tmp24 = tl.load(in_ptr0 + (-3 + 2 * x0 + 8 * x4), tmp23 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp25 = triton_helpers.maximum(tmp24, tmp18) tmp26 = 2 * x1 tmp27 = tmp26 >= tmp1 tmp28 = tmp26 < tmp3 tmp29 = tmp27 & tmp28 tmp30 = tmp29 & tmp9 tmp31 = tl.load(in_ptr0 + (-1 + 2 * x0 + 8 * x4), tmp30 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp32 = triton_helpers.maximum(tmp31, tmp25) tmp33 = tmp29 & tmp15 tmp34 = tl.load(in_ptr0 + (2 * x0 + 8 * x4), tmp33 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp35 = triton_helpers.maximum(tmp34, tmp32) tmp36 = tmp29 & tmp22 tmp37 = tl.load(in_ptr0 + (1 + 2 * x0 + 8 * x4), tmp36 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp38 = triton_helpers.maximum(tmp37, tmp35) tmp39 = 1 + 2 * x1 tmp40 = tmp39 >= tmp1 tmp41 = tmp39 < tmp3 tmp42 = tmp40 & tmp41 tmp43 = tmp42 & tmp9 tmp44 = tl.load(in_ptr0 + (3 + 2 * x0 + 8 * x4), tmp43 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp45 = triton_helpers.maximum(tmp44, tmp38) tmp46 = tmp42 & tmp15 tmp47 = tl.load(in_ptr0 + (4 + 2 * x0 + 8 * x4), tmp46 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp48 = triton_helpers.maximum(tmp47, tmp45) tmp49 = tmp42 & tmp22 tmp50 = tl.load(in_ptr0 + (5 + 2 * x0 + 8 * x4), tmp49 & xmask, eviction_policy='evict_last', other=float('-inf')) tmp51 = triton_helpers.maximum(tmp50, tmp48) tmp52 = tmp17 > tmp11 tmp53 = tl.full([1], 1, tl.int8) tmp54 = tl.full([1], 0, tl.int8) tmp55 = tl.where(tmp52, tmp53, tmp54) tmp56 = tmp24 > tmp18 tmp57 = tl.full([1], 2, tl.int8) tmp58 = tl.where(tmp56, tmp57, tmp55) tmp59 = tmp31 > tmp25 tmp60 = tl.full([1], 3, tl.int8) tmp61 = tl.where(tmp59, tmp60, tmp58) tmp62 = tmp34 > tmp32 tmp63 = tl.full([1], 4, tl.int8) tmp64 = tl.where(tmp62, tmp63, tmp61) tmp65 = tmp37 > tmp35 tmp66 = tl.full([1], 5, tl.int8) tmp67 = tl.where(tmp65, tmp66, tmp64) tmp68 = tmp44 > tmp38 tmp69 = tl.full([1], 6, tl.int8) tmp70 = tl.where(tmp68, tmp69, tmp67) tmp71 = tmp47 > tmp45 tmp72 = tl.full([1], 7, tl.int8) tmp73 = tl.where(tmp71, tmp72, tmp70) tmp74 = tmp50 > tmp48 tmp75 = tl.full([1], 8, tl.int8) tmp76 = tl.where(tmp74, tmp75, tmp73) tmp77 = tl.full([1], 0, tl.int32) tmp78 = triton_helpers.maximum(tmp77, tmp51) tl.store(out_ptr0 + x3, tmp51, xmask) tl.store(out_ptr1 + x3, tmp76, xmask) tl.store(out_ptr2 + x3, tmp78, xmask) @triton.jit def triton_poi_fused_convolution_relu_2(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 tmp3 = tl.full([1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(in_out_ptr0 + x3, tmp4, xmask) @triton.jit def triton_poi_fused_add_convolution_relu_3(in_ptr0, in_ptr1, in_ptr2, out_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_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + x3, xmask) tmp2 = tmp0 + tmp1 tmp4 = tmp2 + tmp3 tmp5 = tl.full([1], 0, tl.int32) tmp6 = triton_helpers.maximum(tmp5, tmp4) tl.store(out_ptr0 + x3, tmp6, xmask) @triton.jit def triton_poi_fused_add_convolution_4(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, in_ptr3, 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') tmp3 = tl.load(in_ptr1 + x3, xmask) tmp4 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr3 + x3, xmask) tmp2 = tmp0 + tmp1 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp2 + tmp7 tl.store(in_out_ptr0 + x3, tmp8, 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) = args args.clear() assert_size_stride(primals_1, (4, 4, 3, 3), (36, 9, 3, 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, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_7, (4,), (1,)) assert_size_stride(primals_8, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_9, (4,), (1,)) assert_size_stride(primals_10, (4, 4, 3, 3), (36, 9, 3, 1)) assert_size_stride(primals_11, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1, 1), padding=(1, 1), 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 get_raw_stream(0) triton_poi_fused_convolution_0[grid(256)](buf1, primals_2, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.float32) buf3 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.int8) buf4 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.float32) triton_poi_fused_max_pool2d_with_indices_relu_1[grid(64)](buf1, buf2, buf3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) buf5 = extern_kernels.convolution(buf4, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf5, (4, 4, 2, 2), (16, 4, 2, 1)) buf6 = buf5 del buf5 triton_poi_fused_convolution_relu_2[grid(64)](buf6, primals_5, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_5 buf7 = extern_kernels.convolution(buf6, primals_6, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf7, (4, 4, 2, 2), (16, 4, 2, 1)) buf8 = empty_strided_cuda((4, 4, 2, 2), (16, 4, 2, 1), torch.float32) triton_poi_fused_add_convolution_relu_3[grid(64)](buf7, primals_7, buf2, buf8, 64, XBLOCK=64, num_warps=1, num_stages=1) buf9 = extern_kernels.convolution(buf8, primals_8, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf9, (4, 4, 2, 2), (16, 4, 2, 1)) buf10 = buf9 del buf9 triton_poi_fused_convolution_relu_2[grid(64)](buf10, primals_9, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_9 buf11 = extern_kernels.convolution(buf10, primals_10, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf11, (4, 4, 2, 2), (16, 4, 2, 1)) buf12 = buf11 del buf11 triton_poi_fused_add_convolution_4[grid(64)](buf12, primals_11, buf7, primals_7, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf2 del buf7 del primals_11 del primals_7 return (buf12, primals_1, primals_3, primals_4, primals_6, primals_8, primals_10, buf1, buf3, buf4, buf6, buf8, buf10) class ResidualBlock(nn.Module): def __init__(self, in_channels): super(ResidualBlock, self).__init__() self.conv1 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) self.conv2 = nn.Conv2d(in_channels=in_channels, out_channels= in_channels, kernel_size=3, stride=1, padding=1) def forward(self, x): out = nn.ReLU()(x) out = self.conv1(out) out = nn.ReLU()(out) out = self.conv2(out) return out + x class ImpalaBlockNew(nn.Module): def __init__(self, in_channels, out_channels): super(ImpalaBlockNew, self).__init__() self.conv = nn.Conv2d(in_channels=in_channels, out_channels= out_channels, kernel_size=3, stride=1, padding=1) self.res1 = ResidualBlock(out_channels) self.res2 = ResidualBlock(out_channels) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_4 = self.res1.conv1.weight primals_5 = self.res1.conv1.bias primals_6 = self.res1.conv2.weight primals_7 = self.res1.conv2.bias primals_8 = self.res2.conv1.weight primals_9 = self.res2.conv1.bias primals_10 = self.res2.conv2.weight primals_11 = self.res2.conv2.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]) return output[0]
abhay97ps/visual-control-ppo-procgen
ImpalaBlock
false
1,362
[ "MIT" ]
0
765fe1ddb289d384abddc4df8eb865379c8da76a
https://github.com/abhay97ps/visual-control-ppo-procgen/tree/765fe1ddb289d384abddc4df8eb865379c8da76a
MultiHeadAttention
import math import torch import torch.utils.checkpoint from torch import nn import torch.nn.functional as F class ScaledDotProductAttention(nn.Module): def forward(self, query, key, value, mask=None): dk = query.size()[-1] scores = query.matmul(key.transpose(-2, -1)) / math.sqrt(dk) if mask is not None: scores = scores.masked_fill(mask == 0, -1000000000.0) attention = F.softmax(scores, dim=-1) return attention.matmul(value) class MultiHeadAttention(nn.Module): def __init__(self, in_features, head_num, bias=True, activation=F.relu): """Multi-head attention. :param in_features: Size of each input sample. :param head_num: Number of heads. :param bias: Whether to use the bias term. :param activation: The activation after each linear transformation. """ super(MultiHeadAttention, self).__init__() if in_features % head_num != 0: raise ValueError( '`in_features`({}) should be divisible by `head_num`({})'. format(in_features, head_num)) self.in_features = in_features self.head_num = head_num self.activation = activation self.bias = bias self.linear_q = nn.Linear(in_features, in_features, bias) self.linear_k = nn.Linear(in_features, in_features, bias) self.linear_v = nn.Linear(in_features, in_features, bias) self.linear_o = nn.Linear(in_features, in_features, bias) def forward(self, q, k, v, mask=None): q, k, v = self.linear_q(q), self.linear_k(k), self.linear_v(v) if self.activation is not None: q = self.activation(q) k = self.activation(k) v = self.activation(v) q = self._reshape_to_batches(q) k = self._reshape_to_batches(k) v = self._reshape_to_batches(v) if mask is not None: mask = mask.repeat(self.head_num, 1, 1) y = ScaledDotProductAttention()(q, k, v, mask) y = self._reshape_from_batches(y) y = self.linear_o(y) if self.activation is not None: y = self.activation(y) return y @staticmethod def gen_history_mask(x): """Generate the mask that only uses history data. :param x: Input tensor. :return: The mask. """ batch_size, seq_len, _ = x.size() return torch.tril(torch.ones(seq_len, seq_len)).view(1, seq_len, seq_len).repeat(batch_size, 1, 1) def _reshape_to_batches(self, x): batch_size, seq_len, in_feature = x.size() sub_dim = in_feature // self.head_num return x.reshape(batch_size, seq_len, self.head_num, sub_dim).permute( 0, 2, 1, 3).reshape(batch_size * self.head_num, seq_len, sub_dim) def _reshape_from_batches(self, x): batch_size, seq_len, in_feature = x.size() batch_size //= self.head_num out_dim = in_feature * self.head_num return x.reshape(batch_size, self.head_num, seq_len, in_feature ).permute(0, 2, 1, 3).reshape(batch_size, seq_len, out_dim) def extra_repr(self): return 'in_features={}, head_num={}, bias={}, activation={}'.format( self.in_features, self.head_num, self.bias, self.activation) def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4]), torch.rand([4, 4, 4]) ] def get_init_inputs(): return [[], {'in_features': 4, 'head_num': 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 math import torch.utils.checkpoint from torch import 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_clone_0(in_ptr0, in_ptr1, 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') tmp1 = tl.load(in_ptr1 + y0, ymask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = tl.full([1, 1], 0, tl.int32) tmp4 = triton_helpers.maximum(tmp3, tmp2) tl.store(out_ptr0 + (x2 + 4 * y3), tmp4, xmask & ymask) @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) 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 = tmp14 * tmp1 tmp16 = tl_math.exp(tmp15) tl.store(out_ptr0 + x2, tmp16, xmask) @triton.jit def triton_poi_fused__softmax_2(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) @triton.jit def triton_poi_fused_clone_3(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_relu_threshold_backward_4(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) @triton.jit def triton_poi_fused_relu_threshold_backward_5(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 x2 = xindex x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + 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(out_ptr0 + x2, tmp6, 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) = 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), (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), (16, 4, 1)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) assert_size_stride(primals_9, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_10, (4, 4), (4, 1)) assert_size_stride(primals_11, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_3, (16, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_6, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf1) del primals_4 buf2 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_9, (16, 4), (4, 1), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), out=buf2) del primals_7 buf3 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(16, 4)](buf0, primals_2, buf3, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf4 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 1), torch.float32) triton_poi_fused_clone_0[grid(16, 4)](buf1, primals_5, buf4, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf5 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf3, (16, 4, 1), (4, 1, 0), 0), reinterpret_tensor(buf4, (16, 1, 4), (4, 0, 1), 0), out=buf5) buf6 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf5, buf6, 256, XBLOCK=256, num_warps=4, num_stages=1) buf7 = buf5 del buf5 triton_poi_fused__softmax_2[grid(256)](buf6, buf7, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf6 buf8 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 1), torch.float32) triton_poi_fused_clone_0[grid(16, 4)](buf2, primals_8, buf8, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf9 = empty_strided_cuda((16, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf7, reinterpret_tensor(buf8, (16, 4, 1), (4, 1, 0), 0), out=buf9) buf10 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_clone_3[grid(16, 4)](buf9, buf10, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) buf11 = reinterpret_tensor(buf9, (16, 4), (4, 1), 0) del buf9 extern_kernels.mm(reinterpret_tensor(buf10, (16, 4), (4, 1), 0), reinterpret_tensor(primals_10, (4, 4), (1, 4), 0), out=buf11) buf12 = reinterpret_tensor(buf11, (4, 4, 4), (16, 4, 1), 0) del buf11 buf13 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.bool) triton_poi_fused_add_relu_threshold_backward_4[grid(64)](buf12, primals_11, buf13, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_11 buf14 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_5[grid(64)](buf2, primals_8, buf14, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf2 del primals_8 buf15 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_5[grid(64)](buf1, primals_5, buf15, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf1 del primals_5 buf16 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_5[grid(64)](buf0, primals_2, buf16, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf0 del primals_2 return buf12, reinterpret_tensor(primals_3, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_6, (16, 4), (4, 1), 0 ), reinterpret_tensor(primals_9, (16, 4), (4, 1), 0 ), buf7, reinterpret_tensor(buf10, (16, 4), (4, 1), 0 ), buf13, primals_10, reinterpret_tensor(buf8, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf3, (16, 1, 4), (4, 1, 1), 0 ), reinterpret_tensor(buf4, (16, 4, 1), (4, 1, 1), 0 ), buf14, buf15, buf16 class ScaledDotProductAttention(nn.Module): def forward(self, query, key, value, mask=None): dk = query.size()[-1] scores = query.matmul(key.transpose(-2, -1)) / math.sqrt(dk) if mask is not None: scores = scores.masked_fill(mask == 0, -1000000000.0) attention = F.softmax(scores, dim=-1) return attention.matmul(value) class MultiHeadAttentionNew(nn.Module): def __init__(self, in_features, head_num, bias=True, activation=F.relu): """Multi-head attention. :param in_features: Size of each input sample. :param head_num: Number of heads. :param bias: Whether to use the bias term. :param activation: The activation after each linear transformation. """ super(MultiHeadAttentionNew, self).__init__() if in_features % head_num != 0: raise ValueError( '`in_features`({}) should be divisible by `head_num`({})'. format(in_features, head_num)) self.in_features = in_features self.head_num = head_num self.activation = activation self.bias = bias self.linear_q = nn.Linear(in_features, in_features, bias) self.linear_k = nn.Linear(in_features, in_features, bias) self.linear_v = nn.Linear(in_features, in_features, bias) self.linear_o = nn.Linear(in_features, in_features, bias) @staticmethod def gen_history_mask(x): """Generate the mask that only uses history data. :param x: Input tensor. :return: The mask. """ batch_size, seq_len, _ = x.size() return torch.tril(torch.ones(seq_len, seq_len)).view(1, seq_len, seq_len).repeat(batch_size, 1, 1) def _reshape_to_batches(self, x): batch_size, seq_len, in_feature = x.size() sub_dim = in_feature // self.head_num return x.reshape(batch_size, seq_len, self.head_num, sub_dim).permute( 0, 2, 1, 3).reshape(batch_size * self.head_num, seq_len, sub_dim) def _reshape_from_batches(self, x): batch_size, seq_len, in_feature = x.size() batch_size //= self.head_num out_dim = in_feature * self.head_num return x.reshape(batch_size, self.head_num, seq_len, in_feature ).permute(0, 2, 1, 3).reshape(batch_size, seq_len, out_dim) def extra_repr(self): return 'in_features={}, head_num={}, bias={}, activation={}'.format( self.in_features, self.head_num, self.bias, self.activation) def forward(self, input_0, input_1, input_2): primals_1 = self.linear_q.weight primals_2 = self.linear_q.bias primals_4 = self.linear_k.weight primals_5 = self.linear_k.bias primals_7 = self.linear_v.weight primals_8 = self.linear_v.bias primals_10 = self.linear_o.weight primals_11 = self.linear_o.bias primals_3 = input_0 primals_6 = input_1 primals_9 = input_2 output = call([primals_1, primals_2, primals_3, primals_4, primals_5, primals_6, primals_7, primals_8, primals_9, primals_10, primals_11]) return output[0]
abedi1/ECLARe
MultiHeadAttention
false
1,363
[ "Apache-2.0" ]
0
a446b8086404b058923a9b3ce47e75cc40436a58
https://github.com/abedi1/ECLARe/tree/a446b8086404b058923a9b3ce47e75cc40436a58
BertSelfOutput
from _paritybench_helpers import _mock_config import torch from torch import nn import torch.onnx class BertLayerNorm(nn.Module): def __init__(self, hidden_size, eps=1e-12): """Construct a layernorm module in the TF style (epsilon inside the square root). """ super(BertLayerNorm, self).__init__() self.weight = nn.Parameter(torch.ones(hidden_size)) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.variance_epsilon = eps def forward(self, x): u = x.mean(-1, keepdim=True) s = (x - u).pow(2).mean(-1, keepdim=True) x = (x - u) / torch.sqrt(s + self.variance_epsilon) return self.weight * x + self.bias class BertSelfOutput(nn.Module): def __init__(self, config): super(BertSelfOutput, self).__init__() self.dense = nn.Linear(config.hidden_size, config.hidden_size, bias =False) self.LayerNorm = BertLayerNorm(config.hidden_size, eps=config. layer_norm_eps) self.dropout = nn.Dropout(config.hidden_dropout_prob) def forward(self, hidden_states, input_tensor): hidden_states = self.dense(hidden_states) hidden_states = self.dropout(hidden_states) hidden_states = hidden_states + input_tensor hidden_states = self.LayerNorm(hidden_states) return hidden_states def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'config': _mock_config(hidden_size=4, layer_norm_eps=1, hidden_dropout_prob=0.5)}]
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 from torch import nn import torch.onnx 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_mean_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 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 tl.store(out_ptr0 + x0, tmp16, xmask) @triton.jit def triton_poi_fused_add_mean_sub_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 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') tmp2 = tmp0 + tmp1 tmp4 = tmp2 - tmp3 tl.store(in_out_ptr0 + x2, tmp4, xmask) @triton.jit def triton_poi_fused_add_div_mean_mul_pow_sqrt_2(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 x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask) tmp2 = tl.load(in_ptr1 + 4 * x1, xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr1 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr1 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp10 = tl.load(in_ptr1 + (3 + 4 * x1), xmask, eviction_policy='evict_last' ) tmp20 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp3 = tmp2 * tmp2 tmp5 = tmp4 * tmp4 tmp6 = tmp3 + tmp5 tmp8 = tmp7 * tmp7 tmp9 = tmp6 + tmp8 tmp11 = tmp10 * tmp10 tmp12 = tmp9 + tmp11 tmp13 = 4.0 tmp14 = tmp12 / tmp13 tmp15 = 1.0 tmp16 = tmp14 + tmp15 tmp17 = libdevice.sqrt(tmp16) tmp18 = tmp1 / tmp17 tmp19 = tmp0 * tmp18 tmp21 = tmp19 + tmp20 tl.store(out_ptr0 + x2, tmp21, 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, 1)) assert_size_stride(primals_2, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_3, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_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_2, (64, 4), (4, 1), 0), reinterpret_tensor(primals_1, (4, 4), (1, 4), 0), out=buf0) del primals_1 buf1 = empty_strided_cuda((4, 4, 4, 1), (16, 4, 1, 64), torch.float32) get_raw_stream(0) triton_poi_fused_add_mean_0[grid(64)](buf0, primals_3, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = reinterpret_tensor(buf0, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf0 triton_poi_fused_add_mean_sub_1[grid(256)](buf2, primals_3, buf1, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf1 del primals_3 buf3 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_add_div_mean_mul_pow_sqrt_2[grid(256)](primals_4, buf2, primals_5, buf3, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_5 return buf3, primals_4, reinterpret_tensor(primals_2, (64, 4), (4, 1), 0 ), buf2 class BertLayerNorm(nn.Module): def __init__(self, hidden_size, eps=1e-12): """Construct a layernorm module in the TF style (epsilon inside the square root). """ super(BertLayerNorm, self).__init__() self.weight = nn.Parameter(torch.ones(hidden_size)) self.bias = nn.Parameter(torch.zeros(hidden_size)) self.variance_epsilon = eps def forward(self, x): u = x.mean(-1, keepdim=True) s = (x - u).pow(2).mean(-1, keepdim=True) x = (x - u) / torch.sqrt(s + self.variance_epsilon) return self.weight * x + self.bias class BertSelfOutputNew(nn.Module): def __init__(self, config): super(BertSelfOutputNew, self).__init__() self.dense = nn.Linear(config.hidden_size, config.hidden_size, bias =False) self.LayerNorm = BertLayerNorm(config.hidden_size, eps=config. layer_norm_eps) self.dropout = nn.Dropout(config.hidden_dropout_prob) def forward(self, input_0, input_1): primals_1 = self.dense.weight primals_4 = self.LayerNorm.weight primals_5 = self.LayerNorm.bias primals_2 = input_0 primals_3 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
Alwaysproblem/examples-1
BertSelfOutput
false
1,364
[ "MIT" ]
0
9754fa63ed1931489a21ac1f5b299f945e369a5c
https://github.com/Alwaysproblem/examples-1/tree/9754fa63ed1931489a21ac1f5b299f945e369a5c
LinearWithChannel
import math import torch import torch.nn as nn class LinearWithChannel(nn.Module): def __init__(self, channel_size, input_size, output_size): super(LinearWithChannel, self).__init__() self.weight = torch.nn.Parameter(torch.zeros(channel_size, output_size, input_size)) self.bias = torch.nn.Parameter(torch.zeros(channel_size, output_size)) self.reset_parameters(self.weight, self.bias) def reset_parameters(self, weights, bias): torch.nn.init.kaiming_uniform_(weights, a=math.sqrt(3)) fan_in, _ = torch.nn.init._calculate_fan_in_and_fan_out(weights) bound = 1 / math.sqrt(fan_in) torch.nn.init.uniform_(bias, -bound, bound) def forward(self, x): assert x.ndim >= 2, 'Requires (..., channel, features) shape.' x = x.unsqueeze(-1) result = torch.matmul(self.weight, x).squeeze(-1) + self.bias return result def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'channel_size': 4, 'input_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 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_clone_0(in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 1024 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_add_1(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 % 16 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 = args args.clear() assert_size_stride(primals_1, (4, 4, 4, 4), (64, 16, 4, 1)) assert_size_stride(primals_2, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_3, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 4, 4, 4), (256, 64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_0[grid(1024)](primals_2, buf0, 1024, XBLOCK= 256, num_warps=4, num_stages=1) del primals_2 buf1 = empty_strided_cuda((64, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (64, 4, 4), (16, 4, 1), 0), reinterpret_tensor(primals_1, (64, 4, 1), (4, 1, 1), 0), out=buf1) del buf0 buf2 = reinterpret_tensor(buf1, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf1 triton_poi_fused_add_1[grid(256)](buf2, primals_3, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_3 return buf2, reinterpret_tensor(primals_1, (64, 1, 4), (4, 1, 1), 0) class LinearWithChannelNew(nn.Module): def __init__(self, channel_size, input_size, output_size): super(LinearWithChannelNew, self).__init__() self.weight = torch.nn.Parameter(torch.zeros(channel_size, output_size, input_size)) self.bias = torch.nn.Parameter(torch.zeros(channel_size, output_size)) self.reset_parameters(self.weight, self.bias) def reset_parameters(self, weights, bias): torch.nn.init.kaiming_uniform_(weights, a=math.sqrt(3)) fan_in, _ = torch.nn.init._calculate_fan_in_and_fan_out(weights) bound = 1 / math.sqrt(fan_in) torch.nn.init.uniform_(bias, -bound, bound) def forward(self, input_0): primals_2 = self.weight primals_3 = self.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
adam-coogan/swyft
LinearWithChannel
false
1,365
[ "MIT" ]
0
c54bdd9f77ddf02fda857e26640df012cbe545fc
https://github.com/adam-coogan/swyft/tree/c54bdd9f77ddf02fda857e26640df012cbe545fc
WeightedL1
import torch import torch.nn as nn class WeightedL1(nn.Module): def __init__(self): super(WeightedL1, self).__init__() def forward(self, x, target, w): return (w * torch.abs(x - target)).mean() 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 [[], {}]
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_mean_mul_sub_0(in_out_ptr0, in_ptr0, in_ptr1, in_ptr2, 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 = tl.load(in_ptr2 + r0, None) tmp3 = tmp1 - tmp2 tmp4 = tl_math.abs(tmp3) tmp5 = tmp0 * tmp4 tmp6 = tl.broadcast_to(tmp5, [RBLOCK]) tmp8 = triton_helpers.promote_to_tensor(tl.sum(tmp6, 0)) tmp9 = 256.0 tmp10 = tmp8 / tmp9 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp10, None) 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((), (), torch.float32) buf1 = buf0 del buf0 get_raw_stream(0) triton_per_fused_abs_mean_mul_sub_0[grid(1)](buf1, arg2_1, arg0_1, arg1_1, 1, 256, num_warps=2, num_stages=1) del arg0_1 del arg1_1 del arg2_1 return buf1, class WeightedL1New(nn.Module): def __init__(self): super(WeightedL1New, self).__init__() 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]
acrosson/dl
WeightedL1
false
1,366
[ "MIT" ]
0
94e68533b38f53f09e9bef460ba96fa389fc8eb4
https://github.com/acrosson/dl/tree/94e68533b38f53f09e9bef460ba96fa389fc8eb4
minibatch_std_concat_layer
import copy import torch import torch.utils.data from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg from torch import autograd as autograd class minibatch_std_concat_layer(nn.Module): def __init__(self, averaging='all'): super(minibatch_std_concat_layer, self).__init__() self.averaging = averaging.lower() if 'group' in self.averaging: self.n = int(self.averaging[5:]) else: assert self.averaging in ['all', 'flat', 'spatial', 'none', 'gpool' ], 'Invalid averaging mode' % self.averaging self.adjusted_std = lambda x, **kwargs: torch.sqrt(torch.mean((x - torch.mean(x, **kwargs)) ** 2, **kwargs) + 1e-08) def forward(self, x): shape = list(x.size()) target_shape = copy.deepcopy(shape) vals = self.adjusted_std(x, dim=0, keepdim=True) if self.averaging == 'all': target_shape[1] = 1 vals = torch.mean(vals, dim=1, keepdim=True) elif self.averaging == 'spatial': if len(shape) == 4: vals = mean(vals, axis=[2, 3], keepdim=True) elif self.averaging == 'none': target_shape = [target_shape[0]] + [s for s in target_shape[1:]] elif self.averaging == 'gpool': if len(shape) == 4: vals = mean(x, [0, 2, 3], keepdim=True) elif self.averaging == 'flat': target_shape[1] = 1 vals = torch.FloatTensor([self.adjusted_std(x)]) else: target_shape[1] = self.n vals = vals.view(self.n, self.shape[1] / self.n, self.shape[2], self.shape[3]) vals = mean(vals, axis=0, keepdim=True).view(1, self.n, 1, 1) vals = vals.expand(*target_shape) return torch.cat([x, vals], 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.triton_helpers import libdevice import torch.utils.data from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg 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_poi_fused_add_mean_pow_sqrt_sub_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 = tl.load(in_ptr0 + (64 + x0), xmask) tmp3 = tl.load(in_ptr0 + (128 + x0), xmask) tmp5 = tl.load(in_ptr0 + (192 + x0), xmask) tmp24 = tl.load(in_ptr0 + (16 + x0), xmask) tmp25 = tl.load(in_ptr0 + (80 + x0), xmask) tmp27 = tl.load(in_ptr0 + (144 + x0), xmask) tmp29 = tl.load(in_ptr0 + (208 + x0), xmask) tmp47 = tl.load(in_ptr0 + (32 + x0), xmask) tmp48 = tl.load(in_ptr0 + (96 + x0), xmask) tmp50 = tl.load(in_ptr0 + (160 + x0), xmask) tmp52 = tl.load(in_ptr0 + (224 + x0), xmask) tmp70 = tl.load(in_ptr0 + (48 + x0), xmask) tmp71 = tl.load(in_ptr0 + (112 + x0), xmask) tmp73 = tl.load(in_ptr0 + (176 + x0), xmask) tmp75 = tl.load(in_ptr0 + (240 + x0), xmask) 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-08 tmp22 = tmp20 + tmp21 tmp23 = libdevice.sqrt(tmp22) tmp26 = tmp24 + tmp25 tmp28 = tmp26 + tmp27 tmp30 = tmp28 + tmp29 tmp31 = tmp30 / tmp7 tmp32 = tmp24 - tmp31 tmp33 = tmp32 * tmp32 tmp34 = tmp25 - tmp31 tmp35 = tmp34 * tmp34 tmp36 = tmp33 + tmp35 tmp37 = tmp27 - tmp31 tmp38 = tmp37 * tmp37 tmp39 = tmp36 + tmp38 tmp40 = tmp29 - tmp31 tmp41 = tmp40 * tmp40 tmp42 = tmp39 + tmp41 tmp43 = tmp42 / tmp7 tmp44 = tmp43 + tmp21 tmp45 = libdevice.sqrt(tmp44) tmp46 = tmp23 + tmp45 tmp49 = tmp47 + tmp48 tmp51 = tmp49 + tmp50 tmp53 = tmp51 + tmp52 tmp54 = tmp53 / tmp7 tmp55 = tmp47 - tmp54 tmp56 = tmp55 * tmp55 tmp57 = tmp48 - tmp54 tmp58 = tmp57 * tmp57 tmp59 = tmp56 + tmp58 tmp60 = tmp50 - tmp54 tmp61 = tmp60 * tmp60 tmp62 = tmp59 + tmp61 tmp63 = tmp52 - tmp54 tmp64 = tmp63 * tmp63 tmp65 = tmp62 + tmp64 tmp66 = tmp65 / tmp7 tmp67 = tmp66 + tmp21 tmp68 = libdevice.sqrt(tmp67) tmp69 = tmp46 + tmp68 tmp72 = tmp70 + tmp71 tmp74 = tmp72 + tmp73 tmp76 = tmp74 + tmp75 tmp77 = tmp76 / tmp7 tmp78 = tmp70 - tmp77 tmp79 = tmp78 * tmp78 tmp80 = tmp71 - tmp77 tmp81 = tmp80 * tmp80 tmp82 = tmp79 + tmp81 tmp83 = tmp73 - tmp77 tmp84 = tmp83 * tmp83 tmp85 = tmp82 + tmp84 tmp86 = tmp75 - tmp77 tmp87 = tmp86 * tmp86 tmp88 = tmp85 + tmp87 tmp89 = tmp88 / tmp7 tmp90 = tmp89 + tmp21 tmp91 = libdevice.sqrt(tmp90) tmp92 = tmp69 + tmp91 tmp93 = tmp92 / tmp7 tl.store(out_ptr0 + x0, tmp93, xmask) @triton.jit def triton_poi_fused_cat_1(in_ptr0, in_ptr1, out_ptr0, xnumel, XBLOCK: tl. constexpr): xnumel = 320 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x1 = xindex // 16 % 5 x0 = xindex % 16 x2 = xindex // 80 x3 = xindex tmp0 = x1 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (x0 + 16 * x1 + 64 * x2), tmp4 & xmask, other=0.0) tmp6 = tmp0 >= tmp3 tl.full([1], 5, tl.int64) tmp9 = tl.load(in_ptr1 + x0, tmp6 & xmask, eviction_policy='evict_last', other=0.0) tmp10 = tl.where(tmp4, tmp5, tmp9) tl.store(out_ptr0 + x3, 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((1, 1, 4, 4), (16, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_mean_pow_sqrt_sub_0[grid(16)](arg0_1, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 5, 4, 4), (80, 16, 4, 1), torch.float32) triton_poi_fused_cat_1[grid(320)](arg0_1, buf0, buf1, 320, XBLOCK= 256, num_warps=4, num_stages=1) del arg0_1 del buf0 return buf1, class minibatch_std_concat_layerNew(nn.Module): def __init__(self, averaging='all'): super(minibatch_std_concat_layerNew, self).__init__() self.averaging = averaging.lower() if 'group' in self.averaging: self.n = int(self.averaging[5:]) else: assert self.averaging in ['all', 'flat', 'spatial', 'none', 'gpool' ], 'Invalid averaging mode' % self.averaging self.adjusted_std = lambda x, **kwargs: torch.sqrt(torch.mean((x - torch.mean(x, **kwargs)) ** 2, **kwargs) + 1e-08) def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
achrefjarray/ESRGANplus-master
minibatch_std_concat_layer
false
1,367
[ "Apache-2.0" ]
0
ba470ec5c565a6dc8b48575b1e185ef6b796aec6
https://github.com/achrefjarray/ESRGANplus-master/tree/ba470ec5c565a6dc8b48575b1e185ef6b796aec6
ResidualBlockNoBN
import torch import torch.utils.data from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torch.nn.modules.batchnorm import _BatchNorm from torchvision.models import vgg as vgg from torch import autograd as autograd @torch.no_grad() def default_init_weights(module_list, scale=1, bias_fill=0, **kwargs): """Initialize network weights. Args: module_list (list[nn.Module] | nn.Module): Modules to be initialized. scale (float): Scale initialized weights, especially for residual blocks. Default: 1. bias_fill (float): The value to fill bias. Default: 0 kwargs (dict): Other arguments for initialization function. """ if not isinstance(module_list, list): module_list = [module_list] for module in module_list: for m in module.modules(): if isinstance(m, nn.Conv2d): init.kaiming_normal_(m.weight, **kwargs) m.weight.data *= scale if m.bias is not None: m.bias.data.fill_(bias_fill) elif isinstance(m, nn.Linear): init.kaiming_normal_(m.weight, **kwargs) m.weight.data *= scale if m.bias is not None: m.bias.data.fill_(bias_fill) elif isinstance(m, _BatchNorm): init.constant_(m.weight, 1) if m.bias is not None: m.bias.data.fill_(bias_fill) class ResidualBlockNoBN(nn.Module): """Residual block without BN. It has a style of: ---Conv-ReLU-Conv-+- |________________| Args: num_feat (int): Channel number of intermediate features. Default: 64. res_scale (float): Residual scale. Default: 1. pytorch_init (bool): If set to True, use pytorch default init, otherwise, use default_init_weights. Default: False. """ def __init__(self, num_feat=64, res_scale=1, pytorch_init=False): super(ResidualBlockNoBN, self).__init__() self.res_scale = res_scale self.conv1 = nn.Conv2d(num_feat, num_feat, 3, 1, 1, bias=True) self.conv2 = nn.Conv2d(num_feat, num_feat, 3, 1, 1, bias=True) self.relu = nn.ReLU(inplace=True) if not pytorch_init: default_init_weights([self.conv1, self.conv2], 0.1) def forward(self, x): identity = x out = self.conv2(self.relu(self.conv1(x))) return identity + out * self.res_scale 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.utils.data from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torch.nn.modules.batchnorm import _BatchNorm from torchvision.models import vgg as vgg from torch import autograd as autograd assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_relu_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) x3 = xindex x1 = xindex // 4096 % 64 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_add_convolution_mul_1(in_out_ptr0, in_ptr0, in_ptr1, 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 // 4096 % 64 tmp0 = tl.load(in_ptr0 + x3, None) tmp1 = tl.load(in_out_ptr0 + x3, None) tmp2 = tl.load(in_ptr1 + x1, None, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = 1.0 tmp5 = tmp3 * tmp4 tmp6 = tmp0 + tmp5 tl.store(in_out_ptr0 + x3, tmp6, None) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 64, 64, 64), (262144, 4096, 64, 1)) assert_size_stride(primals_2, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_3, (64,), (1,)) assert_size_stride(primals_4, (64, 64, 3, 3), (576, 9, 3, 1)) assert_size_stride(primals_5, (64,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_1, primals_2, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 64, 64, 64), (262144, 4096, 64, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_relu_0[grid(1048576)](buf1, primals_3, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_3 buf2 = extern_kernels.convolution(buf1, primals_4, stride=(1, 1), padding=(1, 1), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf2, (4, 64, 64, 64), (262144, 4096, 64, 1)) buf3 = buf2 del buf2 triton_poi_fused_add_convolution_mul_1[grid(1048576)](buf3, primals_1, primals_5, 1048576, XBLOCK=1024, num_warps=4, num_stages=1) del primals_5 return buf3, primals_1, primals_2, primals_4, buf1 @torch.no_grad() def default_init_weights(module_list, scale=1, bias_fill=0, **kwargs): """Initialize network weights. Args: module_list (list[nn.Module] | nn.Module): Modules to be initialized. scale (float): Scale initialized weights, especially for residual blocks. Default: 1. bias_fill (float): The value to fill bias. Default: 0 kwargs (dict): Other arguments for initialization function. """ if not isinstance(module_list, list): module_list = [module_list] for module in module_list: for m in module.modules(): if isinstance(m, nn.Conv2d): init.kaiming_normal_(m.weight, **kwargs) m.weight.data *= scale if m.bias is not None: m.bias.data.fill_(bias_fill) elif isinstance(m, nn.Linear): init.kaiming_normal_(m.weight, **kwargs) m.weight.data *= scale if m.bias is not None: m.bias.data.fill_(bias_fill) elif isinstance(m, _BatchNorm): init.constant_(m.weight, 1) if m.bias is not None: m.bias.data.fill_(bias_fill) class ResidualBlockNoBNNew(nn.Module): """Residual block without BN. It has a style of: ---Conv-ReLU-Conv-+- |________________| Args: num_feat (int): Channel number of intermediate features. Default: 64. res_scale (float): Residual scale. Default: 1. pytorch_init (bool): If set to True, use pytorch default init, otherwise, use default_init_weights. Default: False. """ def __init__(self, num_feat=64, res_scale=1, pytorch_init=False): super(ResidualBlockNoBNNew, self).__init__() self.res_scale = res_scale self.conv1 = nn.Conv2d(num_feat, num_feat, 3, 1, 1, bias=True) self.conv2 = nn.Conv2d(num_feat, num_feat, 3, 1, 1, bias=True) self.relu = nn.ReLU(inplace=True) if not pytorch_init: default_init_weights([self.conv1, self.conv2], 0.1) def forward(self, input_0): primals_2 = self.conv1.weight primals_3 = self.conv1.bias primals_4 = self.conv2.weight primals_5 = self.conv2.bias primals_1 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
achrefjarray/ESRGANplus-master
ResidualBlockNoBN
false
1,368
[ "Apache-2.0" ]
0
ba470ec5c565a6dc8b48575b1e185ef6b796aec6
https://github.com/achrefjarray/ESRGANplus-master/tree/ba470ec5c565a6dc8b48575b1e185ef6b796aec6
MySoftmax
import torch import torch.nn as nn import torch.nn.functional as F class MySoftmax(nn.Module): def forward(self, input_): batch_size = input_.size()[0] output_ = torch.stack([F.softmax(input_[i]) for i in range( batch_size)], 0) return output_ 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 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 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_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 + (64 + x2), xmask) tmp1 = tl.load(in_ptr0 + (64 + x0), xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (80 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (96 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (112 + 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 + (128 + x2), xmask) tmp1 = tl.load(in_ptr0 + (128 + x0), xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (144 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (160 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (176 + 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_3(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 + (192 + x2), xmask) tmp1 = tl.load(in_ptr0 + (192 + x0), xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (208 + x0), xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr0 + (224 + x0), xmask, eviction_policy='evict_last') tmp6 = tl.load(in_ptr0 + (240 + 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_stack_4(in_ptr0, in_ptr1, in_ptr2, in_ptr3, 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 // 16 x0 = xindex % 16 x2 = xindex tmp0 = x1 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 4, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + (x0 + 16 * x1), tmp4 & xmask, other=0.0) tmp6 = tl.load(in_ptr0 + x0, tmp4 & xmask, eviction_policy='evict_last', other=0.0) tmp7 = tl.load(in_ptr0 + (16 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp8 = tmp6 + tmp7 tmp9 = tl.load(in_ptr0 + (32 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp10 = tmp8 + tmp9 tmp11 = tl.load(in_ptr0 + (48 + x0), tmp4 & xmask, eviction_policy= 'evict_last', other=0.0) tmp12 = tmp10 + tmp11 tmp13 = tmp5 / tmp12 tmp14 = tl.full(tmp13.shape, 0.0, tmp13.dtype) tmp15 = tl.where(tmp4, tmp13, tmp14) tmp16 = tmp0 >= tmp3 tmp17 = tl.full([1], 8, tl.int64) tmp18 = tmp0 < tmp17 tmp19 = tmp16 & tmp18 tmp20 = tl.load(in_ptr1 + (x0 + 16 * (-4 + x1)), tmp19 & xmask, other=0.0) tmp21 = tl.load(in_ptr1 + x0, tmp19 & xmask, eviction_policy= 'evict_last', other=0.0) tmp22 = tl.load(in_ptr1 + (16 + x0), tmp19 & xmask, eviction_policy= 'evict_last', other=0.0) tmp23 = tmp21 + tmp22 tmp24 = tl.load(in_ptr1 + (32 + x0), tmp19 & xmask, eviction_policy= 'evict_last', other=0.0) tmp25 = tmp23 + tmp24 tmp26 = tl.load(in_ptr1 + (48 + x0), tmp19 & xmask, eviction_policy= 'evict_last', other=0.0) tmp27 = tmp25 + tmp26 tmp28 = tmp20 / tmp27 tmp29 = tl.full(tmp28.shape, 0.0, tmp28.dtype) tmp30 = tl.where(tmp19, tmp28, tmp29) tmp31 = tmp0 >= tmp17 tmp32 = tl.full([1], 12, tl.int64) tmp33 = tmp0 < tmp32 tmp34 = tmp31 & tmp33 tmp35 = tl.load(in_ptr2 + (x0 + 16 * (-8 + x1)), tmp34 & xmask, other=0.0) tmp36 = tl.load(in_ptr2 + x0, tmp34 & xmask, eviction_policy= 'evict_last', other=0.0) tmp37 = tl.load(in_ptr2 + (16 + x0), tmp34 & xmask, eviction_policy= 'evict_last', other=0.0) tmp38 = tmp36 + tmp37 tmp39 = tl.load(in_ptr2 + (32 + x0), tmp34 & xmask, eviction_policy= 'evict_last', other=0.0) tmp40 = tmp38 + tmp39 tmp41 = tl.load(in_ptr2 + (48 + x0), tmp34 & xmask, eviction_policy= 'evict_last', other=0.0) tmp42 = tmp40 + tmp41 tmp43 = tmp35 / tmp42 tmp44 = tl.full(tmp43.shape, 0.0, tmp43.dtype) tmp45 = tl.where(tmp34, tmp43, tmp44) tmp46 = tmp0 >= tmp32 tl.full([1], 16, tl.int64) tmp49 = tl.load(in_ptr3 + (x0 + 16 * (-12 + x1)), tmp46 & xmask, other=0.0) tmp50 = tl.load(in_ptr3 + x0, tmp46 & xmask, eviction_policy= 'evict_last', other=0.0) tmp51 = tl.load(in_ptr3 + (16 + x0), tmp46 & xmask, eviction_policy= 'evict_last', other=0.0) tmp52 = tmp50 + tmp51 tmp53 = tl.load(in_ptr3 + (32 + x0), tmp46 & xmask, eviction_policy= 'evict_last', other=0.0) tmp54 = tmp52 + tmp53 tmp55 = tl.load(in_ptr3 + (48 + x0), tmp46 & xmask, eviction_policy= 'evict_last', other=0.0) tmp56 = tmp54 + tmp55 tmp57 = tmp49 / tmp56 tmp58 = tl.full(tmp57.shape, 0.0, tmp57.dtype) tmp59 = tl.where(tmp46, tmp57, tmp58) tmp60 = tl.where(tmp34, tmp45, tmp59) tmp61 = tl.where(tmp19, tmp30, tmp60) tmp62 = tl.where(tmp4, tmp15, tmp61) tl.store(out_ptr0 + x2, tmp62, 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), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(64)](arg0_1, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(64)](arg0_1, buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_2[grid(64)](arg0_1, buf2, 64, XBLOCK=64, num_warps=1, num_stages=1) buf3 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_3[grid(64)](arg0_1, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) del arg0_1 buf4 = empty_strided_cuda((16, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_stack_4[grid(256)](buf0, buf1, buf2, buf3, buf4, 256, XBLOCK=128, num_warps=4, num_stages=1) del buf0 del buf1 del buf2 del buf3 return reinterpret_tensor(buf4, (4, 4, 4, 4), (64, 16, 4, 1), 0), class MySoftmaxNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
acrosson/dl
MySoftmax
false
1,369
[ "MIT" ]
0
94e68533b38f53f09e9bef460ba96fa389fc8eb4
https://github.com/acrosson/dl/tree/94e68533b38f53f09e9bef460ba96fa389fc8eb4
CBR
import torch import torch.nn as nn class CBR(nn.Module): def __init__(self, in_channels, out_channels, kernel_size): super(CBR, self).__init__() self.cnn = nn.Conv2d(in_channels, out_channels, kernel_size, stride =2, padding=2) self.relu = nn.ReLU() def forward(self, x): out = self.cnn(x) out = self.relu(out) return out 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 from torch._inductor.runtime import triton_helpers 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_convolution_relu_threshold_backward_0(in_out_ptr0, in_ptr0, out_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 144 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 9 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, 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 + x3, tmp4, xmask) tl.store(out_ptr0 + x3, tmp6, 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=(2, 2), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 3, 3), (36, 9, 3, 1)) buf1 = buf0 del buf0 buf2 = empty_strided_cuda((4, 4, 3, 3), (36, 9, 3, 1), torch.bool) get_raw_stream(0) triton_poi_fused_convolution_relu_threshold_backward_0[grid(144)](buf1, primals_2, buf2, 144, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 return buf1, primals_1, primals_3, buf2 class CBRNew(nn.Module): def __init__(self, in_channels, out_channels, kernel_size): super(CBRNew, self).__init__() self.cnn = nn.Conv2d(in_channels, out_channels, kernel_size, stride =2, padding=2) self.relu = nn.ReLU() def forward(self, input_0): primals_1 = self.cnn.weight primals_2 = self.cnn.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
adamkrekorian/CI-UNet
CBR
false
1,370
[ "MIT" ]
0
fab0f8806540f5d79911bd81ba54dff135f9814f
https://github.com/adamkrekorian/CI-UNet/tree/fab0f8806540f5d79911bd81ba54dff135f9814f
TransformerEncoderLayer
import math import torch from torch import nn from torch.nn import functional as F import torch.utils.data def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class LayerNorm(nn.Module): def __init__(self, d_model, eps=1e-06): super().__init__() self.gamma = nn.Parameter(torch.ones(d_model)) self.beta = nn.Parameter(torch.zeros(d_model)) self.eps = eps def forward(self, x): mean = x.mean(-1, keepdim=True) std = x.std(-1, keepdim=True) return self.gamma * (x - mean) / (std + self.eps) + self.beta class ResidualBlock(nn.Module): def __init__(self, layer, d_model, dropout_ratio): super().__init__() self.layer = layer self.dropout = nn.Dropout(dropout_ratio) self.layernorm = LayerNorm(d_model) def forward(self, *x, padding=None): return self.layernorm(x[0] + self.dropout(self.layer(*x, padding= padding))) class Attention(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal def forward(self, query, key, value, padding=None): dot_products = matmul(query, key.transpose(1, 2)) if query.dim() == 3 and self.causal: tri = key.new_ones((key.size(1), key.size(1))).triu(1) * INF dot_products.sub_(tri.unsqueeze(0)) if padding is not None: if dot_products.dim() == 3: dot_products.masked_fill_(padding.unsqueeze(1).expand_as( dot_products), -INF) else: dot_products.masked_fill_(padding, -INF) return matmul(self.dropout(F.softmax(dot_products / self.scale, dim =-1)), value) class Linear(nn.Linear): def forward(self, x): size = x.size() return super().forward(x.contiguous().view(-1, size[-1])).view(* size[:-1], -1) class MultiHead(nn.Module): def __init__(self, d_key, d_value, n_heads, dropout_ratio, causal=False): super().__init__() self.attention = Attention(d_key, dropout_ratio, causal=causal) self.wq = Linear(d_key, d_key, bias=False) self.wk = Linear(d_key, d_key, bias=False) self.wv = Linear(d_value, d_value, bias=False) self.n_heads = n_heads def forward(self, query, key, value, padding=None): query, key, value = self.wq(query), self.wk(key), self.wv(value) query, key, value = (x.chunk(self.n_heads, -1) for x in (query, key, value)) return torch.cat([self.attention(q, k, v, padding=padding) for q, k, v in zip(query, key, value)], -1) class Feedforward(nn.Module): def __init__(self, d_in, d_out, activation=None, bias=True, dropout=0.2): super().__init__() if activation is not None: self.activation = getattr(torch, activation) else: self.activation = lambda x: x self.linear = Linear(d_in, d_out, bias=bias) self.dropout = nn.Dropout(dropout) def forward(self, x): return self.activation(self.linear(self.dropout(x))) class LinearReLU(nn.Module): def __init__(self, d_model, d_hidden): super().__init__() self.feedforward = Feedforward(d_model, d_hidden, activation='relu') self.linear = Linear(d_hidden, d_model) def forward(self, x, padding=None): return self.linear(self.feedforward(x)) class TransformerEncoderLayer(nn.Module): def __init__(self, dimension, n_heads, hidden, dropout): super().__init__() self.selfattn = ResidualBlock(MultiHead(dimension, dimension, n_heads, dropout), dimension, dropout) self.feedforward = ResidualBlock(LinearReLU(dimension, hidden), dimension, dropout) def forward(self, x, padding=None): return self.feedforward(self.selfattn(x, x, x, padding=padding)) def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'dimension': 4, 'n_heads': 4, 'hidden': 4, 'dropout': 0.5}]
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, math as tl_math import math from torch import nn from torch.nn import functional as F import torch.utils.data 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 = 0.5 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) @triton.jit def triton_poi_fused_cat_2(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 x0 = xindex % 4 x1 = xindex // 4 x2 = xindex tmp0 = x0 tl.full([1], 0, tl.int64) tmp3 = tl.full([1], 1, tl.int64) tmp4 = tmp0 < tmp3 tmp5 = tl.load(in_ptr0 + x1, 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 + x1, 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 + x1, tmp14 & xmask, eviction_policy= 'evict_last', other=0.0) tmp16 = tmp0 >= tmp12 tl.full([1], 4, tl.int64) tmp19 = tl.load(in_ptr3 + x1, 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 + x2, tmp22, xmask) @triton.jit def triton_poi_fused_add_mean_std_3(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 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 = 3.0 tmp29 = tmp27 / tmp28 tl.store(in_out_ptr0 + x0, tmp29, xmask) tl.store(out_ptr0 + x0, tmp16, xmask) @triton.jit def triton_poi_fused_add_div_mean_mul_std_sub_4(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, in_ptr5, 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 % 4 x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask) tmp2 = tl.load(in_ptr2 + x2, xmask) tmp4 = tl.load(in_ptr3 + x1, xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr4 + x1, xmask, eviction_policy='evict_last') tmp12 = tl.load(in_ptr5 + x0, xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 - tmp4 tmp6 = tmp0 * tmp5 tmp8 = libdevice.sqrt(tmp7) tmp9 = 1e-06 tmp10 = tmp8 + tmp9 tmp11 = tmp6 / tmp10 tmp13 = tmp11 + tmp12 tl.store(out_ptr0 + x2, tmp13, xmask) @triton.jit def triton_poi_fused_relu_threshold_backward_5(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) @triton.jit def triton_poi_fused_add_6(in_out_ptr0, in_ptr0, in_ptr1, 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_ptr0 + x2, xmask) tmp1 = tl.load(in_out_ptr0 + x2, xmask) tmp2 = tl.load(in_ptr1 + x0, xmask, eviction_policy='evict_last') tmp3 = tmp1 + tmp2 tmp4 = tmp0 + tmp3 tl.store(in_out_ptr0 + x2, tmp4, xmask) @triton.jit def triton_poi_fused_add_div_mean_mul_std_sub_7(in_ptr0, in_ptr1, in_ptr2, 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 % 4 x2 = xindex x1 = xindex // 4 tmp0 = tl.load(in_ptr0 + x0, xmask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr1 + x2, xmask) tmp2 = tl.load(in_ptr1 + 4 * x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr1 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr1 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr1 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp30 = tl.load(in_ptr2 + x0, xmask, eviction_policy='evict_last') tmp4 = tmp2 + tmp3 tmp6 = tmp4 + tmp5 tmp8 = tmp6 + tmp7 tmp9 = 4.0 tmp10 = tmp8 / tmp9 tmp11 = tmp1 - tmp10 tmp12 = tmp0 * tmp11 tmp13 = tmp2 - tmp10 tmp14 = tmp13 * tmp13 tmp15 = tmp3 - tmp10 tmp16 = tmp15 * tmp15 tmp17 = tmp14 + tmp16 tmp18 = tmp5 - tmp10 tmp19 = tmp18 * tmp18 tmp20 = tmp17 + tmp19 tmp21 = tmp7 - tmp10 tmp22 = tmp21 * tmp21 tmp23 = tmp20 + tmp22 tmp24 = 3.0 tmp25 = tmp23 / tmp24 tmp26 = libdevice.sqrt(tmp25) tmp27 = 1e-06 tmp28 = tmp26 + tmp27 tmp29 = tmp12 / tmp28 tmp31 = tmp29 + tmp30 tl.store(out_ptr0 + x2, tmp31, 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, (4, 4, 4), (16, 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, 4), (4, 1)) assert_size_stride(primals_5, (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,)) assert_size_stride(primals_9, (4, 4), (4, 1)) assert_size_stride(primals_10, (4,), (1,)) assert_size_stride(primals_11, (4,), (1,)) assert_size_stride(primals_12, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (16, 4), (4, 1), 0), reinterpret_tensor(primals_2, (4, 4), (1, 4), 0), out=buf0) del primals_2 buf1 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (16, 4), (4, 1), 0), reinterpret_tensor(primals_3, (4, 4), (1, 4), 0), out=buf1) del primals_3 buf2 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(primals_1, (16, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf2) del primals_4 buf3 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 0), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 0), out=buf3) buf4 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused__softmax_0[grid(64)](buf3, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) buf5 = buf3 del buf3 triton_poi_fused__softmax_1[grid(64)](buf4, buf5, 64, XBLOCK=64, num_warps=1, num_stages=1) buf6 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf5, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 0), out=buf6) buf7 = buf4 del buf4 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 1), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 1), out=buf7) buf8 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf7, buf8, 64, XBLOCK=64, num_warps=1, num_stages=1) buf9 = buf7 del buf7 triton_poi_fused__softmax_1[grid(64)](buf8, buf9, 64, XBLOCK=64, num_warps=1, num_stages=1) buf10 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf9, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 1), out=buf10) buf11 = buf8 del buf8 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 2), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 2), out=buf11) buf12 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf11, buf12, 64, XBLOCK=64, num_warps=1, num_stages=1) buf13 = buf11 del buf11 triton_poi_fused__softmax_1[grid(64)](buf12, buf13, 64, XBLOCK=64, num_warps=1, num_stages=1) buf14 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf13, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 2), out=buf14) buf15 = buf12 del buf12 extern_kernels.bmm(reinterpret_tensor(buf0, (4, 4, 1), (16, 4, 1), 3), reinterpret_tensor(buf1, (4, 1, 4), (16, 1, 4), 3), out=buf15) buf16 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_0[grid(64)](buf15, buf16, 64, XBLOCK=64, num_warps=1, num_stages=1) buf17 = buf15 del buf15 triton_poi_fused__softmax_1[grid(64)](buf16, buf17, 64, XBLOCK=64, num_warps=1, num_stages=1) buf18 = empty_strided_cuda((4, 4, 1), (4, 1, 1), torch.float32) extern_kernels.bmm(buf17, reinterpret_tensor(buf2, (4, 4, 1), (16, 4, 1), 3), out=buf18) buf19 = buf16 del buf16 triton_poi_fused_cat_2[grid(64)](buf6, buf10, buf14, buf18, buf19, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf10 del buf14 buf20 = reinterpret_tensor(buf6, (4, 4, 1), (4, 1, 16), 0) del buf6 buf21 = buf20 del buf20 buf22 = reinterpret_tensor(buf18, (4, 4, 1), (4, 1, 16), 0) del buf18 triton_poi_fused_add_mean_std_3[grid(16)](buf21, primals_1, buf19, buf22, 16, XBLOCK=16, num_warps=1, num_stages=1) buf23 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_add_div_mean_mul_std_sub_4[grid(64)](primals_5, primals_1, buf19, buf22, buf21, primals_6, buf23, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf21 del buf22 del primals_6 buf24 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf23, (16, 4), (4, 1), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), out=buf24) buf25 = reinterpret_tensor(buf24, (4, 4, 4), (16, 4, 1), 0) del buf24 buf29 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_5[grid(64)](buf25, primals_8, buf29, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_8 buf26 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf25, (16, 4), (4, 1), 0), reinterpret_tensor(primals_9, (4, 4), (1, 4), 0), out=buf26) buf27 = reinterpret_tensor(buf26, (4, 4, 4), (16, 4, 1), 0) del buf26 triton_poi_fused_add_6[grid(64)](buf27, buf23, primals_10, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_10 buf28 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_add_div_mean_mul_std_sub_7[grid(64)](primals_11, buf27, primals_12, buf28, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_12 return (buf28, primals_1, primals_5, primals_11, buf5, buf9, buf13, buf17, buf19, reinterpret_tensor(buf23, (16, 4), (4, 1), 0), reinterpret_tensor(buf25, (16, 4), (4, 1), 0), buf27, primals_9, buf29, primals_7, reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 3 ), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 3), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 3), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 2), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 2), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 2), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 1), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 1), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 1), reinterpret_tensor(buf2, (4, 1, 4), (16, 1, 4), 0), reinterpret_tensor(buf0, (4, 1, 4), (16, 1, 4), 0), reinterpret_tensor(buf1, (4, 4, 1), (16, 4, 1), 0)) def matmul(x, y): if x.dim() == y.dim(): return x @ y if x.dim() == y.dim() - 1: return (x.unsqueeze(-2) @ y).squeeze(-2) return (x @ y.unsqueeze(-2)).squeeze(-2) class LayerNorm(nn.Module): def __init__(self, d_model, eps=1e-06): super().__init__() self.gamma = nn.Parameter(torch.ones(d_model)) self.beta = nn.Parameter(torch.zeros(d_model)) self.eps = eps def forward(self, x): mean = x.mean(-1, keepdim=True) std = x.std(-1, keepdim=True) return self.gamma * (x - mean) / (std + self.eps) + self.beta class ResidualBlock(nn.Module): def __init__(self, layer, d_model, dropout_ratio): super().__init__() self.layer = layer self.dropout = nn.Dropout(dropout_ratio) self.layernorm = LayerNorm(d_model) def forward(self, *x, padding=None): return self.layernorm(x[0] + self.dropout(self.layer(*x, padding= padding))) class Attention(nn.Module): def __init__(self, d_key, dropout_ratio, causal): super().__init__() self.scale = math.sqrt(d_key) self.dropout = nn.Dropout(dropout_ratio) self.causal = causal def forward(self, query, key, value, padding=None): dot_products = matmul(query, key.transpose(1, 2)) if query.dim() == 3 and self.causal: tri = key.new_ones((key.size(1), key.size(1))).triu(1) * INF dot_products.sub_(tri.unsqueeze(0)) if padding is not None: if dot_products.dim() == 3: dot_products.masked_fill_(padding.unsqueeze(1).expand_as( dot_products), -INF) else: dot_products.masked_fill_(padding, -INF) return matmul(self.dropout(F.softmax(dot_products / self.scale, dim =-1)), value) class Linear(nn.Linear): def forward(self, x): size = x.size() return super().forward(x.contiguous().view(-1, size[-1])).view(* size[:-1], -1) class MultiHead(nn.Module): def __init__(self, d_key, d_value, n_heads, dropout_ratio, causal=False): super().__init__() self.attention = Attention(d_key, dropout_ratio, causal=causal) self.wq = Linear(d_key, d_key, bias=False) self.wk = Linear(d_key, d_key, bias=False) self.wv = Linear(d_value, d_value, bias=False) self.n_heads = n_heads def forward(self, query, key, value, padding=None): query, key, value = self.wq(query), self.wk(key), self.wv(value) query, key, value = (x.chunk(self.n_heads, -1) for x in (query, key, value)) return torch.cat([self.attention(q, k, v, padding=padding) for q, k, v in zip(query, key, value)], -1) class Feedforward(nn.Module): def __init__(self, d_in, d_out, activation=None, bias=True, dropout=0.2): super().__init__() if activation is not None: self.activation = getattr(torch, activation) else: self.activation = lambda x: x self.linear = Linear(d_in, d_out, bias=bias) self.dropout = nn.Dropout(dropout) def forward(self, x): return self.activation(self.linear(self.dropout(x))) class LinearReLU(nn.Module): def __init__(self, d_model, d_hidden): super().__init__() self.feedforward = Feedforward(d_model, d_hidden, activation='relu') self.linear = Linear(d_hidden, d_model) def forward(self, x, padding=None): return self.linear(self.feedforward(x)) class TransformerEncoderLayerNew(nn.Module): def __init__(self, dimension, n_heads, hidden, dropout): super().__init__() self.selfattn = ResidualBlock(MultiHead(dimension, dimension, n_heads, dropout), dimension, dropout) self.feedforward = ResidualBlock(LinearReLU(dimension, hidden), dimension, dropout) def forward(self, input_0): primals_2 = self.selfattn.layer.wq.weight primals_3 = self.selfattn.layer.wk.weight primals_4 = self.selfattn.layer.wv.weight primals_5 = self.selfattn.layernorm.gamma primals_6 = self.selfattn.layernorm.beta primals_7 = self.feedforward.layer.feedforward.linear.weight primals_8 = self.feedforward.layer.feedforward.linear.bias primals_9 = self.feedforward.layer.linear.weight primals_10 = self.feedforward.layer.linear.bias primals_11 = self.feedforward.layernorm.gamma primals_12 = self.feedforward.layernorm.beta primals_1 = 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]) return output[0]
abhinavrangarajan/genienlp
TransformerEncoderLayer
false
1,371
[ "BSD-3-Clause" ]
0
ba121274b3365739ce9e5a8facc9a2904149b9c7
https://github.com/abhinavrangarajan/genienlp/tree/ba121274b3365739ce9e5a8facc9a2904149b9c7
DCT
import torch import torch.nn as nn class DCT(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, out_pad=0): super(DCT, self).__init__() self.dcnn = nn.ConvTranspose2d(in_channels, out_channels, kernel_size=2, stride=2, output_padding=out_pad) self.tanh = nn.Tanh() def forward(self, x1): out = self.dcnn(x1) out = self.tanh(out) return out 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 from torch._inductor.runtime.triton_helpers import libdevice import torch.nn as nn assert_size_stride = torch._C._dynamo.guards.assert_size_stride @triton.jit def triton_poi_fused_convolution_tanh_0(in_out_ptr0, in_ptr0, xnumel, XBLOCK: tl.constexpr): xnumel = 1024 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 64 % 4 tmp0 = tl.load(in_out_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = libdevice.tanh(tmp2) tl.store(in_out_ptr0 + x3, tmp3, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (4, 4, 2, 2), (16, 4, 2, 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=(2, 2), padding=(0, 0), dilation=(1, 1), transposed=True, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 8, 8), (256, 64, 8, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_tanh_0[grid(1024)](buf1, primals_2, 1024, XBLOCK=128, num_warps=4, num_stages=1) del primals_2 return buf1, primals_1, primals_3, buf1 class DCTNew(nn.Module): def __init__(self, in_channels, out_channels, kernel_size, out_pad=0): super(DCTNew, self).__init__() self.dcnn = nn.ConvTranspose2d(in_channels, out_channels, kernel_size=2, stride=2, output_padding=out_pad) self.tanh = nn.Tanh() def forward(self, input_0): primals_1 = self.dcnn.weight primals_2 = self.dcnn.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
adamkrekorian/CI-UNet
DCT
false
1,372
[ "MIT" ]
0
fab0f8806540f5d79911bd81ba54dff135f9814f
https://github.com/adamkrekorian/CI-UNet/tree/fab0f8806540f5d79911bd81ba54dff135f9814f
CL
import torch import torch.nn as nn class CL(nn.Module): def __init__(self, in_channels, out_channels, kernel_size): super(CL, self).__init__() self.cnn = nn.Conv2d(in_channels, out_channels, kernel_size, stride =2, padding=2) self.lr = nn.LeakyReLU(negative_slope=0.2) def forward(self, x): out = self.cnn(x) out = self.lr(out) return out 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 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_convolution_leaky_relu_0(in_ptr0, in_ptr1, out_ptr0, out_ptr1, xnumel, XBLOCK: tl.constexpr): xnumel = 144 xoffset = tl.program_id(0) * XBLOCK xindex = xoffset + tl.arange(0, XBLOCK)[:] xmask = xindex < xnumel x3 = xindex x1 = xindex // 9 % 4 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp2 = tmp0 + tmp1 tmp3 = 0.0 tmp4 = tmp2 > tmp3 tmp5 = 0.2 tmp6 = tmp2 * tmp5 tmp7 = tl.where(tmp4, tmp2, tmp6) tl.store(out_ptr0 + x3, tmp4, xmask) tl.store(out_ptr1 + x3, tmp7, 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=(2, 2), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 3, 3), (36, 9, 3, 1)) buf1 = empty_strided_cuda((4, 4, 3, 3), (36, 9, 3, 1), torch.bool) buf2 = empty_strided_cuda((4, 4, 3, 3), (36, 9, 3, 1), torch.float32) get_raw_stream(0) triton_poi_fused_convolution_leaky_relu_0[grid(144)](buf0, primals_2, buf1, buf2, 144, XBLOCK=128, num_warps=4, num_stages=1) del buf0 del primals_2 return buf2, primals_1, primals_3, buf1 class CLNew(nn.Module): def __init__(self, in_channels, out_channels, kernel_size): super(CLNew, self).__init__() self.cnn = nn.Conv2d(in_channels, out_channels, kernel_size, stride =2, padding=2) self.lr = nn.LeakyReLU(negative_slope=0.2) def forward(self, input_0): primals_1 = self.cnn.weight primals_2 = self.cnn.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
adamkrekorian/CI-UNet
CL
false
1,373
[ "MIT" ]
0
fab0f8806540f5d79911bd81ba54dff135f9814f
https://github.com/adamkrekorian/CI-UNet/tree/fab0f8806540f5d79911bd81ba54dff135f9814f
ModulatedConv2d
from torch.autograd import Function import math import torch import torch.utils.data from torch.nn import functional as F from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg from torch import autograd as autograd def pad(pad_type, padding): pad_type = pad_type.lower() if padding == 0: return None if pad_type == 'reflect': layer = nn.ReflectionPad2d(padding) elif pad_type == 'replicate': layer = nn.ReplicationPad2d(padding) else: raise NotImplementedError('padding layer [{:s}] is not implemented' .format(pad_type)) return layer 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 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})' ) def get_inputs(): return [torch.rand([4, 4, 4, 4]), torch.rand([4, 4])] def get_init_inputs(): return [[], {'in_channels': 4, 'out_channels': 4, 'kernel_size': 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._inductor.runtime.triton_helpers import libdevice from torch.autograd import Function import math import torch.utils.data from torch.nn import functional as F from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg 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_per_fused_add_mul_pow_rsqrt_sum_2(in_out_ptr0, in_ptr0, in_ptr1, out_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): xnumel = 16 RBLOCK: tl.constexpr = 64 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) r5 = rindex x0 = xindex % 4 r3 = rindex // 16 x1 = xindex // 4 x4 = xindex tmp0 = tl.load(in_ptr0 + (r5 + 64 * x0), xmask, eviction_policy= 'evict_last', other=0.0) tmp3 = tl.load(in_ptr1 + (r3 + 4 * x1), xmask, eviction_policy= 'evict_last', other=0.0) tmp1 = 0.125 tmp2 = tmp0 * tmp1 tmp4 = tmp2 * tmp3 tmp5 = tmp4 * tmp4 tmp6 = tl.broadcast_to(tmp5, [XBLOCK, RBLOCK]) tmp8 = tl.where(xmask, tmp6, 0) tmp9 = tl.sum(tmp8, 1)[:, None] tmp10 = 1e-08 tmp11 = tmp9 + tmp10 tmp12 = libdevice.rsqrt(tmp11) tmp13 = tmp4 * tmp12 tl.debug_barrier() tl.store(in_out_ptr0 + x4, tmp12, xmask) tl.store(out_ptr0 + (r5 + 64 * x4), tmp13, 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,), (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, 4, 4, 4, 4), (256, 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_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 buf1 buf3 = buf0 del buf0 buf4 = buf3 del buf3 buf5 = empty_strided_cuda((4, 4, 4, 4, 4), (256, 64, 16, 4, 1), torch.float32) triton_per_fused_add_mul_pow_rsqrt_sum_2[grid(16)](buf4, primals_5, buf2, buf5, 16, 64, XBLOCK=1, num_warps=2, num_stages=1) buf6 = extern_kernels.convolution(reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0), reinterpret_tensor(buf5, (16, 4, 4, 4), (64, 16, 4, 1), 0), stride=(1, 1), padding=(2, 2), dilation=(1, 1), transposed=False, output_padding=(0, 0), groups=4, bias=None) assert_size_stride(buf6, (1, 16, 5, 5), (400, 25, 5, 1)) return reinterpret_tensor(buf6, (4, 4, 5, 5), (100, 25, 5, 1), 0 ), primals_4, primals_5, buf2, buf4, reinterpret_tensor(buf5, (16, 4, 4, 4), (64, 16, 4, 1), 0), reinterpret_tensor(primals_1, (1, 16, 4, 4), (256, 16, 4, 1), 0) def pad(pad_type, padding): pad_type = pad_type.lower() if padding == 0: return None if pad_type == 'reflect': layer = nn.ReflectionPad2d(padding) elif pad_type == 'replicate': layer = nn.ReplicationPad2d(padding) else: raise NotImplementedError('padding layer [{:s}] is not implemented' .format(pad_type)) return layer 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 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 ModulatedConv2dNew(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(ModulatedConv2dNew, 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 __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})' ) def forward(self, input_0, input_1): primals_5 = self.weight primals_3 = self.modulation.weight primals_2 = self.modulation.bias primals_1 = input_0 primals_4 = input_1 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
achrefjarray/ESRGANplus-master
ModulatedConv2d
false
1,374
[ "Apache-2.0" ]
0
ba470ec5c565a6dc8b48575b1e185ef6b796aec6
https://github.com/achrefjarray/ESRGANplus-master/tree/ba470ec5c565a6dc8b48575b1e185ef6b796aec6
ToRGB
from torch.autograd import Function import math import torch import torch.utils.data from torch.nn import functional as F from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg from torch import autograd as autograd def pad(pad_type, padding): pad_type = pad_type.lower() if padding == 0: return None if pad_type == 'reflect': layer = nn.ReflectionPad2d(padding) elif pad_type == 'replicate': layer = nn.ReplicationPad2d(padding) else: raise NotImplementedError('padding layer [{:s}] is not implemented' .format(pad_type)) return layer 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 import torch.utils.data from torch.nn import functional as F from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg 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=128, 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 pad(pad_type, padding): pad_type = pad_type.lower() if padding == 0: return None if pad_type == 'reflect': layer = nn.ReflectionPad2d(padding) elif pad_type == 'replicate': layer = nn.ReplicationPad2d(padding) else: raise NotImplementedError('padding layer [{:s}] is not implemented' .format(pad_type)) return layer 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]
achrefjarray/ESRGANplus-master
ToRGB
false
1,375
[ "Apache-2.0" ]
0
ba470ec5c565a6dc8b48575b1e185ef6b796aec6
https://github.com/achrefjarray/ESRGANplus-master/tree/ba470ec5c565a6dc8b48575b1e185ef6b796aec6
HighwayLayer
import torch import torch.nn as nn import torch.utils.data import torch.utils.data.distributed def my_xavier_init(m, gain=1): """Xavier initialization: weights initialization that tries to make variance of outputs of a layer equal to variance of its inputs. """ for p in m.parameters(): if p.dim() > 1: nn.init.xavier_uniform_(p, gain) else: nn.init.constant_(p, 0) class HighwayLayer(torch.nn.Module): """Highway transformation used in span prediction.""" def __init__(self, dim): super(HighwayLayer, self).__init__() self.gate_proj = nn.Linear(dim, dim, bias=True) self.nlin_proj = nn.Linear(dim, dim, bias=True) my_xavier_init(self.nlin_proj) my_xavier_init(self.gate_proj) nn.init.constant_(self.gate_proj.bias, -1) def forward(self, x): gate = torch.sigmoid(self.gate_proj(x)) nlin = torch.tanh(self.nlin_proj(x)) res = gate * nlin + (1 - gate) * x return res def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'dim': 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.utils.data import torch.utils.data.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_add_mul_rsub_sigmoid_tanh_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 tmp0 = tl.load(in_ptr0 + x0, xmask) tmp2 = tl.load(in_ptr1 + x0, xmask) tmp7 = tl.load(in_ptr2 + x0, xmask) tmp1 = tl.sigmoid(tmp0) tmp3 = libdevice.tanh(tmp2) tmp4 = tmp1 * tmp3 tmp5 = 1.0 tmp6 = tmp5 - tmp1 tmp8 = tmp6 * tmp7 tmp9 = tmp4 + tmp8 tl.store(out_ptr0 + x0, tmp9, 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, 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,)) 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((64, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_5, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0 ), alpha=1, beta=1, out=buf1) del primals_4 del primals_5 buf2 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_add_mul_rsub_sigmoid_tanh_0[grid(256)](buf0, buf1, primals_3, buf2, 256, XBLOCK=128, num_warps=4, num_stages=1) return buf2, primals_3, buf0, buf1 def my_xavier_init(m, gain=1): """Xavier initialization: weights initialization that tries to make variance of outputs of a layer equal to variance of its inputs. """ for p in m.parameters(): if p.dim() > 1: nn.init.xavier_uniform_(p, gain) else: nn.init.constant_(p, 0) class HighwayLayerNew(torch.nn.Module): """Highway transformation used in span prediction.""" def __init__(self, dim): super(HighwayLayerNew, self).__init__() self.gate_proj = nn.Linear(dim, dim, bias=True) self.nlin_proj = nn.Linear(dim, dim, bias=True) my_xavier_init(self.nlin_proj) my_xavier_init(self.gate_proj) nn.init.constant_(self.gate_proj.bias, -1) def forward(self, input_0): primals_1 = self.gate_proj.weight primals_2 = self.gate_proj.bias primals_4 = self.nlin_proj.weight primals_5 = self.nlin_proj.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
adamlerer/droidlet
HighwayLayer
false
1,376
[ "MIT" ]
0
ada38d191dadcea9aba12330e35e8e7d6d1663d9
https://github.com/adamlerer/droidlet/tree/ada38d191dadcea9aba12330e35e8e7d6d1663d9
GramMatrix
import torch import torch.nn as nn import torch.onnx class GramMatrix(nn.Module): def forward(self, input): a, b, c, d = input.size() features = input.view(a, b, c * d) G = torch.matmul(features, torch.transpose(features, 1, 2)) return G.div(a * b * c * d) def get_inputs(): return [torch.rand([4, 4, 4, 4])] 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 as nn import torch.onnx 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_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_out_ptr0 + x0, xmask) tmp1 = 0.00390625 tmp2 = tmp0 * tmp1 tl.store(in_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), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(arg0_1, (4, 4, 16), (64, 16, 1), 0), reinterpret_tensor(arg0_1, (4, 16, 4), (64, 1, 16), 0), out=buf0) del arg0_1 buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_div_0[grid(64)](buf1, 64, XBLOCK=64, num_warps=1, num_stages=1) return buf1, class GramMatrixNew(nn.Module): def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
adi-horowitz/final-project
GramMatrix
false
1,377
[ "MIT" ]
0
0fd864663e92a6bcaa5f068e3e45b2a76460d335
https://github.com/adi-horowitz/final-project/tree/0fd864663e92a6bcaa5f068e3e45b2a76460d335
MDN
import torch import torch.nn as nn import torch.nn.functional as F class MDN(nn.Module): def __init__(self, input_size, hidden_size, output_size, batch_size): super(MDN, self).__init__() self.hidden_size = hidden_size self.batch_size = batch_size self.z_h = nn.Linear(input_size, hidden_size) self.z_pi = nn.Linear(hidden_size, output_size) self.z_mu = nn.Linear(hidden_size, output_size) self.z_sig = nn.Linear(hidden_size, output_size) def forward(self, inp): z_h = F.tanh(self.z_h(inp)) pi = F.softmax(self.z_pi(z_h)) mu = self.z_mu(z_h) sig = torch.exp(self.z_sig(z_h)) return pi, sig, mu def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'input_size': 4, 'hidden_size': 4, 'output_size': 4, 'batch_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 libdevice, 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 reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor @triton.jit def triton_poi_fused_tanh_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 = libdevice.tanh(tmp2) tl.store(in_out_ptr0 + x2, tmp3, 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 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__softmax_2(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 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused_exp_3(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_math.exp(tmp2) tl.store(in_out_ptr0 + x2, tmp3, 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,), (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,)) 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 get_raw_stream(0) triton_poi_fused_tanh_0[grid(256)](buf1, primals_2, 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, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused__softmax_1[grid(256)](buf2, buf3, 256, XBLOCK=256, num_warps=4, num_stages=1) buf4 = reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf2 triton_poi_fused__softmax_2[grid(256)](buf3, buf4, 256, XBLOCK=256, num_warps=4, num_stages=1) buf5 = reinterpret_tensor(buf3, (64, 4), (4, 1), 0) del buf3 extern_kernels.addmm(primals_7, reinterpret_tensor(buf1, (64, 4), ( 4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf5) del primals_7 buf6 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_8, (4, 4), (1, 4), 0), out=buf6) buf7 = reinterpret_tensor(buf6, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf6 triton_poi_fused_exp_3[grid(256)](buf7, primals_9, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_9 return buf4, buf7, reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0 ), reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), buf1, buf4, buf7, primals_8, primals_6, primals_4 class MDNNew(nn.Module): def __init__(self, input_size, hidden_size, output_size, batch_size): super(MDNNew, self).__init__() self.hidden_size = hidden_size self.batch_size = batch_size self.z_h = nn.Linear(input_size, hidden_size) self.z_pi = nn.Linear(hidden_size, output_size) self.z_mu = nn.Linear(hidden_size, output_size) self.z_sig = nn.Linear(hidden_size, output_size) def forward(self, input_0): primals_1 = self.z_h.weight primals_2 = self.z_h.bias primals_4 = self.z_pi.weight primals_5 = self.z_pi.bias primals_6 = self.z_mu.weight primals_7 = self.z_mu.bias primals_8 = self.z_sig.weight primals_9 = self.z_sig.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], output[1], output[2]
adelaunay3/DL-Seq2Seq
MDN
false
1,378
[ "MIT" ]
0
7b83e2501b26780ff2dec140ac15a6664699dc16
https://github.com/adelaunay3/DL-Seq2Seq/tree/7b83e2501b26780ff2dec140ac15a6664699dc16
ConvReLUNorm
import torch import torch.cuda import torch.distributed import torch.optim class ConvReLUNorm(torch.nn.Module): def __init__(self, in_channels, out_channels, kernel_size=1, dropout=0.0): super(ConvReLUNorm, self).__init__() self.conv = torch.nn.Conv1d(in_channels, out_channels, kernel_size= kernel_size, padding=kernel_size // 2) self.norm = torch.nn.LayerNorm(out_channels) self.dropout = torch.nn.Dropout(dropout) def forward(self, signal): out = torch.nn.functional.relu(self.conv(signal)) out = self.norm(out.transpose(1, 2)).transpose(1, 2) return self.dropout(out) def get_inputs(): return [torch.rand([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._inductor.runtime import triton_helpers from torch._inductor.runtime.triton_helpers import libdevice import torch.cuda import torch.distributed import torch.optim 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_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) @triton.jit def triton_poi_fused_native_layer_norm_1(in_ptr0, 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 % 4 x1 = xindex // 4 x2 = xindex tmp0 = tl.load(in_ptr0 + (x0 + 16 * x1), xmask) tmp3 = tl.load(in_ptr0 + (4 + x0 + 16 * x1), xmask) tmp6 = tl.load(in_ptr0 + (8 + x0 + 16 * x1), xmask) tmp9 = tl.load(in_ptr0 + (12 + x0 + 16 * x1), xmask) tmp1 = tl.full([1], 0, tl.int32) tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = triton_helpers.maximum(tmp1, tmp3) tmp5 = tmp2 + tmp4 tmp7 = triton_helpers.maximum(tmp1, tmp6) tmp8 = tmp5 + tmp7 tmp10 = triton_helpers.maximum(tmp1, tmp9) tmp11 = tmp8 + tmp10 tmp12 = 4.0 tmp13 = tmp11 / tmp12 tmp14 = tmp2 - tmp13 tmp15 = tmp14 * tmp14 tmp16 = tmp4 - tmp13 tmp17 = tmp16 * tmp16 tmp18 = tmp15 + tmp17 tmp19 = tmp7 - tmp13 tmp20 = tmp19 * tmp19 tmp21 = tmp18 + tmp20 tmp22 = tmp10 - tmp13 tmp23 = tmp22 * tmp22 tmp24 = tmp21 + tmp23 tmp25 = tmp24 / tmp12 tmp26 = 1e-05 tmp27 = tmp25 + tmp26 tmp28 = libdevice.rsqrt(tmp27) tl.store(out_ptr0 + x2, tmp13, xmask) tl.store(out_ptr1 + x2, tmp28, xmask) @triton.jit def triton_poi_fused_native_layer_norm_2(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, 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') tmp3 = tl.load(in_ptr1 + y3, ymask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr2 + y3, ymask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr3 + x2, xmask, eviction_policy='evict_last') tmp9 = tl.load(in_ptr4 + x2, xmask, eviction_policy='evict_last') tmp1 = tl.full([1, 1], 0, tl.int32) tmp2 = triton_helpers.maximum(tmp1, tmp0) tmp4 = tmp2 - tmp3 tmp6 = tmp4 * tmp5 tmp8 = tmp6 * tmp7 tmp10 = tmp8 + tmp9 tl.store(out_ptr0 + (x2 + 4 * y3), tmp10, xmask & ymask) def call(args): primals_1, primals_2, primals_3, primals_4, primals_5 = args args.clear() assert_size_stride(primals_1, (4, 4, 1), (4, 1, 1)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_4, (4,), (1,)) assert_size_stride(primals_5, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = extern_kernels.convolution(primals_3, primals_1, stride=(1,), padding=(0,), dilation=(1,), transposed=False, output_padding=( 0,), groups=1, bias=None) assert_size_stride(buf0, (4, 4, 4), (16, 4, 1)) buf1 = buf0 del buf0 get_raw_stream(0) triton_poi_fused_convolution_0[grid(64)](buf1, primals_2, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_2 buf2 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) buf3 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) triton_poi_fused_native_layer_norm_1[grid(16)](buf1, buf2, buf3, 16, XBLOCK=16, num_warps=1, num_stages=1) buf4 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_native_layer_norm_2[grid(16, 4)](buf1, buf2, buf3, primals_4, primals_5, buf4, 16, 4, XBLOCK=4, YBLOCK=16, num_warps=1, num_stages=1) del buf2 del buf3 del primals_5 return reinterpret_tensor(buf4, (4, 4, 4), (16, 1, 4), 0 ), primals_1, primals_3, primals_4, buf1 class ConvReLUNormNew(torch.nn.Module): def __init__(self, in_channels, out_channels, kernel_size=1, dropout=0.0): super(ConvReLUNormNew, self).__init__() self.conv = torch.nn.Conv1d(in_channels, out_channels, kernel_size= kernel_size, padding=kernel_size // 2) self.norm = torch.nn.LayerNorm(out_channels) self.dropout = torch.nn.Dropout(dropout) def forward(self, input_0): primals_1 = self.conv.weight primals_2 = self.conv.bias primals_4 = self.norm.weight primals_5 = self.norm.bias primals_3 = input_0 output = call([primals_1, primals_2, primals_3, primals_4, primals_5]) return output[0]
admariner/NeMo
ConvReLUNorm
false
1,379
[ "Apache-2.0" ]
0
e542d7f9063a40afa4119a3b94de4c2c636a37bb
https://github.com/admariner/NeMo/tree/e542d7f9063a40afa4119a3b94de4c2c636a37bb
MultiHeadDense
import math import torch import torch.nn as nn class MultiHeadDense(nn.Module): def __init__(self, d): super(MultiHeadDense, self).__init__() self.weight = nn.Parameter(torch.Tensor(d, d)) self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self) ->None: nn.init.kaiming_uniform_(self.weight, a=math.sqrt(5)) def forward(self, x): b, _wh, _d = x.size() x = torch.bmm(x, self.weight.repeat(b, 1, 1)) return x def get_inputs(): return [torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'d': 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_repeat_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 % 16 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 = args args.clear() assert_size_stride(primals_1, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_2, (4, 4), (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_repeat_0[grid(64)](primals_2, buf0, 64, XBLOCK=64, num_warps=1, num_stages=1) del primals_2 buf1 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(primals_1, buf0, out=buf1) del buf0 return buf1, reinterpret_tensor(primals_1, (4, 4, 4), (16, 1, 4), 0) class MultiHeadDenseNew(nn.Module): def __init__(self, d): super(MultiHeadDenseNew, self).__init__() self.weight = nn.Parameter(torch.Tensor(d, d)) self.register_parameter('bias', None) self.reset_parameters() def reset_parameters(self) ->None: nn.init.kaiming_uniform_(self.weight, a=math.sqrt(5)) def forward(self, input_0): primals_2 = self.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0]
afperezm/DeepGlobe-Road-Extraction-Challenge
MultiHeadDense
false
1,380
[ "MIT" ]
0
d3e0a8123d64baa3975663ece053edbc4bbdc4e6
https://github.com/afperezm/DeepGlobe-Road-Extraction-Challenge/tree/d3e0a8123d64baa3975663ece053edbc4bbdc4e6
EqualLinear
from torch.autograd import Function import math import torch import torch.utils.data from torch.nn import functional as F from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg 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 import torch.utils.data from torch.utils import data as data import torch.nn as nn from torch.nn import init as init from torchvision.models import vgg as vgg 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]
achrefjarray/ESRGANplus-master
EqualLinear
false
1,381
[ "Apache-2.0" ]
0
ba470ec5c565a6dc8b48575b1e185ef6b796aec6
https://github.com/achrefjarray/ESRGANplus-master/tree/ba470ec5c565a6dc8b48575b1e185ef6b796aec6
GlobalMaxPool1d
import torch from torch import nn class GlobalMaxPool1d(nn.Module): """Performs global max pooling over the entire length of a batched 1D tensor # Arguments input: Input tensor """ def forward(self, input): return nn.functional.max_pool1d(input, kernel_size=input.size()[2:] ).view(-1, input.size(1)) def get_inputs(): return [torch.rand([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 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_max_pool2d_with_indices_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') 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), (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) get_raw_stream(0) triton_poi_fused_max_pool2d_with_indices_0[grid(16)](arg0_1, buf0, 16, XBLOCK=16, num_warps=1, num_stages=1) del arg0_1 return reinterpret_tensor(buf0, (4, 4), (4, 1), 0), class GlobalMaxPool1dNew(nn.Module): """Performs global max pooling over the entire length of a batched 1D tensor # Arguments input: Input tensor """ def forward(self, input_0): arg0_1 = input_0 output = call([arg0_1]) return output[0]
aiswaryasankar/Few_shot_exp
GlobalMaxPool1d
false
1,382
[ "MIT" ]
0
21c5a5d93dc69715b037a0fd2dca1b6f7d9de773
https://github.com/aiswaryasankar/Few_shot_exp/tree/21c5a5d93dc69715b037a0fd2dca1b6f7d9de773
VectorQuantizer
import torch from torch import Tensor from torch import nn from torch.nn import functional as F class VectorQuantizer(nn.Module): """ Reference: [1] https://github.com/deepmind/sonnet/blob/v2/sonnet/src/nets/vqvae.py """ def __init__(self, num_embeddings: 'int', embedding_dim: 'int', beta: 'float'=0.25): super(VectorQuantizer, self).__init__() self.K = num_embeddings self.D = embedding_dim self.beta = beta self.embedding = nn.Embedding(self.K, self.D) self.embedding.weight.data.uniform_(-1 / self.K, 1 / self.K) def forward(self, latents: 'Tensor') ->Tensor: latents = latents.permute(0, 2, 3, 1).contiguous() latents_shape = latents.shape flat_latents = latents.view(-1, self.D) dist = torch.sum(flat_latents ** 2, dim=1, keepdim=True) + torch.sum( self.embedding.weight ** 2, dim=1) - 2 * torch.matmul(flat_latents, self.embedding.weight.t()) encoding_inds = torch.argmin(dist, dim=1).unsqueeze(1) device = latents.device encoding_one_hot = torch.zeros(encoding_inds.size(0), self.K, device=device) encoding_one_hot.scatter_(1, encoding_inds, 1) quantized_latents = torch.matmul(encoding_one_hot, self.embedding. weight) quantized_latents = quantized_latents.view(latents_shape) commitment_loss = F.mse_loss(quantized_latents.detach(), latents) embedding_loss = F.mse_loss(quantized_latents, latents.detach()) vq_loss = commitment_loss * self.beta + embedding_loss quantized_latents = latents + (quantized_latents - latents).detach() return quantized_latents.permute(0, 3, 1, 2).contiguous(), vq_loss def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_embeddings': 4, 'embedding_dim': 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_clone_view_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 x1 = xindex y0 = yindex tmp0 = tl.load(in_ptr0 + (16 * x1 + 64 * (y0 // 16) + y0 % 16), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x1 + 4 * y0), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_add_mul_pow_sub_sum_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 x1 = xindex // 4 x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp13 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp19 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp23 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tmp0 * tmp0 tmp3 = tmp2 * tmp2 tmp4 = tmp1 + tmp3 tmp6 = tmp5 * tmp5 tmp7 = tmp4 + tmp6 tmp9 = tmp8 * tmp8 tmp10 = tmp7 + tmp9 tmp12 = tmp11 * tmp11 tmp14 = tmp13 * tmp13 tmp15 = tmp12 + tmp14 tmp17 = tmp16 * tmp16 tmp18 = tmp15 + tmp17 tmp20 = tmp19 * tmp19 tmp21 = tmp18 + tmp20 tmp22 = tmp10 + tmp21 tmp24 = 2.0 tmp25 = tmp23 * tmp24 tmp26 = tmp22 - tmp25 tl.store(in_out_ptr0 + x2, tmp26, xmask) @triton.jit def triton_poi_fused_argmin_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 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') tmp17 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp32 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 < tmp1 tmp3 = tmp0 == tmp1 tmp4 = tmp0 != tmp0 tmp5 = tmp1 != tmp1 tmp6 = tmp4 > tmp5 tmp7 = tmp2 | tmp6 tmp8 = tmp4 & tmp5 tmp9 = tmp3 | tmp8 tmp10 = tl.full([1], 0, tl.int64) tmp11 = tl.full([1], 1, tl.int64) tmp12 = tmp10 < tmp11 tmp13 = tmp9 & tmp12 tmp14 = tmp7 | tmp13 tmp15 = tl.where(tmp14, tmp0, tmp1) tmp16 = tl.where(tmp14, tmp10, tmp11) tmp18 = tmp15 < tmp17 tmp19 = tmp15 == tmp17 tmp20 = tmp15 != tmp15 tmp21 = tmp17 != tmp17 tmp22 = tmp20 > tmp21 tmp23 = tmp18 | tmp22 tmp24 = tmp20 & tmp21 tmp25 = tmp19 | tmp24 tmp26 = tl.full([1], 2, tl.int64) tmp27 = tmp16 < tmp26 tmp28 = tmp25 & tmp27 tmp29 = tmp23 | tmp28 tmp30 = tl.where(tmp29, tmp15, tmp17) tmp31 = tl.where(tmp29, tmp16, tmp26) tmp33 = tmp30 < tmp32 tmp34 = tmp30 == tmp32 tmp35 = tmp30 != tmp30 tmp36 = tmp32 != tmp32 tmp37 = tmp35 > tmp36 tmp38 = tmp33 | tmp37 tmp39 = tmp35 & tmp36 tmp40 = tmp34 | tmp39 tmp41 = tl.full([1], 3, tl.int64) tmp42 = tmp31 < tmp41 tmp43 = tmp40 & tmp42 tmp44 = tmp38 | tmp43 tl.where(tmp44, tmp30, tmp32) tmp46 = tl.where(tmp44, tmp31, tmp41) tl.store(out_ptr0 + x0, tmp46, xmask) @triton.jit def triton_poi_fused_scatter_3(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 x1 = xindex // 4 x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp1 = x0 tmp2 = tmp0 == tmp1 tmp3 = 1.0 tmp4 = 0.0 tmp5 = tl.where(tmp2, tmp3, tmp4) tl.store(out_ptr0 + x2, tmp5, xmask) @triton.jit def triton_per_fused_add_clone_mse_loss_mul_4(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) r3 = rindex r0 = rindex % 4 r1 = rindex // 4 % 16 r2 = rindex // 64 tmp0 = tl.load(in_ptr0 + r3, None) tmp1 = tl.load(in_ptr1 + (r1 + 16 * r0 + 64 * r2), None, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp3 = tmp2 * tmp2 tmp4 = tl.broadcast_to(tmp3, [RBLOCK]) tmp6 = triton_helpers.promote_to_tensor(tl.sum(tmp4, 0)) tmp7 = 256.0 tmp8 = tmp6 / tmp7 tmp9 = 0.25 tmp10 = tmp8 * tmp9 tmp11 = tmp10 + tmp8 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp11, None) @triton.jit def triton_poi_fused_clone_5(in_ptr0, in_ptr1, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 16 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 y3 = yindex y0 = yindex % 4 y1 = yindex // 4 tmp0 = tl.load(in_ptr0 + (x2 + 16 * y3), xmask & ymask) tmp1 = tl.load(in_ptr1 + (y0 + 4 * x2 + 64 * y1), xmask & ymask) tmp2 = tmp1 - tmp0 tmp3 = tmp0 + tmp2 tl.store(out_ptr0 + (x2 + 16 * y3), tmp3, xmask & ymask) @triton.jit def triton_poi_fused_clone_mse_loss_mse_loss_backward_6(in_out_ptr0, in_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 x2 = xindex y3 = yindex y0 = yindex % 16 y1 = yindex // 16 tmp0 = tl.load(in_out_ptr0 + (x2 + 4 * y3), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (y0 + 16 * x2 + 64 * y1), xmask & ymask, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp3 = 0.0078125 tmp4 = tmp2 * tmp3 tl.debug_barrier() tl.store(in_out_ptr0 + (x2 + 4 * y3), tmp4, xmask & ymask) 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, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_view_0[grid(64, 4)](primals_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_2, (4, 4), (1, 4 ), 0), out=buf1) buf2 = buf1 del buf1 triton_poi_fused_add_mul_pow_sub_sum_1[grid(256)](buf2, buf0, primals_2, 256, XBLOCK=256, num_warps=4, num_stages=1) buf3 = empty_strided_cuda((64,), (1,), torch.int64) triton_poi_fused_argmin_2[grid(64)](buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = buf2 del buf2 triton_poi_fused_scatter_3[grid(256)](buf3, buf4, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf3 buf5 = buf0 del buf0 extern_kernels.mm(buf4, primals_2, out=buf5) del primals_2 buf6 = empty_strided_cuda((), (), torch.float32) buf9 = buf6 del buf6 triton_per_fused_add_clone_mse_loss_mul_4[grid(1)](buf9, buf5, primals_1, 1, 256, num_warps=2, num_stages=1) buf7 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_clone_5[grid(16, 16)](primals_1, buf5, buf7, 16, 16, XBLOCK=16, YBLOCK=16, num_warps=4, num_stages=1) buf8 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused_clone_mse_loss_mse_loss_backward_6[grid(64, 4)](buf8, primals_1, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) del primals_1 return buf7, buf9, buf8, reinterpret_tensor(buf4, (4, 64), (1, 4), 0) class VectorQuantizerNew(nn.Module): """ Reference: [1] https://github.com/deepmind/sonnet/blob/v2/sonnet/src/nets/vqvae.py """ def __init__(self, num_embeddings: 'int', embedding_dim: 'int', beta: 'float'=0.25): super(VectorQuantizerNew, self).__init__() self.K = num_embeddings self.D = embedding_dim self.beta = beta self.embedding = nn.Embedding(self.K, self.D) self.embedding.weight.data.uniform_(-1 / self.K, 1 / self.K) def forward(self, input_0): primals_2 = self.embedding.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0], output[1]
adammoss/vae
VectorQuantizer
false
1,383
[ "Apache-2.0" ]
0
52f0f56492e3ac7c8b866ae99d5333b4281a371f
https://github.com/adammoss/vae/tree/52f0f56492e3ac7c8b866ae99d5333b4281a371f
VectorQuantizer
import torch import torch.nn as nn import torch.nn.functional as F class VectorQuantizer(nn.Module): def __init__(self, num_embeddings, embedding_dim, commitment_cost): super(VectorQuantizer, self).__init__() self._embedding_dim = embedding_dim self._num_embeddings = num_embeddings self._embedding = nn.Embedding(self._num_embeddings, self. _embedding_dim) self._embedding.weight.data.uniform_(-1 / self._num_embeddings, 1 / self._num_embeddings) self._commitment_cost = commitment_cost def forward(self, inputs): inputs = inputs.permute(0, 2, 3, 1).contiguous() input_shape = inputs.shape flat_input = inputs.view(-1, self._embedding_dim) distances = torch.sum(flat_input ** 2, dim=1, keepdim=True ) + torch.sum(self._embedding.weight ** 2, dim=1 ) - 2 * torch.matmul(flat_input, self._embedding.weight.t()) encoding_indices = torch.argmin(distances, dim=1).unsqueeze(1) encodings = torch.zeros(encoding_indices.shape[0], self. _num_embeddings, device=inputs.device) encodings.scatter_(1, encoding_indices, 1) quantized = torch.matmul(encodings, self._embedding.weight).view( input_shape) e_latent_loss = F.mse_loss(quantized.detach(), inputs) q_latent_loss = F.mse_loss(quantized, inputs.detach()) loss = q_latent_loss + self._commitment_cost * e_latent_loss quantized = inputs + (quantized - inputs).detach() avg_probs = torch.mean(encodings, dim=0) perplexity = torch.exp(-torch.sum(avg_probs * torch.log(avg_probs + 1e-10))) return loss, quantized.permute(0, 3, 1, 2).contiguous( ), perplexity, encodings def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'num_embeddings': 4, 'embedding_dim': 4, 'commitment_cost': 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 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_view_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 x1 = xindex y0 = yindex tmp0 = tl.load(in_ptr0 + (16 * x1 + 64 * (y0 // 16) + y0 % 16), xmask & ymask, eviction_policy='evict_last') tl.store(out_ptr0 + (x1 + 4 * y0), tmp0, xmask & ymask) @triton.jit def triton_poi_fused_add_mul_pow_sub_sum_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 x1 = xindex // 4 x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + 4 * x1, xmask, eviction_policy='evict_last') tmp2 = tl.load(in_ptr0 + (1 + 4 * x1), xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr0 + (2 + 4 * x1), xmask, eviction_policy='evict_last') tmp8 = tl.load(in_ptr0 + (3 + 4 * x1), xmask, eviction_policy='evict_last') tmp11 = tl.load(in_ptr1 + 4 * x0, xmask, eviction_policy='evict_last') tmp13 = tl.load(in_ptr1 + (1 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp16 = tl.load(in_ptr1 + (2 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp19 = tl.load(in_ptr1 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp23 = tl.load(in_out_ptr0 + x2, xmask) tmp1 = tmp0 * tmp0 tmp3 = tmp2 * tmp2 tmp4 = tmp1 + tmp3 tmp6 = tmp5 * tmp5 tmp7 = tmp4 + tmp6 tmp9 = tmp8 * tmp8 tmp10 = tmp7 + tmp9 tmp12 = tmp11 * tmp11 tmp14 = tmp13 * tmp13 tmp15 = tmp12 + tmp14 tmp17 = tmp16 * tmp16 tmp18 = tmp15 + tmp17 tmp20 = tmp19 * tmp19 tmp21 = tmp18 + tmp20 tmp22 = tmp10 + tmp21 tmp24 = 2.0 tmp25 = tmp23 * tmp24 tmp26 = tmp22 - tmp25 tl.store(in_out_ptr0 + x2, tmp26, xmask) @triton.jit def triton_poi_fused_argmin_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 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') tmp17 = tl.load(in_ptr0 + (2 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp32 = tl.load(in_ptr0 + (3 + 4 * x0), xmask, eviction_policy='evict_last' ) tmp2 = tmp0 < tmp1 tmp3 = tmp0 == tmp1 tmp4 = tmp0 != tmp0 tmp5 = tmp1 != tmp1 tmp6 = tmp4 > tmp5 tmp7 = tmp2 | tmp6 tmp8 = tmp4 & tmp5 tmp9 = tmp3 | tmp8 tmp10 = tl.full([1], 0, tl.int64) tmp11 = tl.full([1], 1, tl.int64) tmp12 = tmp10 < tmp11 tmp13 = tmp9 & tmp12 tmp14 = tmp7 | tmp13 tmp15 = tl.where(tmp14, tmp0, tmp1) tmp16 = tl.where(tmp14, tmp10, tmp11) tmp18 = tmp15 < tmp17 tmp19 = tmp15 == tmp17 tmp20 = tmp15 != tmp15 tmp21 = tmp17 != tmp17 tmp22 = tmp20 > tmp21 tmp23 = tmp18 | tmp22 tmp24 = tmp20 & tmp21 tmp25 = tmp19 | tmp24 tmp26 = tl.full([1], 2, tl.int64) tmp27 = tmp16 < tmp26 tmp28 = tmp25 & tmp27 tmp29 = tmp23 | tmp28 tmp30 = tl.where(tmp29, tmp15, tmp17) tmp31 = tl.where(tmp29, tmp16, tmp26) tmp33 = tmp30 < tmp32 tmp34 = tmp30 == tmp32 tmp35 = tmp30 != tmp30 tmp36 = tmp32 != tmp32 tmp37 = tmp35 > tmp36 tmp38 = tmp33 | tmp37 tmp39 = tmp35 & tmp36 tmp40 = tmp34 | tmp39 tmp41 = tl.full([1], 3, tl.int64) tmp42 = tmp31 < tmp41 tmp43 = tmp40 & tmp42 tmp44 = tmp38 | tmp43 tl.where(tmp44, tmp30, tmp32) tmp46 = tl.where(tmp44, tmp31, tmp41) tl.store(out_ptr0 + x0, tmp46, xmask) @triton.jit def triton_poi_fused_scatter_3(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 x1 = xindex // 4 x0 = xindex % 4 x2 = xindex tmp0 = tl.load(in_ptr0 + x1, xmask, eviction_policy='evict_last') tmp1 = x0 tmp2 = tmp0 == tmp1 tmp3 = 1.0 tmp4 = 0.0 tmp5 = tl.where(tmp2, tmp3, tmp4) tl.store(out_ptr0 + x2, tmp5, xmask) @triton.jit def triton_per_fused_add_clone_mse_loss_mul_4(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) r3 = rindex r0 = rindex % 4 r1 = rindex // 4 % 16 r2 = rindex // 64 tmp0 = tl.load(in_ptr0 + r3, None) tmp1 = tl.load(in_ptr1 + (r1 + 16 * r0 + 64 * r2), None, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp3 = tmp2 * tmp2 tmp4 = tl.broadcast_to(tmp3, [RBLOCK]) tmp6 = triton_helpers.promote_to_tensor(tl.sum(tmp4, 0)) tmp7 = 256.0 tmp8 = tmp6 / tmp7 tmp9 = 4.0 tmp10 = tmp8 * tmp9 tmp11 = tmp8 + tmp10 tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([1], 0, tl.int32), tmp11, None) @triton.jit def triton_per_fused_mean_5(in_ptr0, out_ptr0, xnumel, rnumel, XBLOCK: tl. constexpr): xnumel = 4 RBLOCK: tl.constexpr = 64 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 + (x0 + 4 * r1), xmask, other=0.0) tmp1 = tl.broadcast_to(tmp0, [XBLOCK, RBLOCK]) tmp3 = tl.where(xmask, tmp1, 0) tmp4 = tl.sum(tmp3, 1)[:, None] tl.store(out_ptr0 + x0, tmp4, xmask) @triton.jit def triton_per_fused_add_exp_log_mean_mul_neg_sum_6(in_out_ptr0, in_ptr0, xnumel, rnumel, XBLOCK: tl.constexpr): RBLOCK: tl.constexpr = 4 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 = 64.0 tmp2 = tmp0 / tmp1 tmp3 = 1e-10 tmp4 = tmp2 + tmp3 tmp5 = tl_math.log(tmp4) tmp6 = tmp2 * tmp5 tmp7 = tl.broadcast_to(tmp6, [XBLOCK, RBLOCK]) tmp9 = tl.sum(tmp7, 1)[:, None] tmp10 = -tmp9 tmp11 = tl_math.exp(tmp10) tl.debug_barrier() tl.store(in_out_ptr0 + tl.full([XBLOCK, 1], 0, tl.int32), tmp11, None) @triton.jit def triton_poi_fused_clone_7(in_ptr0, in_ptr1, out_ptr0, ynumel, xnumel, YBLOCK: tl.constexpr, XBLOCK: tl.constexpr): ynumel = 16 xnumel = 16 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 y3 = yindex y0 = yindex % 4 y1 = yindex // 4 tmp0 = tl.load(in_ptr0 + (x2 + 16 * y3), xmask & ymask) tmp1 = tl.load(in_ptr1 + (y0 + 4 * x2 + 64 * y1), xmask & ymask) tmp2 = tmp1 - tmp0 tmp3 = tmp0 + tmp2 tl.store(out_ptr0 + (x2 + 16 * y3), tmp3, xmask & ymask) @triton.jit def triton_poi_fused_clone_mse_loss_mse_loss_backward_8(in_out_ptr0, in_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 x2 = xindex y3 = yindex y0 = yindex % 16 y1 = yindex // 16 tmp0 = tl.load(in_out_ptr0 + (x2 + 4 * y3), xmask & ymask, eviction_policy='evict_last') tmp1 = tl.load(in_ptr0 + (y0 + 16 * x2 + 64 * y1), xmask & ymask, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp3 = 0.0078125 tmp4 = tmp2 * tmp3 tl.debug_barrier() tl.store(in_out_ptr0 + (x2 + 4 * y3), tmp4, xmask & ymask) 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, (4, 4), (4, 1)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((64, 4), (4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_clone_view_0[grid(64, 4)](primals_1, buf0, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) buf1 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(buf0, reinterpret_tensor(primals_2, (4, 4), (1, 4 ), 0), out=buf1) buf2 = buf1 del buf1 triton_poi_fused_add_mul_pow_sub_sum_1[grid(256)](buf2, buf0, primals_2, 256, XBLOCK=256, num_warps=4, num_stages=1) buf3 = empty_strided_cuda((64,), (1,), torch.int64) triton_poi_fused_argmin_2[grid(64)](buf2, buf3, 64, XBLOCK=64, num_warps=1, num_stages=1) buf4 = buf2 del buf2 triton_poi_fused_scatter_3[grid(256)](buf3, buf4, 256, XBLOCK=256, num_warps=4, num_stages=1) del buf3 buf5 = buf0 del buf0 extern_kernels.mm(buf4, primals_2, out=buf5) del primals_2 buf6 = empty_strided_cuda((), (), torch.float32) buf11 = buf6 del buf6 triton_per_fused_add_clone_mse_loss_mul_4[grid(1)](buf11, buf5, primals_1, 1, 256, num_warps=2, num_stages=1) buf7 = empty_strided_cuda((4,), (1,), torch.float32) triton_per_fused_mean_5[grid(4)](buf4, buf7, 4, 64, XBLOCK=1, num_warps=2, num_stages=1) buf8 = empty_strided_cuda((), (), torch.float32) buf12 = buf8 del buf8 triton_per_fused_add_exp_log_mean_mul_neg_sum_6[grid(1)](buf12, buf7, 1, 4, XBLOCK=1, num_warps=2, num_stages=1) del buf7 buf9 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.float32) triton_poi_fused_clone_7[grid(16, 16)](primals_1, buf5, buf9, 16, 16, XBLOCK=16, YBLOCK=16, num_warps=4, num_stages=1) buf10 = reinterpret_tensor(buf5, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf5 triton_poi_fused_clone_mse_loss_mse_loss_backward_8[grid(64, 4)](buf10, primals_1, 64, 4, XBLOCK=4, YBLOCK=32, num_warps=4, num_stages=1) del primals_1 return buf11, buf9, buf12, buf4, buf10, reinterpret_tensor(buf4, (4, 64 ), (1, 4), 0) class VectorQuantizerNew(nn.Module): def __init__(self, num_embeddings, embedding_dim, commitment_cost): super(VectorQuantizerNew, self).__init__() self._embedding_dim = embedding_dim self._num_embeddings = num_embeddings self._embedding = nn.Embedding(self._num_embeddings, self. _embedding_dim) self._embedding.weight.data.uniform_(-1 / self._num_embeddings, 1 / self._num_embeddings) self._commitment_cost = commitment_cost def forward(self, input_0): primals_2 = self._embedding.weight primals_1 = input_0 output = call([primals_1, primals_2]) return output[0], output[1], output[2], output[3]
acyclics/neurips2020-procgen-starter-kit
VectorQuantizer
false
1,384
[ "Apache-2.0" ]
0
16d52eb72d41c6b808c20644501710842134add4
https://github.com/acyclics/neurips2020-procgen-starter-kit/tree/16d52eb72d41c6b808c20644501710842134add4
ANN
import torch import torch.nn as nn import torch.nn.functional as F class ANN(nn.Module): def __init__(self, n_li, n_l1, n_l2, n_l3, n_lo): super(ANN, self).__init__() self.lin_in = nn.Linear(n_li, n_l1) self.lin_h1 = nn.Linear(n_l1, n_l2) self.lin_h2 = nn.Linear(n_l2, n_l3) self.lin_out = nn.Linear(n_l3, n_lo) def forward(self, inputs): out = F.relu(self.lin_in(inputs)) out = F.relu(self.lin_h1(out)) out = F.relu(self.lin_h2(out)) out = F.sigmoid(self.lin_out(out)) return out def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'n_li': 4, 'n_l1': 4, 'n_l2': 4, 'n_l3': 4, 'n_lo': 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 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_sigmoid_1(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.sigmoid(tmp2) tl.store(in_out_ptr0 + x2, tmp3, 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,), (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,)) 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 buf10 = 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, buf10, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_2 buf2 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf1, (64, 4), (4, 1), 0), reinterpret_tensor(primals_4, (4, 4), (1, 4), 0), out=buf2) buf3 = reinterpret_tensor(buf2, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf2 buf9 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf3, primals_5, buf9, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_5 buf4 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf3, (64, 4), (4, 1), 0), reinterpret_tensor(primals_6, (4, 4), (1, 4), 0), out=buf4) buf5 = reinterpret_tensor(buf4, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf4 buf8 = empty_strided_cuda((4, 4, 4, 4), (64, 16, 4, 1), torch.bool) triton_poi_fused_relu_threshold_backward_0[grid(256)](buf5, primals_7, buf8, 256, XBLOCK=256, num_warps=4, num_stages=1) del primals_7 buf6 = empty_strided_cuda((64, 4), (4, 1), torch.float32) extern_kernels.mm(reinterpret_tensor(buf5, (64, 4), (4, 1), 0), reinterpret_tensor(primals_8, (4, 4), (1, 4), 0), out=buf6) buf7 = reinterpret_tensor(buf6, (4, 4, 4, 4), (64, 16, 4, 1), 0) del buf6 triton_poi_fused_sigmoid_1[grid(256)](buf7, primals_9, 256, XBLOCK= 128, num_warps=4, num_stages=1) del primals_9 return buf7, reinterpret_tensor(primals_3, (64, 4), (4, 1), 0 ), reinterpret_tensor(buf1, (64, 4), (4, 1), 0), reinterpret_tensor( buf3, (64, 4), (4, 1), 0), reinterpret_tensor(buf5, (64, 4), (4, 1), 0 ), buf7, primals_8, buf8, primals_6, buf9, primals_4, buf10 class ANNNew(nn.Module): def __init__(self, n_li, n_l1, n_l2, n_l3, n_lo): super(ANNNew, self).__init__() self.lin_in = nn.Linear(n_li, n_l1) self.lin_h1 = nn.Linear(n_l1, n_l2) self.lin_h2 = nn.Linear(n_l2, n_l3) self.lin_out = nn.Linear(n_l3, n_lo) def forward(self, input_0): primals_1 = self.lin_in.weight primals_2 = self.lin_in.bias primals_4 = self.lin_h1.weight primals_5 = self.lin_h1.bias primals_6 = self.lin_h2.weight primals_7 = self.lin_h2.bias primals_8 = self.lin_out.weight primals_9 = self.lin_out.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]
aixpact/python
ANN
false
1,385
[ "MIT" ]
0
41256672472fec2c0f8bf6a9146c4053b16fd907
https://github.com/aixpact/python/tree/41256672472fec2c0f8bf6a9146c4053b16fd907
Affine
import torch import torch.nn as nn import torch.nn.parallel import torch.utils.data class Affine(nn.Module): def __init__(self, dim): super().__init__() self.alpha = nn.Parameter(torch.ones((1, 1, dim))) self.beta = nn.Parameter(torch.zeros((1, 1, dim))) def forward(self, x): return torch.addcmul(self.beta, self.alpha, x) def get_inputs(): return [torch.rand([4, 4, 4, 4])] def get_init_inputs(): return [[], {'dim': 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 as nn import torch.nn.parallel import torch.utils.data 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_addcmul_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 + x0, xmask, eviction_policy='evict_last') tmp4 = tl.load(in_ptr2 + x2, xmask) tmp2 = 1.0 tmp3 = tmp1 * tmp2 tmp5 = tmp3 * tmp4 tmp6 = tmp0 + tmp5 tl.store(out_ptr0 + x2, tmp6, xmask) def call(args): primals_1, primals_2, primals_3 = args args.clear() assert_size_stride(primals_1, (1, 1, 4), (4, 4, 1)) assert_size_stride(primals_2, (1, 1, 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, 4), (64, 16, 4, 1), torch.float32) get_raw_stream(0) triton_poi_fused_addcmul_0[grid(256)](primals_1, primals_2, primals_3, buf0, 256, XBLOCK=128, num_warps=4, num_stages=1) del primals_1 del primals_2 return buf0, primals_3 class AffineNew(nn.Module): def __init__(self, dim): super().__init__() self.alpha = nn.Parameter(torch.ones((1, 1, dim))) self.beta = nn.Parameter(torch.zeros((1, 1, dim))) def forward(self, input_0): primals_1 = self.alpha primals_2 = self.beta primals_3 = input_0 output = call([primals_1, primals_2, primals_3]) return output[0]
akarshkumar0101/timm-mlp-shaker
Affine
false
1,386
[ "Apache-2.0" ]
0
ab211dd137b790ac57f5ed924c2ada148d54a194
https://github.com/akarshkumar0101/timm-mlp-shaker/tree/ab211dd137b790ac57f5ed924c2ada148d54a194
WeightedAttention
import torch from torch import nn class WeightedAttention(nn.Module): def __init__(self, dim, eps=1e-08, softmax_dim=1, weighted_mean_dim=2): super().__init__() self.norm_input = nn.LayerNorm(dim) self.norm_context = nn.LayerNorm(dim) self.to_q = nn.Linear(dim, dim) self.to_k = nn.Linear(dim, dim) self.to_v = nn.Linear(dim, dim) self.eps = eps self.scale = dim ** -0.5 self.softmax_dim = softmax_dim self.weighted_mean_dim = weighted_mean_dim def forward(self, inputs, context): inputs = self.norm_input(inputs) context = self.norm_context(context) q = self.to_q(inputs) k = self.to_k(context) v = self.to_v(context) dots = torch.einsum('bid,bjd->bij', q, k) * self.scale attn = dots.softmax(dim=self.softmax_dim) + self.eps attn = attn / attn.sum(dim=self.weighted_mean_dim, keepdim=True) updates = torch.einsum('bjd,bij->bid', v, attn) return updates def get_inputs(): return [torch.rand([4, 4, 4]), torch.rand([4, 4, 4])] def get_init_inputs(): return [[], {'dim': 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, 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_native_layer_norm_0(in_ptr0, 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 + 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 = 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-05 tmp22 = tmp20 + tmp21 tmp23 = libdevice.rsqrt(tmp22) tl.store(out_ptr0 + x0, tmp8, xmask) tl.store(out_ptr1 + x0, tmp23, xmask) @triton.jit def triton_poi_fused_native_layer_norm_1(in_ptr0, in_ptr1, in_ptr2, in_ptr3, in_ptr4, 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 x0 = xindex % 4 tmp0 = tl.load(in_ptr0 + x2, xmask) tmp1 = tl.load(in_ptr1 + x1, xmask, eviction_policy='evict_last') tmp3 = tl.load(in_ptr2 + x1, xmask, eviction_policy='evict_last') tmp5 = tl.load(in_ptr3 + x0, xmask, eviction_policy='evict_last') tmp7 = tl.load(in_ptr4 + x0, xmask, eviction_policy='evict_last') tmp2 = tmp0 - tmp1 tmp4 = tmp2 * tmp3 tmp6 = tmp4 * tmp5 tmp8 = tmp6 + tmp7 tl.store(out_ptr0 + x2, tmp8, 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 x3 = xindex x0 = xindex % 4 x2 = xindex // 16 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp3 = tl.load(in_ptr0 + (x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp5 = tl.load(in_ptr0 + (4 + x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp8 = tl.load(in_ptr0 + (8 + x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp11 = tl.load(in_ptr0 + (12 + x0 + 16 * x2), 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 = 0.5 tmp16 = tmp14 * tmp15 tmp17 = tl_math.exp(tmp16) tl.store(out_ptr0 + x3, tmp17, xmask) @triton.jit def triton_poi_fused__softmax_3(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 x3 = xindex x0 = xindex % 4 x2 = xindex // 16 tmp0 = tl.load(in_ptr0 + x3, xmask) tmp1 = tl.load(in_ptr0 + (x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp2 = tl.load(in_ptr0 + (4 + x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp4 = tl.load(in_ptr0 + (8 + x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp6 = tl.load(in_ptr0 + (12 + x0 + 16 * x2), xmask, eviction_policy= 'evict_last') tmp3 = tmp1 + tmp2 tmp5 = tmp3 + tmp4 tmp7 = tmp5 + tmp6 tmp8 = tmp0 / tmp7 tl.store(out_ptr0 + x3, tmp8, xmask) @triton.jit def triton_poi_fused_add_div_sum_4(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 = 1e-08 tmp2 = tmp0 + tmp1 tmp4 = tmp3 + tmp1 tmp6 = tmp5 + tmp1 tmp7 = tmp4 + tmp6 tmp9 = tmp8 + tmp1 tmp10 = tmp7 + tmp9 tmp12 = tmp11 + tmp1 tmp13 = tmp10 + tmp12 tmp14 = tmp2 / tmp13 tl.store(out_ptr0 + x2, tmp14, 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, (4,), (1,)) assert_size_stride(primals_2, (4,), (1,)) assert_size_stride(primals_3, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_4, (4,), (1,)) assert_size_stride(primals_5, (4,), (1,)) assert_size_stride(primals_6, (4, 4, 4), (16, 4, 1)) assert_size_stride(primals_7, (4, 4), (4, 1)) assert_size_stride(primals_8, (4,), (1,)) assert_size_stride(primals_9, (4, 4), (4, 1)) assert_size_stride(primals_10, (4,), (1,)) assert_size_stride(primals_11, (4, 4), (4, 1)) assert_size_stride(primals_12, (4,), (1,)) with torch.cuda._DeviceGuard(0): torch.cuda.set_device(0) buf0 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) buf1 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) get_raw_stream(0) triton_poi_fused_native_layer_norm_0[grid(16)](primals_3, buf0, buf1, 16, XBLOCK=16, num_warps=1, num_stages=1) buf2 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) buf3 = empty_strided_cuda((4, 4, 1), (4, 1, 16), torch.float32) triton_poi_fused_native_layer_norm_0[grid(16)](primals_6, buf2, buf3, 16, XBLOCK=16, num_warps=1, num_stages=1) buf4 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_native_layer_norm_1[grid(64)](primals_3, buf0, buf1, primals_1, primals_2, buf4, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf0 del buf1 del primals_1 del primals_2 buf5 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_8, reinterpret_tensor(buf4, (16, 4), ( 4, 1), 0), reinterpret_tensor(primals_7, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf5) del primals_8 buf6 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused_native_layer_norm_1[grid(64)](primals_6, buf2, buf3, primals_4, primals_5, buf6, 64, XBLOCK=64, num_warps=1, num_stages=1) del buf2 del buf3 del primals_4 del primals_5 buf7 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_10, reinterpret_tensor(buf6, (16, 4), (4, 1), 0), reinterpret_tensor(primals_9, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf7) del primals_10 buf8 = empty_strided_cuda((16, 4), (4, 1), torch.float32) extern_kernels.addmm(primals_12, reinterpret_tensor(buf6, (16, 4), (4, 1), 0), reinterpret_tensor(primals_11, (4, 4), (1, 4), 0), alpha=1, beta=1, out=buf8) del primals_12 buf9 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf5, (4, 4, 4), (16, 4, 1), 0), reinterpret_tensor(buf7, (4, 4, 4), (16, 1, 4), 0), out=buf9) buf10 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) triton_poi_fused__softmax_2[grid(64)](buf9, buf10, 64, XBLOCK=64, num_warps=1, num_stages=1) buf11 = buf9 del buf9 triton_poi_fused__softmax_3[grid(64)](buf10, buf11, 64, XBLOCK=64, num_warps=1, num_stages=1) buf12 = buf10 del buf10 triton_poi_fused_add_div_sum_4[grid(64)](buf11, buf12, 64, XBLOCK= 64, num_warps=1, num_stages=1) buf13 = empty_strided_cuda((4, 4, 4), (16, 4, 1), torch.float32) extern_kernels.bmm(reinterpret_tensor(buf8, (4, 4, 4), (16, 1, 4), 0), reinterpret_tensor(buf12, (4, 4, 4), (16, 1, 4), 0), out=buf13) return reinterpret_tensor(buf13, (4, 4, 4), (16, 1, 4), 0 ), primals_3, primals_6, reinterpret_tensor(buf4, (16, 4), (4, 1), 0 ), reinterpret_tensor(buf6, (16, 4), (4, 1), 0 ), buf11, buf12, reinterpret_tensor(buf8, (4, 4, 4), (16, 4, 1), 0 ), reinterpret_tensor(buf5, (4, 4, 4), (16, 1, 4), 0 ), reinterpret_tensor(buf7, (4, 4, 4), (16, 4, 1), 0 ), primals_11, primals_9, primals_7 class WeightedAttentionNew(nn.Module): def __init__(self, dim, eps=1e-08, softmax_dim=1, weighted_mean_dim=2): super().__init__() self.norm_input = nn.LayerNorm(dim) self.norm_context = nn.LayerNorm(dim) self.to_q = nn.Linear(dim, dim) self.to_k = nn.Linear(dim, dim) self.to_v = nn.Linear(dim, dim) self.eps = eps self.scale = dim ** -0.5 self.softmax_dim = softmax_dim self.weighted_mean_dim = weighted_mean_dim def forward(self, input_0, input_1): primals_1 = self.norm_input.weight primals_2 = self.norm_input.bias primals_4 = self.norm_context.weight primals_5 = self.norm_context.bias primals_7 = self.to_q.weight primals_8 = self.to_q.bias primals_9 = self.to_k.weight primals_10 = self.to_k.bias primals_11 = self.to_v.weight primals_12 = self.to_v.bias primals_3 = input_0 primals_6 = 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]
ajabri/slot-attention
WeightedAttention
false
1,387
[ "MIT" ]
0
32acb6614f1bd511f2dc3c263f852ed2dbe9c213
https://github.com/ajabri/slot-attention/tree/32acb6614f1bd511f2dc3c263f852ed2dbe9c213