| @@ -16,6 +16,7 @@ | |||
| network config setting, will be used in train.py and eval.py | |||
| """ | |||
| from easydict import EasyDict as ed | |||
| config = ed({ | |||
| "class_num": 1000, | |||
| "batch_size": 32, | |||
| @@ -13,24 +13,26 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from mindspore.nn.loss.loss import _Loss | |||
| from mindspore.ops import operations as P | |||
| from mindspore.ops import functional as F | |||
| import mindspore.nn as nn | |||
| from mindspore import Tensor | |||
| from mindspore.common import dtype as mstype | |||
| import mindspore.nn as nn | |||
| from mindspore.nn.loss.loss import _Loss | |||
| from mindspore.ops import functional as F | |||
| from mindspore.ops import operations as P | |||
| class CrossEntropy(_Loss): | |||
| def __init__(self, smooth_factor=0., num_classes=1000): | |||
| super(CrossEntropy, self).__init__() | |||
| self.onehot = P.OneHot() | |||
| self.on_value = Tensor(1.0 - smooth_factor, mstype.float32) | |||
| self.off_value = Tensor(1.0 * smooth_factor / (num_classes -1), mstype.float32) | |||
| #self.cast = P.Cast() | |||
| self.off_value = Tensor(1.0 * smooth_factor / (num_classes - 1), mstype.float32) | |||
| # self.cast = P.Cast() | |||
| self.ce = nn.SoftmaxCrossEntropyWithLogits() | |||
| self.mean = P.ReduceMean(False) | |||
| def construct(self, logit, label): | |||
| #one_hot_label = self.onehot(self.cast(label, mstype.int32), | |||
| # one_hot_label = self.onehot(self.cast(label, mstype.int32), | |||
| # F.shape(logit)[1], self.on_value, self.off_value)、 | |||
| one_hot_label = self.onehot(label, F.shape(logit)[1], self.on_value, self.off_value) | |||
| loss = self.ce(logit, one_hot_label) | |||
| @@ -12,10 +12,9 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusBatchMatMul", | |||
| "imply_type": "TBE", | |||
| @@ -71,11 +70,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusBatchMatMul(input_x1, input_x2, output, transpose_a=False, transpose_b=True, kernel_name="batchmatmul"): | |||
| return | |||
| @@ -12,9 +12,9 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusCholeskyTrsm", | |||
| "imply_type": "TBE", | |||
| @@ -58,7 +58,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusCholeskyTrsm(input_x,output, kernel_name): | |||
| def CusCholeskyTrsm(input_x, output, kernel_name): | |||
| return | |||
| @@ -12,42 +12,27 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| import mindspore as ms | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| # y = x^2 | |||
| class CusBatchMatMul(PrimitiveWithInfer): | |||
| """CusMatMulCube definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusMatMulCube""" | |||
| self.init_prim_io_names(inputs=['x1', 'x2'], outputs=['y']) | |||
| # self.transpose_a = transpose_a | |||
| # self.transpose_b = transpose_b | |||
| from .batch_matmul_impl import CusBatchMatMul | |||
| def get_bprop(self): | |||
| def bprop(x1, x2, out, dout): | |||
| return (C.zeros_like(x1),C.zeros_like(x2)) | |||
| return (C.zeros_like(x1), C.zeros_like(x2)) | |||
| return bprop | |||
| def infer_shape(self, data1_shape, data2_shape): | |||
| #shape = [1, data1_shape[1], data2_shape[2], 16, 16] | |||
| #return shape | |||
| # if self.transpose_a == True: | |||
| # k1, m = data1_shape | |||
| # else: | |||
| # m, k1 = data1_shape | |||
| # if self.transpose_b == True: | |||
| # n, k2 = data2_shape | |||
| # else: | |||
| # k2, n = data2_shape | |||
| # assert k1==k2 | |||
| # shape = [m, n] | |||
| return data1_shape | |||
| def infer_dtype(self, data1_dtype, data2_dtype): | |||
| return data1_dtype | |||
| # return ms.common.dtype.tensor_type(getattr(ms, "float32")) | |||
| return data1_dtype | |||
| @@ -12,24 +12,23 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| class CusCholeskyTrsm(PrimitiveWithInfer): | |||
| """CusCholeskyTrsm definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusCholeskyTrsm""" | |||
| self.init_prim_io_names(inputs=['x1'], outputs=['y']) | |||
| from .cholesky_trsm import CusCholeskyTrsm | |||
| def infer_shape(self, data1_shape): | |||
| m,n = data1_shape | |||
| m, n = data1_shape | |||
| if m >= 128: | |||
| return [m//128,128,128] | |||
| return [m // 128, 128, 128] | |||
| else: | |||
| return [1,64,64] | |||
| return [1, 64, 64] | |||
| def infer_dtype(self, data1_dtype): | |||
| return data1_dtype | |||
| return data1_dtype | |||
| @@ -12,31 +12,30 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| class CusFusedAbsMax1(PrimitiveWithInfer): | |||
| """CusCholeskyTrsm definition""" | |||
| @prim_attr_register | |||
| def __init__(self, origin_shape = [-1,-1]): | |||
| def __init__(self, origin_shape=[-1, -1]): | |||
| """init CusCholeskyTrsm""" | |||
| self.init_prim_io_names(inputs=['x1'], outputs=['y']) | |||
| from .fused_abs_max1 import CusFusedAbsMax1 | |||
| self.origin_shape = origin_shape | |||
| def get_bprop(self): | |||
| def bprop(x, out, dout): | |||
| return (C.zeros_like(x),) | |||
| return bprop | |||
| def infer_shape(self, data1_shape): | |||
| if len(data1_shape) == 2: | |||
| return [1,] | |||
| return [1, ] | |||
| else: | |||
| return [32, 64] | |||
| # return [128,128] | |||
| def infer_dtype(self, data1_dtype): | |||
| return data1_dtype | |||
| @@ -13,26 +13,26 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| class CusImg2Col(PrimitiveWithInfer): | |||
| """CusImg2Col definition""" | |||
| @prim_attr_register | |||
| def __init__(self, ksizes, strides, dilates = (1, 1, 1, 1), mode="NC1HWC0"): | |||
| def __init__(self, ksizes, strides, dilates=(1, 1, 1, 1), mode="NC1HWC0"): | |||
| """init CusImg2Col""" | |||
| self.init_prim_io_names(inputs=['x1'], outputs=['y']) | |||
| self.ksizes = ksizes | |||
| self.strides = strides | |||
| self.dilates = dilates | |||
| self.mode = mode | |||
| from .img2col_impl import CusImg2Col | |||
| def get_bprop(self): | |||
| def bprop(x, out, dout): | |||
| return (C.zeros_like(x),) | |||
| return bprop | |||
| def infer_shape(self, data1_shape): | |||
| @@ -12,30 +12,31 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| import mindspore as ms | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| # y = x^2 | |||
| class CusMatMulCube(PrimitiveWithInfer): | |||
| """CusMatMulCube definition""" | |||
| @prim_attr_register | |||
| def __init__(self, transpose_a=False, transpose_b=False): | |||
| """init CusMatMulCube""" | |||
| self.init_prim_io_names(inputs=['x1', 'x2'], outputs=['y']) | |||
| self.transpose_a = transpose_a | |||
| self.transpose_b = transpose_b | |||
| from .matmul_cube_impl import CusMatMulCube | |||
| def get_bprop(self): | |||
| def bprop(x1, x2, out, dout): | |||
| return (C.zeros_like(x1),C.zeros_like(x2)) | |||
| return (C.zeros_like(x1), C.zeros_like(x2)) | |||
| return bprop | |||
| def infer_shape(self, data1_shape, data2_shape): | |||
| #shape = [1, data1_shape[1], data2_shape[2], 16, 16] | |||
| #return shape | |||
| # shape = [1, data1_shape[1], data2_shape[2], 16, 16] | |||
| # return shape | |||
| if self.transpose_a == True: | |||
| k1, m = data1_shape | |||
| else: | |||
| @@ -44,9 +45,9 @@ class CusMatMulCube(PrimitiveWithInfer): | |||
| n, k2 = data2_shape | |||
| else: | |||
| k2, n = data2_shape | |||
| assert k1==k2 | |||
| assert k1 == k2 | |||
| shape = [m, n] | |||
| return shape | |||
| def infer_dtype(self, data1_dtype, data2_dtype): | |||
| return ms.common.dtype.tensor_type(getattr(ms, "float32")) | |||
| @@ -12,27 +12,28 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| import mindspore as ms | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| # y = x^2 | |||
| class CusMatMulCubeDenseLeft(PrimitiveWithInfer): | |||
| """CusMatMulCube definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusMatMulCube""" | |||
| self.init_prim_io_names(inputs=['x1', 'x2'], outputs=['y']) | |||
| from .matmul_cube_dense_left import CusMatMulCubeDenseLeft | |||
| def get_bprop(self): | |||
| def bprop(x1, x2, out, dout): | |||
| return (C.zeros_like(x1),C.zeros_like(x2)) | |||
| return (C.zeros_like(x1), C.zeros_like(x2)) | |||
| return bprop | |||
| def infer_shape(self, data1_shape, data2_shape): | |||
| return data2_shape | |||
| def infer_dtype(self, data1_dtype, data2_dtype): | |||
| return ms.common.dtype.tensor_type(getattr(ms, "float16")) | |||
| @@ -12,27 +12,27 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| import mindspore as ms | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| # y = x^2 | |||
| class CusMatMulCubeFraczRightMul(PrimitiveWithInfer): | |||
| """CusMatMulCubeFraczRightMul definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusMatMulCubeFraczRightMul""" | |||
| self.init_prim_io_names(inputs=['x1', 'x2', 'x3'], outputs=['y']) | |||
| from .matmul_cube_fracz_right_mul_impl import CusMatMulCubeFraczRightMul | |||
| def get_bprop(self): | |||
| def bprop(x1, x2, x3, out, dout): | |||
| return (C.zeros_like(x1),C.zeros_like(x2),C.zeros_like(x3)) | |||
| return (C.zeros_like(x1), C.zeros_like(x2), C.zeros_like(x3)) | |||
| return bprop | |||
| def infer_shape(self, data1_shape, data2_shape, data3_shape): | |||
| return data1_shape | |||
| def infer_dtype(self, data1_dtype, data2_dtype, data3_dtype): | |||
| return ms.common.dtype.tensor_type(getattr(ms, "float32")) | |||
| @@ -12,29 +12,29 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| import mindspore as ms | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| # y = x^2 | |||
| class CusMatrixCombine(PrimitiveWithInfer): | |||
| """CusMatMulCube definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusMatMulCube""" | |||
| self.init_prim_io_names(inputs=['x'], outputs=['y']) | |||
| from .matrix_combine_impl import CusMatrixCombine | |||
| def get_bprop(self): | |||
| def bprop(x, out, dout): | |||
| return (C.zeros_like(x),) | |||
| return bprop | |||
| def infer_shape(self, data_shape): | |||
| a, b, c = data_shape | |||
| shape = [a*b, a*c] | |||
| shape = [a * b, a * c] | |||
| return shape | |||
| def infer_dtype(self, data_dtype): | |||
| return data_dtype | |||
| @@ -12,35 +12,33 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| from mindspore.ops import prim_attr_register, PrimitiveWithInfer | |||
| from mindspore import Tensor | |||
| from mindspore.ops.composite import multitype_ops as C | |||
| class CusTranspose02314(PrimitiveWithInfer): | |||
| """CusTranspose02314 definition""" | |||
| @prim_attr_register | |||
| def __init__(self): | |||
| """init CusTranspose02314""" | |||
| self.init_prim_io_names(inputs=['x1'], outputs=['y']) | |||
| from .transpose02314_impl import CusTranspose02314 | |||
| def get_bprop(self): | |||
| def bprop(x, out, dout): | |||
| return (C.zeros_like(x),) | |||
| return bprop | |||
| def infer_shape(self, data1_shape): | |||
| assert len(data1_shape) == 4 | |||
| n, c, h, w = data1_shape | |||
| c0 = 16 | |||
| c1 = c // 16 | |||
| shape = (n * h * w, c1 * c0) | |||
| # axis_0, axis_1, axis_2, axis_3, axis_4 = data1_shape | |||
| # shape = (axis_0, axis_2, axis_3, axis_1, axis_4) | |||
| return shape | |||
| def infer_dtype(self, data1_dtype): | |||
| return data1_dtype | |||
| @@ -13,9 +13,9 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusFusedAbsMax1", | |||
| "imply_type": "TBE", | |||
| @@ -64,5 +64,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusFusedAbsMax1(input_x, output, origin_shape = None, kernel_name="fused_abs_max1"): | |||
| def CusFusedAbsMax1(input_x, output, origin_shape=None, kernel_name="fused_abs_max1"): | |||
| return | |||
| @@ -13,9 +13,9 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusImg2ColNC1HWC0", | |||
| "imply_type": "TBE", | |||
| @@ -82,6 +82,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusImg2ColNC1HWC0(input_x, output, ksizes, strides, dilates, padding, kernel_name="img2col"): | |||
| return | |||
| @@ -1,7 +1,7 @@ | |||
| #!/usr/bin/env python | |||
| # -*- coding:utf-8 -*- | |||
| """ | |||
| copyright 2019 Huawei Technologies Co., Ltd | |||
| copyright 2020 Huawei Technologies Co., Ltd | |||
| Licensed under the Apache License, Version 2.0 (the "License"); | |||
| you may not use this file except in compliance with the License. | |||
| @@ -18,22 +18,15 @@ limitations under the License. | |||
| matmul | |||
| """ | |||
| from __future__ import absolute_import | |||
| import te.lang.cce | |||
| import te.platform.cce_params as cce | |||
| from te.platform.fusion_manager import fusion_manager | |||
| from te import tvm | |||
| from topi import generic | |||
| from topi.cce import util | |||
| from impl.matmul_vector import matmul_vector_cce | |||
| from te import tik | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| from topi.cce import util | |||
| # General limitation of the size for input shape: 2**31 | |||
| SHAPE_SIZE_LIMIT = 2147483648 | |||
| NoneType = type(None) | |||
| @op_info_register("""{ | |||
| "op_name": "CusMatMulCubeDenseLeft", | |||
| "imply_type": "TBE", | |||
| @@ -102,8 +95,7 @@ NoneType = type(None) | |||
| } | |||
| ] | |||
| }""") | |||
| @util.check_input_type(dict, dict, (dict, NoneType), dict, bool, bool, str) | |||
| def CusMatMulCubeDenseLeft(input_x1, input_x2, bias=None, output_y={}, trans_a=False, trans_b=False, kernel_name="matmulcube"): | |||
| def CusMatMulCubeDenseLeft(input_x1, input_x2, bias=None, output_y={}, trans_a=False, trans_b=False, | |||
| kernel_name="matmulcube"): | |||
| return | |||
| @@ -1,7 +1,7 @@ | |||
| #!/usr/bin/env python | |||
| # -*- coding:utf-8 -*- | |||
| """ | |||
| copyright 2019 Huawei Technologies Co., Ltd | |||
| copyright 2020 Huawei Technologies Co., Ltd | |||
| Licensed under the Apache License, Version 2.0 (the "License"); | |||
| you may not use this file except in compliance with the License. | |||
| @@ -18,19 +18,15 @@ limitations under the License. | |||
| matmul | |||
| """ | |||
| from __future__ import absolute_import | |||
| import te.platform.cce_params as cce | |||
| from te import tvm | |||
| from topi.cce import util | |||
| from te import tik | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| from topi.cce import util | |||
| # General limitation of the size for input shape: 2**31 | |||
| SHAPE_SIZE_LIMIT = 2147483648 | |||
| NoneType = type(None) | |||
| @op_info_register("""{ | |||
| "op_name": "CusMatMulCubeFraczLeftCast", | |||
| "imply_type": "TBE", | |||
| @@ -99,7 +95,6 @@ NoneType = type(None) | |||
| } | |||
| ] | |||
| }""") | |||
| # pylint: disable=locally-disabled,too-many-arguments, too-many-locals, too-many-statements | |||
| @util.check_input_type(dict, dict, (dict, NoneType), dict, bool, bool, str) | |||
| def CusMatMulCubeFraczLeftCast(input_x1, input_x2, bias=None, output_y={}, trans_a=False, trans_b=False, | |||
| @@ -1,7 +1,7 @@ | |||
| #!/usr/bin/env python | |||
| # -*- coding:utf-8 -*- | |||
| """ | |||
| copyright 2019 Huawei Technologies Co., Ltd | |||
| copyright 2020 Huawei Technologies Co., Ltd | |||
| Licensed under the Apache License, Version 2.0 (the "License"); | |||
| you may not use this file except in compliance with the License. | |||
| @@ -18,21 +18,14 @@ limitations under the License. | |||
| matmul | |||
| """ | |||
| from __future__ import absolute_import | |||
| import te.lang.cce | |||
| import te.platform.cce_params as cce | |||
| from te.platform.fusion_manager import fusion_manager | |||
| from te import tvm | |||
| from topi import generic | |||
| from topi.cce import util | |||
| from te import tik | |||
| from impl.matmul_vector import matmul_vector_cce | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| # General limitation of the size for input shape: 2**31 | |||
| SHAPE_SIZE_LIMIT = 2147483648 | |||
| NoneType = type(None) | |||
| @op_info_register("""{ | |||
| "op_name": "CusMatMulCubeFraczRightMul", | |||
| "imply_type": "TBE", | |||
| @@ -114,8 +107,6 @@ NoneType = type(None) | |||
| } | |||
| ] | |||
| }""") | |||
| def CusMatMulCubeFraczRightMul(input_x1, input_x2, input_x3, bias=None, output_y={}, trans_a=False, trans_b=False, kernel_name="matmulcube"): | |||
| def CusMatMulCubeFraczRightMul(input_x1, input_x2, input_x3, bias=None, output_y={}, trans_a=False, trans_b=False, | |||
| kernel_name="matmulcube"): | |||
| return | |||
| @@ -1,7 +1,7 @@ | |||
| #!/usr/bin/env python | |||
| # -*- coding:utf-8 -*- | |||
| """ | |||
| copyright 2019 Huawei Technologies Co., Ltd | |||
| copyright 2020 Huawei Technologies Co., Ltd | |||
| Licensed under the Apache License, Version 2.0 (the "License"); | |||
| you may not use this file except in compliance with the License. | |||
| @@ -18,20 +18,15 @@ limitations under the License. | |||
| matmul | |||
| """ | |||
| from __future__ import absolute_import | |||
| import te.lang.cce | |||
| import te.platform.cce_params as cce | |||
| from te import tvm | |||
| from topi import generic | |||
| from topi.cce import util | |||
| from impl.matmul_vector import matmul_vector_cce | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| from topi.cce import util | |||
| # General limitation of the size for input shape: 2**31 | |||
| SHAPE_SIZE_LIMIT = 2147483648 | |||
| NoneType = type(None) | |||
| @op_info_register("""{ | |||
| "op_name": "CusMatMulCube", | |||
| "imply_type": "TBE", | |||
| @@ -112,8 +107,7 @@ NoneType = type(None) | |||
| } | |||
| ] | |||
| }""") | |||
| # pylint: disable=locally-disabled,too-many-arguments, too-many-locals, too-many-statements | |||
| @util.check_input_type(dict, dict, (dict, NoneType), dict, bool, bool, str) | |||
| def CusMatMulCube(input_x1, input_x2, bias=None, output_y={}, trans_a=False, trans_b=False, kernel_name="matmulcube"): | |||
| return | |||
| return | |||
| @@ -13,9 +13,9 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusMatrixCombine", | |||
| "imply_type": "TBE", | |||
| @@ -58,7 +58,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusMatrixCombine(input_x, output,kernel_name="matrix_combine"): | |||
| def CusMatrixCombine(input_x, output, kernel_name="matrix_combine"): | |||
| return | |||
| @@ -13,9 +13,9 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from te import tik | |||
| from topi.cce import util | |||
| from mindspore.ops.op_info_register import op_info_register | |||
| @op_info_register("""{ | |||
| "op_name": "CusTranspose02314", | |||
| "imply_type": "TBE", | |||
| @@ -58,6 +58,5 @@ from mindspore.ops.op_info_register import op_info_register | |||
| } | |||
| ] | |||
| }""") | |||
| def CusTranspose02314(input_x, output, kernel_name="transpose021354"): | |||
| return | |||
| @@ -16,11 +16,12 @@ | |||
| create train or eval dataset. | |||
| """ | |||
| import os | |||
| import mindspore.common.dtype as mstype | |||
| import mindspore.dataset.engine as de | |||
| import mindspore.dataset.transforms.vision.c_transforms as V_C | |||
| import mindspore.dataset.transforms.c_transforms as C2 | |||
| from config_imagenet import config | |||
| import mindspore.dataset.transforms.vision.c_transforms as V_C | |||
| def create_dataset(dataset_path, do_train, repeat_num=1, batch_size=32): | |||
| """ | |||
| @@ -41,7 +42,7 @@ def create_dataset(dataset_path, do_train, repeat_num=1, batch_size=32): | |||
| ds = de.ImageFolderDatasetV2(dataset_path, num_parallel_workers=8, shuffle=False) | |||
| else: | |||
| ds = de.ImageFolderDatasetV2(dataset_path, num_parallel_workers=8, shuffle=True, | |||
| num_shards=device_num, shard_id=rank_id) | |||
| num_shards=device_num, shard_id=rank_id) | |||
| image_size = 224 | |||
| mean = [0.485 * 255, 0.456 * 255, 0.406 * 255] | |||
| @@ -61,9 +62,9 @@ def create_dataset(dataset_path, do_train, repeat_num=1, batch_size=32): | |||
| V_C.Normalize(mean=mean, std=std), | |||
| V_C.HWC2CHW() | |||
| ] | |||
| #type_cast_op = C2.TypeCast(mstype.float16) | |||
| # type_cast_op = C2.TypeCast(mstype.float16) | |||
| type_cast_op = C2.TypeCast(mstype.int32) | |||
| ds = ds.map(input_columns="image", operations=transform_img, num_parallel_workers=8) | |||
| ds = ds.map(input_columns="label", operations=type_cast_op, num_parallel_workers=8) | |||
| @@ -13,14 +13,17 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """learning rate generator""" | |||
| import numpy as np | |||
| import math | |||
| import numpy as np | |||
| def linear_warmup_lr(current_step, warmup_steps, base_lr, init_lr): | |||
| lr_inc = (float(base_lr) - float(init_lr)) / float(warmup_steps) | |||
| lr = float(init_lr) + lr_inc * current_step | |||
| return lr | |||
| def cosine_annealing_lr(lr, steps_per_epoch, warmup_epochs, max_epoch, T_max, eta_min=0, num_periods=0.5): | |||
| base_lr = lr | |||
| warmup_init_lr = 0 | |||
| @@ -39,6 +42,7 @@ def cosine_annealing_lr(lr, steps_per_epoch, warmup_epochs, max_epoch, T_max, et | |||
| lr_each_step.append(lr) | |||
| return np.array(lr_each_step).astype(np.float32) | |||
| def warmup_cosine_annealing_lr(lr, steps_per_epoch, warmup_epochs, max_epoch, T_max, eta_min=0, num_periods=0.5): | |||
| base_lr = lr | |||
| warmup_init_lr = 0 | |||
| @@ -57,6 +61,7 @@ def warmup_cosine_annealing_lr(lr, steps_per_epoch, warmup_epochs, max_epoch, T_ | |||
| lr_each_step.append(lr) | |||
| return np.array(lr_each_step).astype(np.float32) | |||
| def get_lr(global_step, lr_init, lr_end, lr_max, warmup_epochs, total_epochs, steps_per_epoch, lr_decay_mode): | |||
| """ | |||
| generate learning rate array | |||
| @@ -13,15 +13,15 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """Dataset help for minddata dataset""" | |||
| from mindspore._checkparam import check_bool | |||
| from mindspore import context | |||
| from mindspore.train.parallel_utils import ParallelMode | |||
| from mindspore.train._utils import _exec_datagraph, _get_types_and_shapes, _to_tensor, \ | |||
| _construct_tensor_list, _to_full_shapes, _to_full_tensor | |||
| from mindspore._checkparam import check_bool | |||
| from mindspore.nn.wrap import GetNextSingleOp | |||
| from mindspore.parallel._utils import _get_device_num, _get_global_rank, _get_parallel_mode | |||
| from mindspore.train._utils import _exec_datagraph, _get_types_and_shapes, _to_tensor, \ | |||
| _construct_tensor_list, _to_full_shapes, _to_full_tensor | |||
| from mindspore.train.parallel_utils import ParallelMode | |||
| class DatasetHelper: | |||
| """ | |||
| Help function to use the Minddata dataset. | |||
| @@ -41,9 +41,10 @@ class DatasetHelper: | |||
| >>> for inputs in dataset_helper: | |||
| >>> outputs = network(*inputs) | |||
| """ | |||
| def __init__(self, dataset, first_order_iter=0, dataset_sink_mode=True): | |||
| check_bool(dataset_sink_mode) | |||
| iterclass = _DatasetIterGE | |||
| if not dataset_sink_mode: | |||
| iterclass = _DatasetIterFeed | |||
| @@ -52,24 +53,25 @@ class DatasetHelper: | |||
| iterclass = _DatasetIterMSLoopSink | |||
| else: | |||
| iterclass = _DatasetIterMS | |||
| self.iter = iterclass(dataset, first_order_iter) | |||
| def __iter__(self): | |||
| return self.iter.__iter__() | |||
| # A temp solution for loop sink. Delete later | |||
| def types_shapes(self): | |||
| """Get the types and shapes from dataset on current config.""" | |||
| return self.iter.types_shapes() | |||
| def loop_size(self): | |||
| """Get loop_size for every iteration.""" | |||
| return self.iter.loop_size | |||
| class _DatasetIter: | |||
| """Base iter for dataset help""" | |||
| def __init__(self, dataset): | |||
| self.loop_size = 1 | |||
| if not hasattr(dataset, '__ME_INITED__'): | |||
| @@ -78,7 +80,7 @@ class _DatasetIter: | |||
| else: | |||
| self.loop_size = dataset.__loop_size__ | |||
| dataset.__ME_INITED__ = _exec_datagraph(dataset, self.loop_size).queue_name | |||
| self.ind = 0 | |||
| self.dataset = dataset | |||
| dataset_types, dataset_shapes = _get_types_and_shapes(dataset) | |||
| @@ -89,53 +91,57 @@ class _DatasetIter: | |||
| if _get_parallel_mode() in (ParallelMode.SEMI_AUTO_PARALLEL, ParallelMode.AUTO_PARALLEL): | |||
| device_num = _get_device_num() | |||
| self.dataset_shapes = _to_full_shapes(dataset_shapes, device_num) | |||
| def __iter__(self): | |||
| self.ind = 0 | |||
| return self | |||
| def __next__(self): | |||
| if self.ind >= self.loop_count: | |||
| raise StopIteration() | |||
| self.ind += 1 | |||
| return self.op() | |||
| def types_shapes(self): | |||
| return self.dataset_types, self.dataset_shapes | |||
| def get_loop_count(self, dataset): | |||
| loop_count = 1 | |||
| if hasattr(dataset, '__loop_size__'): | |||
| loop_size = dataset.__loop_size__ | |||
| loop_count = int(dataset.get_dataset_size()/loop_size) | |||
| loop_count = int(dataset.get_dataset_size() / loop_size) | |||
| return loop_count | |||
| class _DatasetIterMSLoopSink(_DatasetIter): | |||
| """Iter for context (enable_loop_sink=True)""" | |||
| def __init__(self, dataset, first_order_iter): | |||
| super(_DatasetIterMSLoopSink, self).__init__(dataset) | |||
| # self.loop_count = self.get_loop_count(dataset) | |||
| loop_size = dataset.__loop_size__ + first_order_iter | |||
| self.loop_count = int(dataset.get_dataset_size()/loop_size) * 2 | |||
| self.loop_count = int(dataset.get_dataset_size() / loop_size) * 2 | |||
| def op(): | |||
| return tuple() | |||
| self.op = op | |||
| class _DatasetIterMS(_DatasetIter): | |||
| """Iter for context (enable_loop_sink=False)""" | |||
| def __init__(self, dataset, first_order_order): | |||
| super(_DatasetIterMS, self).__init__(dataset) | |||
| self.loop_count = dataset.get_dataset_size() | |||
| self.loop_size = 1 | |||
| queue_name = dataset.__ME_INITED__ | |||
| self.op = GetNextSingleOp(self.dataset_types, self.dataset_shapes, queue_name) | |||
| class _DatasetIterGE(_DatasetIter): | |||
| """Iter for ge""" | |||
| def __init__(self, dataset): | |||
| super(_DatasetIterGE, self).__init__(dataset) | |||
| self.loop_count = self.get_loop_count(dataset) | |||
| @@ -145,14 +151,16 @@ class _DatasetIterGE(_DatasetIter): | |||
| if self.need_to_full: | |||
| batch_expand_num = _get_device_num() | |||
| tensor_list_run = _construct_tensor_list(self.dataset_types, self.dataset_shapes, batch_expand_num) | |||
| def op(): | |||
| return tensor_list_run | |||
| self.op = op | |||
| class _DatasetIterFeed: | |||
| """Iter for feed data""" | |||
| def __init__(self, dataset, first_order_order): | |||
| self.dataset = dataset | |||
| self.device_num = _get_device_num() | |||
| @@ -161,18 +169,18 @@ class _DatasetIterFeed: | |||
| self.repeat_ind = 0 | |||
| self.loop_count = dataset.get_dataset_size() | |||
| self.ind = 0 | |||
| parallel_mode = context.get_auto_parallel_context("parallel_mode") | |||
| self.need_to_full = parallel_mode in (ParallelMode.SEMI_AUTO_PARALLEL, ParallelMode.AUTO_PARALLEL) | |||
| def __iter__(self): | |||
| if self.repeat_ind % self.repeat_count == 0: | |||
| self.iter = self.dataset.__iter__() | |||
| self.repeat_ind += 1 | |||
| self.ind = 0 | |||
| return self | |||
| def __next__(self): | |||
| if self.ind >= self.loop_count: | |||
| raise StopIteration() | |||
| @@ -12,28 +12,30 @@ | |||
| # See the License for the specific language governing permissions and | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| from mindspore.nn.cell import Cell | |||
| import mindspore.common.dtype as mstype | |||
| from mindspore.communication.management import GlobalComm, get_group_size | |||
| from mindspore.nn.cell import Cell | |||
| from mindspore.ops import functional as F, composite as C, operations as P | |||
| from mindspore.ops.operations.comm_ops import AllReduce, ReduceOp | |||
| import mindspore.common.dtype as mstype | |||
| from mindspore.communication import create_group | |||
| reduce_opt = C.MultitypeFuncGraph("reduce_opt") | |||
| _all_reduce_A = AllReduce() | |||
| def _init_optimizer_allreduce(group): | |||
| global _all_reduce_A | |||
| _all_reduce_A = AllReduce(ReduceOp.SUM, GlobalComm.WORLD_COMM_GROUP) | |||
| _all_reduce_A.add_prim_attr('fusion', group) | |||
| @reduce_opt.register("Function", "Number", "Tensor") | |||
| def _tensors_allreduce_mean(mul, degree, grad): | |||
| degree = F.scalar_cast(degree, F.dtype(grad)) | |||
| grad = _all_reduce_A(grad) | |||
| cast_op = P.Cast() | |||
| return mul(grad, cast_op(F.scalar_to_array(1.0/degree), F.dtype(grad))) | |||
| return mul(grad, cast_op(F.scalar_to_array(1.0 / degree), F.dtype(grad))) | |||
| @reduce_opt.register("Bool", "Tensor") | |||
| def _tensors_allreduce(allreduce_filter, grad): | |||
| @@ -41,8 +43,10 @@ def _tensors_allreduce(allreduce_filter, grad): | |||
| return _all_reduce_A(grad) | |||
| return grad | |||
| _get_datatype = C.MultitypeFuncGraph("_get_datatype") | |||
| @_get_datatype.register("Tensor") | |||
| def _tensors_get_datatype(grad): | |||
| """ | |||
| @@ -13,29 +13,26 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """Model.""" | |||
| import numpy as np | |||
| import mindspore.nn as nn | |||
| import numpy as np | |||
| from mindspore import context | |||
| from mindspore import log as logger | |||
| from mindspore._c_expression import init_exec_dataset | |||
| from mindspore._checkparam import check_input_data, check_output_data, check_int_positive, check_bool | |||
| from mindspore.common import dtype as mstype | |||
| from mindspore.common.dtype import pytype_to_dtype | |||
| from mindspore.common.tensor import Tensor | |||
| from mindspore.nn.metrics import Loss | |||
| from mindspore.nn.metrics import get_metrics | |||
| from mindspore._checkparam import check_input_data, check_output_data, check_int_positive, check_bool | |||
| from mindspore.train.callback import _InternalCallbackParam, RunContext, _build_callbacks | |||
| from mindspore import context | |||
| from mindspore.nn.wrap.cell_wrapper import _VirtualDatasetCell | |||
| from mindspore.parallel._utils import _get_parallel_mode, _get_device_num, _get_global_rank, \ | |||
| _get_parameter_broadcast, _device_number_check, _parameter_broadcast_check | |||
| from mindspore.nn.metrics import Loss | |||
| from mindspore.nn.wrap import WithLossCell, WithEvalCell, \ | |||
| DataWrapper | |||
| from mindspore.nn.wrap.cell_wrapper import _VirtualDatasetCell | |||
| from mindspore.train import amp | |||
| from mindspore.train.callback import _InternalCallbackParam, RunContext, _build_callbacks | |||
| from mindspore.train.parallel_utils import ParallelMode | |||
| from mindspore.common import dtype as mstype | |||
| from second_order.dataset_helper import DatasetHelper | |||
| from mindspore.train import amp | |||
| from mindspore.common.dtype import pytype_to_dtype | |||
| from mindspore._c_expression import init_exec_dataset | |||
| from mindspore.common.parameter import Parameter | |||
| def _convert_type(types): | |||
| """ | |||
| Convert from numpy type to tensor type. | |||
| @@ -51,18 +48,20 @@ def _convert_type(types): | |||
| ms_type = pytype_to_dtype(np_type) | |||
| ms_types.append(ms_type) | |||
| return ms_types | |||
| def _get_types_and_shapes(dataset): | |||
| """Get dataset types and shapes.""" | |||
| dataset_types = _convert_type(dataset.output_types()) | |||
| dataset_shapes = dataset.output_shapes() | |||
| return dataset_types, dataset_shapes | |||
| def _exec_datagraph(exec_dataset, dataset_size, phase='dataset'): | |||
| """Initialize and execute the dataset graph.""" | |||
| batch_size = exec_dataset.get_batch_size() | |||
| input_indexs = exec_dataset.input_indexs | |||
| # transform data format | |||
| dataset_types, dataset_shapes = _get_types_and_shapes(exec_dataset) | |||
| init_exec_dataset(exec_dataset.__ME_INITED__, | |||
| @@ -72,8 +71,8 @@ def _exec_datagraph(exec_dataset, dataset_size, phase='dataset'): | |||
| dataset_shapes, | |||
| input_indexs, | |||
| phase=phase) | |||
| class Model: | |||
| """ | |||
| High-Level API for Training or Testing. | |||
| @@ -131,7 +130,7 @@ class Model: | |||
| >>> dataset = get_dataset() | |||
| >>> model.train(2, dataset) | |||
| """ | |||
| def __init__(self, network, loss_fn=None, optimizer=None, metrics=None, eval_network=None, | |||
| eval_indexes=None, amp_level="O0", frequency=278, **kwargs): | |||
| self._network = network | |||
| @@ -152,49 +151,49 @@ class Model: | |||
| self._device_number = _get_device_num() | |||
| self._global_rank = _get_global_rank() | |||
| self._parameter_broadcast = _get_parameter_broadcast() | |||
| self._train_network = self._build_train_network() | |||
| self._build_eval_network(metrics, eval_network, eval_indexes) | |||
| self._build_predict_network() | |||
| def _check_kwargs(self, kwargs): | |||
| for arg in kwargs: | |||
| if arg not in ['loss_scale_manager', 'keep_batchnorm_fp32']: | |||
| raise ValueError(f"Unsupport arg '{arg}'") | |||
| raise ValueError(f"Unsupport arg '{arg}'") | |||
| def _build_train_network(self): | |||
| """Build train network""" | |||
| network = self._network | |||
| if self._optimizer: | |||
| if self._loss_scale_manager_set: | |||
| network = amp.build_train_network(network, | |||
| self._optimizer, | |||
| self._loss_fn, | |||
| level=self._amp_level, | |||
| loss_scale_manager=self._loss_scale_manager, | |||
| keep_batchnorm_fp32=self._keep_bn_fp32) | |||
| self._optimizer, | |||
| self._loss_fn, | |||
| level=self._amp_level, | |||
| loss_scale_manager=self._loss_scale_manager, | |||
| keep_batchnorm_fp32=self._keep_bn_fp32) | |||
| else: | |||
| network = amp.build_train_network(network, | |||
| self._optimizer, | |||
| self._loss_fn, | |||
| level=self._amp_level, | |||
| keep_batchnorm_fp32=self._keep_bn_fp32) | |||
| self._optimizer, | |||
| self._loss_fn, | |||
| level=self._amp_level, | |||
| keep_batchnorm_fp32=self._keep_bn_fp32) | |||
| elif self._loss_fn: | |||
| network = nn.WithLossCell(network, self._loss_fn) | |||
| # If need to check if loss_fn is not None, but optimizer is None | |||
| return network | |||
| def _build_eval_network(self, metrics, eval_network, eval_indexes): | |||
| """Build the network for evaluation.""" | |||
| self._metric_fns = get_metrics(metrics) | |||
| if not self._metric_fns: | |||
| return | |||
| if eval_network is not None: | |||
| if eval_indexes is not None and not (isinstance(eval_indexes, list) and len(eval_indexes) == 3): | |||
| raise ValueError("Eval_indexes must be a list or None. If eval_indexes is a list, length of it \ | |||
| must be three. But got {}".format(eval_indexes)) | |||
| self._eval_network = eval_network | |||
| self._eval_indexes = eval_indexes | |||
| else: | |||
| @@ -202,27 +201,27 @@ class Model: | |||
| raise ValueError("loss_fn can not be None.") | |||
| self._eval_network = nn.WithEvalCell(self._network, self._loss_fn) | |||
| self._eval_indexes = [0, 1, 2] | |||
| def _build_predict_network(self): | |||
| """Build the network for prediction.""" | |||
| self._predict_network = self._network | |||
| if self._parallel_mode in (ParallelMode.SEMI_AUTO_PARALLEL, ParallelMode.AUTO_PARALLEL): | |||
| self._predict_network = _VirtualDatasetCell(self._network) | |||
| def _clear_metrics(self): | |||
| """Clear metrics local values.""" | |||
| for metric in self._metric_fns.values(): | |||
| metric.clear() | |||
| def _update_metrics(self, outputs): | |||
| """Update metrics local values.""" | |||
| if not isinstance(outputs, tuple): | |||
| raise ValueError("The `outputs` is not tuple.") | |||
| if self._eval_indexes is not None and len(outputs) < 3: | |||
| raise ValueError("The length of `outputs` must be greater than or equal to 3, \ | |||
| but got {}".format(len(outputs))) | |||
| for metric in self._metric_fns.values(): | |||
| if self._eval_indexes is None: | |||
| metric.update(*outputs) | |||
| @@ -231,14 +230,14 @@ class Model: | |||
| metric.update(outputs[self._eval_indexes[0]]) | |||
| else: | |||
| metric.update(outputs[self._eval_indexes[1]], outputs[self._eval_indexes[2]]) | |||
| def _get_metrics(self): | |||
| """Get metrics local values.""" | |||
| metrics = dict() | |||
| for key, value in self._metric_fns.items(): | |||
| metrics[key] = value.eval() | |||
| return metrics | |||
| def _get_scaling_sens(self): | |||
| """get the scaling sens""" | |||
| scaling_sens = 1 | |||
| @@ -247,7 +246,7 @@ class Model: | |||
| if self._parallel_mode == ParallelMode.DATA_PARALLEL: | |||
| scaling_sens /= self._device_number | |||
| return scaling_sens | |||
| def _train(self, epoch, train_dataset, callbacks=None, dataset_sink_mode=True): | |||
| """ | |||
| Training. | |||
| @@ -266,10 +265,10 @@ class Model: | |||
| """ | |||
| epoch = check_int_positive(epoch) | |||
| self._train_network.set_train() | |||
| if self._parameter_broadcast: | |||
| self._train_network.set_broadcast_flag() | |||
| # build callback list | |||
| list_callback = _build_callbacks(callbacks) | |||
| cb_params = _InternalCallbackParam() | |||
| @@ -283,7 +282,7 @@ class Model: | |||
| cb_params.device_number = self._device_number | |||
| cb_params.train_dataset = train_dataset | |||
| cb_params.list_callback = list_callback | |||
| if dataset_sink_mode: | |||
| if context.get_context("mode") == context.PYNATIVE_MODE: | |||
| logger.warning("The pynative mode cannot support dataset sink mode currently." | |||
| @@ -293,7 +292,6 @@ class Model: | |||
| self._train_dataset_sink_process(epoch, train_dataset, list_callback, cb_params) | |||
| else: | |||
| self._train_process(epoch, train_dataset, list_callback, cb_params) | |||
| def _train_dataset_sink_process(self, epoch, train_dataset, list_callback=None, cb_params=None): | |||
| """ | |||
| @@ -317,7 +315,7 @@ class Model: | |||
| if not hasattr(train_dataset, '__ME_INITED__') and context.get_context("enable_loop_sink") \ | |||
| and not context.get_context("enable_ge"): | |||
| need_wrap = True | |||
| dataset_helper = DatasetHelper(train_dataset, iter_first_order) | |||
| # remove later to deal with loop sink | |||
| if need_wrap: | |||
| @@ -330,7 +328,7 @@ class Model: | |||
| loop_size = dataset_helper.loop_size() | |||
| run_context = RunContext(cb_params) | |||
| list_callback.begin(run_context) | |||
| # used to stop training for early stop, such as stopAtTIme or stopATStep | |||
| should_stop = False | |||
| has_do_train1_dataset = False | |||
| @@ -338,7 +336,7 @@ class Model: | |||
| for i in range(epoch): | |||
| cb_params.cur_epoch_num = i + 1 | |||
| list_callback.epoch_begin(run_context) | |||
| # for data sink dataset_helper only iter once, other wise iter epoch_size times. | |||
| for inputs in dataset_helper: | |||
| list_callback.step_begin(run_context) | |||
| @@ -357,14 +355,14 @@ class Model: | |||
| outputs = self._train_network(*inputs) | |||
| cb_params.net_outputs = outputs | |||
| list_callback.step_end(run_context) | |||
| list_callback.epoch_end(run_context) | |||
| should_stop = should_stop or run_context.get_stop_requested() | |||
| if should_stop: | |||
| break | |||
| list_callback.end(run_context) | |||
| def _train_process(self, epoch, train_dataset, list_callback=None, cb_params=None): | |||
| """ | |||
| Training process. The data would be passed to network directly. | |||
| @@ -385,12 +383,12 @@ class Model: | |||
| _callback_wrapper(list_callback, run_context, "begin") | |||
| # used to stop training for early stop, such as stopAtTIme or stopATStep | |||
| should_stop = False | |||
| for i in range(epoch): | |||
| cb_params.cur_epoch_num = i + 1 | |||
| _callback_wrapper(list_callback, run_context, "epoch_begin") | |||
| for next_element in dataset_helper: | |||
| len_element = len(next_element) | |||
| if self._loss_fn and len_element != 2: | |||
| @@ -398,33 +396,33 @@ class Model: | |||
| "return two elements, but got {}".format(len_element)) | |||
| cb_params.cur_step_num += 1 | |||
| _callback_wrapper(list_callback, run_context, "step_begin") | |||
| overflow = False | |||
| if self._loss_scale_manager and self._loss_scale_manager.get_drop_overflow_update(): | |||
| scaling_sens = self._get_scaling_sens() | |||
| next_element = tuple(next_element) + (Tensor(scaling_sens, mstype.float32),) | |||
| outputs = self._train_network(*next_element) | |||
| cb_params.net_outputs = outputs | |||
| if self._loss_scale_manager and self._loss_scale_manager.get_drop_overflow_update(): | |||
| _, overflow, _ = outputs | |||
| overflow = np.all(overflow.asnumpy()) | |||
| self._loss_scale_manager.update_loss_scale(overflow) | |||
| _callback_wrapper(list_callback, run_context, "step_end") | |||
| should_stop = should_stop or run_context.get_stop_requested() | |||
| if should_stop: | |||
| break | |||
| train_dataset.reset() | |||
| _callback_wrapper(list_callback, run_context, "epoch_end") | |||
| should_stop = should_stop or run_context.get_stop_requested() | |||
| if should_stop: | |||
| break | |||
| _callback_wrapper(list_callback, run_context, "end") | |||
| def train(self, epoch, train_dataset, callbacks=None, dataset_sink_mode=True): | |||
| """ | |||
| Training API where the iteration is controlled by python front-end. | |||
| @@ -470,12 +468,12 @@ class Model: | |||
| if context.get_context("device_target") in ["CPU", "GPU"] and context.get_context("enable_loop_sink"): | |||
| raise ValueError("CPU and GPU can't support loop sink, please set enable_loop_sink=False.") | |||
| self._train(epoch, | |||
| train_dataset, | |||
| callbacks=callbacks, | |||
| dataset_sink_mode=dataset_sink_mode) | |||
| def _eval_dataset_sink_process(self, valid_dataset, list_callback=None, cb_params=None): | |||
| """ | |||
| Evaluation. The data would be passed to network through dataset channel. | |||
| @@ -489,42 +487,42 @@ class Model: | |||
| Dict, returns the loss value & metrics values for the model in test mode. | |||
| """ | |||
| _device_number_check(self._parallel_mode, self._device_number) | |||
| run_context = RunContext(cb_params) | |||
| # remove later to deal with loop sink | |||
| need_wrap = False | |||
| if not hasattr(valid_dataset, '__ME_INITED__') and context.get_context("enable_loop_sink") \ | |||
| and not context.get_context("enable_ge"): | |||
| and not context.get_context("enable_ge"): | |||
| need_wrap = True | |||
| valid_dataset.__loop_size__ = 1 | |||
| dataset_helper = DatasetHelper(valid_dataset) | |||
| # remove later to deal with loop sink | |||
| if need_wrap: | |||
| self._eval_network = nn.DataWrapper(self._eval_network, *(dataset_helper.types_shapes()), | |||
| valid_dataset.__ME_INITED__) | |||
| valid_dataset.__ME_INITED__) | |||
| self._eval_network.set_train(mode=False) | |||
| self._eval_network.phase = 'eval' | |||
| list_callback.begin(run_context) | |||
| for inputs in dataset_helper: | |||
| cb_params.cur_step_num += 1 | |||
| list_callback.step_begin(run_context) | |||
| outputs = self._eval_network(*inputs) | |||
| cb_params.net_outputs = outputs | |||
| list_callback.step_end(run_context) | |||
| self._update_metrics(outputs) | |||
| metrics = self._get_metrics() | |||
| cb_params.metrics = metrics | |||
| list_callback.end(run_context) | |||
| return metrics | |||
| def _eval_process(self, valid_dataset, list_callback=None, cb_params=None): | |||
| """ | |||
| Evaluation. The data would be passed to network directly. | |||
| @@ -539,7 +537,7 @@ class Model: | |||
| """ | |||
| run_context = RunContext(cb_params) | |||
| list_callback.begin(run_context) | |||
| dataset_helper = DatasetHelper(valid_dataset, dataset_sink_mode=False) | |||
| for next_element in dataset_helper: | |||
| cb_params.cur_step_num += 1 | |||
| @@ -548,12 +546,12 @@ class Model: | |||
| cb_params.net_outputs = outputs | |||
| list_callback.step_end(run_context) | |||
| self._update_metrics(outputs) | |||
| metrics = self._get_metrics() | |||
| cb_params.metrics = metrics | |||
| list_callback.end(run_context) | |||
| return metrics | |||
| def eval(self, valid_dataset, callbacks=None, dataset_sink_mode=True): | |||
| """ | |||
| Evaluation API where the iteration is controlled by python front-end. | |||
| @@ -584,7 +582,7 @@ class Model: | |||
| check_bool(dataset_sink_mode) | |||
| if not self._metric_fns: | |||
| raise ValueError("metric fn can not be None or empty.") | |||
| list_callback = _build_callbacks(callbacks) | |||
| cb_params = _InternalCallbackParam() | |||
| cb_params.eval_network = self._eval_network | |||
| @@ -592,16 +590,16 @@ class Model: | |||
| cb_params.batch_num = valid_dataset.get_dataset_size() | |||
| cb_params.mode = "eval" | |||
| cb_params.cur_step_num = 0 | |||
| self._eval_network.set_train(mode=False) | |||
| self._eval_network.phase = 'eval' | |||
| self._clear_metrics() | |||
| if dataset_sink_mode: | |||
| return self._eval_dataset_sink_process(valid_dataset, list_callback, cb_params) | |||
| return self._eval_process(valid_dataset, list_callback, cb_params) | |||
| def predict(self, *predict_data): | |||
| """ | |||
| Generates output predictions for the input samples. | |||
| @@ -625,9 +623,9 @@ class Model: | |||
| self._predict_network.set_train(False) | |||
| check_input_data(*predict_data, data_class=Tensor) | |||
| result = self._predict_network(*predict_data) | |||
| check_output_data(result) | |||
| return result | |||
| __all__ = ["Model"] | |||
| @@ -13,12 +13,14 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """ResNet.""" | |||
| import numpy as np | |||
| import math | |||
| import mindspore.nn as nn | |||
| from mindspore.ops import operations as P | |||
| import numpy as np | |||
| from mindspore.common.tensor import Tensor | |||
| from mindspore.ops import operations as P | |||
| from second_order.thor_layer import Conv2d_Thor, Dense_Thor | |||
| import math | |||
| def calculate_gain(nonlinearity, param=None): | |||
| linear_fns = ['linear', 'conv1d', 'conv2d', 'conv3d', 'conv_transpose1d', 'conv_transpose2d', 'conv_transpose3d'] | |||
| @@ -39,12 +41,13 @@ def calculate_gain(nonlinearity, param=None): | |||
| return math.sqrt(2.0 / (1 + negative_slope ** 2)) | |||
| else: | |||
| raise ValueError("Unsupported nonlinearity {}".format(nonlinearity)) | |||
| def _calculate_fan_in_and_fan_out(tensor): | |||
| dimensions = len(tensor) | |||
| if dimensions < 2: | |||
| raise ValueError("Fan in and fan out can not be computed for tensor with fewer than 2 dimensions") | |||
| if dimensions == 2: # Linear | |||
| fan_in = tensor[1] | |||
| fan_out = tensor[0] | |||
| @@ -57,22 +60,25 @@ def _calculate_fan_in_and_fan_out(tensor): | |||
| fan_in = num_input_fmaps * receptive_field_size | |||
| fan_out = num_output_fmaps * receptive_field_size | |||
| return fan_in, fan_out | |||
| def _calculate_correct_fan(tensor, mode): | |||
| mode = mode.lower() | |||
| valid_modes = ['fan_in', 'fan_out'] | |||
| if mode not in valid_modes: | |||
| raise ValueError("Mode {} not supported, please use one of {}".format(mode, valid_modes)) | |||
| fan_in, fan_out = _calculate_fan_in_and_fan_out(tensor) | |||
| return fan_in if mode == 'fan_in' else fan_out | |||
| def kaiming_normal(inputs_shape, a=0, mode='fan_in', nonlinearity='leaky_relu'): | |||
| fan = _calculate_correct_fan(inputs_shape, mode) | |||
| gain = calculate_gain(nonlinearity, a) | |||
| std = gain / math.sqrt(fan) | |||
| return np.random.normal(0, std, size=inputs_shape).astype(np.float32) | |||
| def kaiming_uniform(inputs_shape, a=0, mode='fan_in', nonlinearity='leaky_relu'): | |||
| fan = _calculate_correct_fan(inputs_shape, mode) | |||
| gain = calculate_gain(nonlinearity, a) | |||
| @@ -80,6 +86,7 @@ def kaiming_uniform(inputs_shape, a=0, mode='fan_in', nonlinearity='leaky_relu') | |||
| bound = math.sqrt(3.0) * std # Calculate uniform bounds from standard deviation | |||
| return np.random.uniform(-bound, bound, size=inputs_shape).astype(np.float32) | |||
| def _conv3x3(in_channel, out_channel, stride=1, damping=0.03, loss_scale=1, frequency=278): | |||
| weight_shape = (out_channel, in_channel, 3, 3) | |||
| weight = Tensor(kaiming_normal(weight_shape, mode="fan_out", nonlinearity='relu')) | |||
| @@ -88,35 +95,41 @@ def _conv3x3(in_channel, out_channel, stride=1, damping=0.03, loss_scale=1, freq | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| # return nn.Conv2d(in_channel, out_channel, | |||
| # kernel_size=3, stride=stride, padding=0, pad_mode='same', weight_init=weight) | |||
| def _conv1x1(in_channel, out_channel, stride=1, damping=0.03, loss_scale=1, frequency=278): | |||
| weight_shape = (out_channel, in_channel, 1, 1) | |||
| weight = Tensor(kaiming_normal(weight_shape, mode="fan_out", nonlinearity='relu')) | |||
| return Conv2d_Thor(in_channel, out_channel, | |||
| kernel_size=1, stride=stride, padding=0, pad_mode='same', weight_init=weight, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| kernel_size=1, stride=stride, padding=0, pad_mode='same', weight_init=weight, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| def _conv7x7(in_channel, out_channel, stride=1, damping=0.03, loss_scale=1, frequency=278): | |||
| weight_shape = (out_channel, in_channel, 7, 7) | |||
| weight = Tensor(kaiming_normal(weight_shape, mode="fan_out", nonlinearity='relu')) | |||
| return Conv2d_Thor(in_channel, out_channel, | |||
| kernel_size=7, stride=stride, padding=0, pad_mode='same', weight_init=weight, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| kernel_size=7, stride=stride, padding=0, pad_mode='same', weight_init=weight, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| def _bn(channel): | |||
| return nn.BatchNorm2d(channel, eps=1e-4, momentum=0.9, | |||
| gamma_init=1, beta_init=0, moving_mean_init=0, moving_var_init=1) | |||
| def _bn_last(channel): | |||
| return nn.BatchNorm2d(channel, eps=1e-4, momentum=0.9, | |||
| gamma_init=1, beta_init=0, moving_mean_init=0, moving_var_init=1) | |||
| def _fc(in_channel, out_channel, damping, loss_scale, frequency): | |||
| weight_shape = (out_channel, in_channel) | |||
| weight = Tensor(kaiming_uniform(weight_shape, a = math.sqrt(5)) | |||
| weight = Tensor(kaiming_uniform(weight_shape, a=math.sqrt(5)) | |||
| return Dense_Thor(in_channel, out_channel, has_bias=False, weight_init=weight, bias_init=0, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| class ResidualBlock(nn.Cell): | |||
| """ | |||
| ResNet V1 residual block definition. | |||
| @@ -133,7 +146,7 @@ class ResidualBlock(nn.Cell): | |||
| >>> ResidualBlock(3, 256, stride=2) | |||
| """ | |||
| expansion = 4 | |||
| def __init__(self, | |||
| in_channel, | |||
| out_channel, | |||
| @@ -142,54 +155,58 @@ class ResidualBlock(nn.Cell): | |||
| loss_scale=1, | |||
| frequency=278): | |||
| super(ResidualBlock, self).__init__() | |||
| channel = out_channel // self.expansion | |||
| self.conv1 = _conv1x1(in_channel, channel, stride=1, damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| self.conv1 = _conv1x1(in_channel, channel, stride=1, damping=damping, loss_scale=loss_scale, | |||
| frequency=frequency) | |||
| self.bn1 = _bn(channel) | |||
| self.conv2 = _conv3x3(channel, channel, stride=stride, damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| self.conv2 = _conv3x3(channel, channel, stride=stride, damping=damping, loss_scale=loss_scale, | |||
| frequency=frequency) | |||
| self.bn2 = _bn(channel) | |||
| self.conv3 = _conv1x1(channel, out_channel, stride=1, damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| self.conv3 = _conv1x1(channel, out_channel, stride=1, damping=damping, loss_scale=loss_scale, | |||
| frequency=frequency) | |||
| self.bn3 = _bn_last(out_channel) | |||
| self.relu = nn.ReLU() | |||
| self.down_sample = False | |||
| if stride != 1 or in_channel != out_channel: | |||
| self.down_sample = True | |||
| self.down_sample_layer = None | |||
| if self.down_sample: | |||
| self.down_sample_layer = nn.SequentialCell([_conv1x1(in_channel, out_channel, stride, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency), | |||
| damping=damping, loss_scale=loss_scale, | |||
| frequency=frequency), | |||
| _bn(out_channel)]) | |||
| self.add = P.TensorAdd() | |||
| def construct(self, x): | |||
| identity = x | |||
| out = self.conv1(x) | |||
| out = self.bn1(out) | |||
| out = self.relu(out) | |||
| out = self.conv2(out) | |||
| out = self.bn2(out) | |||
| out = self.relu(out) | |||
| out = self.conv3(out) | |||
| out = self.bn3(out) | |||
| if self.down_sample: | |||
| identity = self.down_sample_layer(identity) | |||
| out = self.add(out, identity) | |||
| out = self.relu(out) | |||
| return out | |||
| class ResNet(nn.Cell): | |||
| """ | |||
| ResNet architecture. | |||
| @@ -212,7 +229,7 @@ class ResNet(nn.Cell): | |||
| >>> [1, 2, 2, 2], | |||
| >>> 10) | |||
| """ | |||
| def __init__(self, | |||
| block, | |||
| layer_nums, | |||
| @@ -224,15 +241,15 @@ class ResNet(nn.Cell): | |||
| loss_scale, | |||
| frequency): | |||
| super(ResNet, self).__init__() | |||
| if not len(layer_nums) == len(in_channels) == len(out_channels) == 4: | |||
| raise ValueError("the length of layer_num, in_channels, out_channels list must be 4!") | |||
| self.conv1 = _conv7x7(3, 64, stride=2, damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| self.bn1 = _bn(64) | |||
| self.relu = P.ReLU() | |||
| self.maxpool = P.MaxPoolWithArgmax(padding="same", ksize=3, strides=2) | |||
| self.layer1 = self._make_layer(block, | |||
| layer_nums[0], | |||
| in_channel=in_channels[0], | |||
| @@ -253,7 +270,7 @@ class ResNet(nn.Cell): | |||
| layer_nums[2], | |||
| in_channel=in_channels[2], | |||
| out_channel=out_channels[2], | |||
| stride=strides[2],damping=damping, | |||
| stride=strides[2], damping=damping, | |||
| loss_scale=loss_scale, | |||
| frequency=frequency) | |||
| self.layer4 = self._make_layer(block, | |||
| @@ -264,11 +281,11 @@ class ResNet(nn.Cell): | |||
| damping=damping, | |||
| loss_scale=loss_scale, | |||
| frequency=frequency) | |||
| self.mean = P.ReduceMean(keep_dims=True) | |||
| self.flatten = nn.Flatten() | |||
| self.end_point = _fc(out_channels[3], num_classes, damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| def _make_layer(self, block, layer_num, in_channel, out_channel, stride, | |||
| damping, loss_scale, frequency): | |||
| """ | |||
| @@ -288,36 +305,36 @@ class ResNet(nn.Cell): | |||
| >>> _make_layer(ResidualBlock, 3, 128, 256, 2) | |||
| """ | |||
| layers = [] | |||
| resnet_block = block(in_channel, out_channel, stride=stride, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| layers.append(resnet_block) | |||
| for _ in range(1, layer_num): | |||
| resnet_block = block(out_channel, out_channel, stride=1, | |||
| damping=damping, loss_scale=loss_scale, frequency=frequency) | |||
| layers.append(resnet_block) | |||
| return nn.SequentialCell(layers) | |||
| def construct(self, x): | |||
| x = self.conv1(x) | |||
| x = self.bn1(x) | |||
| x = self.relu(x) | |||
| c1, argmax = self.maxpool(x) | |||
| c2 = self.layer1(c1) | |||
| c3 = self.layer2(c2) | |||
| c4 = self.layer3(c3) | |||
| c5 = self.layer4(c4) | |||
| out = self.mean(c5, (2, 3)) | |||
| out = self.flatten(out) | |||
| out = self.end_point(out) | |||
| return out | |||
| def resnet50(class_num=10, damping=0.03, loss_scale=1, frequency=278): | |||
| """ | |||
| Get ResNet50 neural network. | |||
| @@ -13,42 +13,47 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """momentum""" | |||
| import numpy as np | |||
| from mindspore.ops import functional as F, composite as C, operations as P | |||
| import mindspore.common.dtype as mstype | |||
| from cus_ops.cus_matmul_cube_dense_right import CusMatMulCubeDenseRight | |||
| from cus_ops.cus_matmul_cube_fracz_left_cast import CusMatMulCubeFraczLeftCast | |||
| from mindspore.common.initializer import initializer | |||
| from mindspore.common.parameter import Parameter | |||
| from mindspore.common.parameter import ParameterTuple | |||
| from mindspore.common.tensor import Tensor | |||
| import mindspore.common.dtype as mstype | |||
| from mindspore.nn.optim.optimizer import Optimizer | |||
| from mindspore.common.parameter import ParameterTuple | |||
| from mindspore.parallel._utils import _get_device_num, _get_parallel_mode, _get_mirror_mean | |||
| from mindspore.common.initializer import initializer | |||
| from model.grad_reducer_thor import DistributedGradReducerThor | |||
| from cus_ops.cus_matmul_cube_fracz_right_mul import CusMatMulCubeFraczRightMul | |||
| from cus_ops.cus_fused_abs_max1 import CusFusedAbsMax1 | |||
| from cus_ops.cus_matmul_cube_fracz_left_cast import CusMatMulCubeFraczLeftCast | |||
| from mindspore.ops import functional as F, composite as C, operations as P | |||
| from mindspore.parallel._utils import _get_device_num, _get_mirror_mean | |||
| from cus_ops.cus_matmul_cube_dense_left import CusMatMulCubeDenseLeft | |||
| from cus_ops.cus_matmul_cube_dense_right import CusMatMulCubeDenseRight | |||
| from cus_ops.cus_matmul_cube_fracz_right_mul import CusMatMulCubeFraczRightMul | |||
| from model.grad_reducer_thor import DistributedGradReducerThor | |||
| momentum_opt = C.MultitypeFuncGraph("momentum_opt") | |||
| @momentum_opt.register("Function", "Tensor", "Tensor", "Tensor", "Tensor", "Tensor") | |||
| def _tensor_run_opt_ext(opt, learning_rate, momentum, gradient, weight, moment): | |||
| """Apply momentum optimizer to the weight parameter using Tensor.""" | |||
| success = True | |||
| success = F.depend(success, opt(weight, moment, learning_rate, gradient, momentum)) | |||
| return success | |||
| op_add = P.AddN() | |||
| apply_decay = C.MultitypeFuncGraph("apply_decay") | |||
| @apply_decay.register("Number", "Bool", "Tensor", "Tensor") | |||
| def _tensor_apply_decay(weight_decay, if_apply, weight, gradient): | |||
| """Get grad with weight_decay.""" | |||
| if if_apply: | |||
| return op_add((weight * weight_decay, gradient)) | |||
| return gradient | |||
| class THOR(Optimizer): | |||
| def __init__(self, params, learning_rate, momentum, matrix_A, matrix_G, A_inv_max, G_inv_max, weight_decay=0.0, loss_scale=1.0, | |||
| def __init__(self, params, learning_rate, momentum, matrix_A, matrix_G, A_inv_max, G_inv_max, weight_decay=0.0, | |||
| loss_scale=1.0, | |||
| decay_filter=lambda x: x.name not in []): | |||
| super(THOR, self).__init__(learning_rate, params, weight_decay, loss_scale) | |||
| if isinstance(momentum, float) and momentum < 0.0: | |||
| @@ -93,9 +98,10 @@ class THOR(Optimizer): | |||
| self.matrix_A_inv = () | |||
| self.matrix_G_inv = () | |||
| self.matrix_max_inv = () | |||
| for i in range(54): | |||
| self.matrix_max_inv = self.matrix_max_inv + (Parameter(initializer(1, [1], mstype.float32), name="matrix_max"+str(i), requires_grad=False), ) | |||
| self.matrix_max_inv = self.matrix_max_inv + ( | |||
| Parameter(initializer(1, [1], mstype.float32), name="matrix_max" + str(i), requires_grad=False),) | |||
| self.log = P.Log() | |||
| self.exp = P.Exp() | |||
| self.sqrt = P.Sqrt() | |||
| @@ -105,7 +111,7 @@ class THOR(Optimizer): | |||
| self.thor = True | |||
| self.weight_decay = weight_decay * loss_scale | |||
| self.decay_flags = tuple(decay_filter(x) for x in self.parameters) | |||
| def construct(self, gradients): | |||
| params = self.params | |||
| moments = self.moments | |||
| @@ -124,9 +130,9 @@ class THOR(Optimizer): | |||
| matrix_G = F.depend(matrix_G, g) | |||
| A_max = F.depend(A_max, g) | |||
| G_max = F.depend(G_max, g) | |||
| matrix_A_allreduce = matrix_A_allreduce + (matrix_A, ) | |||
| matrix_G_allreduce = matrix_G_allreduce + (matrix_G, ) | |||
| matrix_A_max_allreduce = matrix_A_max_allreduce + (A_max, ) | |||
| matrix_A_allreduce = matrix_A_allreduce + (matrix_A,) | |||
| matrix_G_allreduce = matrix_G_allreduce + (matrix_G,) | |||
| matrix_A_max_allreduce = matrix_A_max_allreduce + (A_max,) | |||
| matrix_G_max_allreduce = matrix_G_max_allreduce + (G_max,) | |||
| matrix_A_allreduce = self.grad_reducer_A(matrix_A_allreduce) | |||
| matrix_G_allreduce = self.grad_reducer_G(matrix_G_allreduce) | |||
| @@ -182,13 +188,13 @@ class THOR(Optimizer): | |||
| new_grads = new_grads + (g,) | |||
| else: | |||
| g = self.cube_matmul_left(matrix_G, g) | |||
| g =self.cube_matmul_right_mul(g, matrix_A, matrix_max) | |||
| g = self.cube_matmul_right_mul(g, matrix_A, matrix_max) | |||
| new_grads = new_grads + (g, gradients[i * 3 + 1], gradients[i * 3 + 2]) | |||
| gradients = new_grads | |||
| if self.weight_decay > 0: | |||
| gradients = self.hyper_map(F.partial(apply_decay, self.weight_decay), self.decay_flags, | |||
| params, gradients) | |||
| params, gradients) | |||
| gradients = self.scale_grad(gradients) | |||
| lr = self.get_lr() | |||
| success = self.hyper_map(F.partial(momentum_opt, self.opt, lr, self.momentum), gradients, params, moments) | |||
| @@ -13,27 +13,29 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| import numpy as np | |||
| import mindspore as ms | |||
| import mindspore.common.dtype as mstype | |||
| from mindspore.ops import operations as P | |||
| from mindspore.common.parameter import Parameter | |||
| from mindspore.common.initializer import initializer | |||
| import numpy as np | |||
| from mindspore._checkparam import check_bool, twice, check_int_positive | |||
| from mindspore.nn.cell import Cell | |||
| from mindspore.ops import functional as F | |||
| from mindspore._extends import cell_attr_register | |||
| from mindspore.common.initializer import initializer | |||
| from mindspore.common.parameter import Parameter | |||
| from mindspore.common.tensor import Tensor | |||
| from mindspore.nn.cell import Cell | |||
| from mindspore.nn.layer.activation import get_activation | |||
| from mindspore._extends import cell_attr_register | |||
| from cus_ops.cus_matmul_cube import CusMatMulCube | |||
| from cus_ops.cus_matrix_combine import CusMatrixCombine | |||
| from mindspore.ops import operations as P | |||
| from cus_ops.cus_batch_matmul import CusBatchMatMul | |||
| from cus_ops.cus_cholesky_trsm import CusCholeskyTrsm | |||
| from cus_ops.cus_img2col import CusImg2Col | |||
| from cus_ops.cus_fused_abs_max1 import CusFusedAbsMax1 | |||
| from cus_ops.cus_batch_matmul import CusBatchMatMul | |||
| from cus_ops.cus_img2col import CusImg2Col | |||
| from cus_ops.cus_matmul_cube import CusMatMulCube | |||
| from cus_ops.cus_matrix_combine import CusMatrixCombine | |||
| from cus_ops.cus_transpose02314 import CusTranspose02314 | |||
| C0 = 16 | |||
| def caculate_device_shape(matrix_dim, channel, is_A): | |||
| if is_A: | |||
| if channel // C0 == 0: | |||
| @@ -41,11 +43,13 @@ def caculate_device_shape(matrix_dim, channel, is_A): | |||
| return (int(matrix_dim // C0), int(matrix_dim // C0), C0, C0), int(matrix_dim) | |||
| else: | |||
| return (int(matrix_dim // C0), int(matrix_dim // C0), C0, C0), int(matrix_dim) | |||
| class _Conv(Cell): | |||
| r"""Applies a N-D convolution over an input signal composed of several input | |||
| planes. | |||
| """ | |||
| def __init__(self, | |||
| in_channels, | |||
| out_channels, | |||
| @@ -73,23 +77,23 @@ class _Conv(Cell): | |||
| self.has_bias = has_bias | |||
| if not (isinstance(in_channels, int) and in_channels > 0): | |||
| raise ValueError('Attr \'in_channels\' of \'Conv2D\' Op passed ' | |||
| +str(in_channels)+ ', should be a int and greater than 0.') | |||
| + str(in_channels) + ', should be a int and greater than 0.') | |||
| if (not isinstance(kernel_size, tuple)) or len(kernel_size) != 2 or \ | |||
| (not isinstance(kernel_size[0], int)) or (not isinstance(kernel_size[1], int)) or \ | |||
| (not isinstance(kernel_size[0], int)) or (not isinstance(kernel_size[1], int)) or \ | |||
| kernel_size[0] < 1 or kernel_size[1] < 1: | |||
| raise ValueError('Attr \'kernel_size\' of \'Conv2D\' Op passed ' | |||
| +str(self.kernel_size)+', should be a int or tuple and equal to or greater than 1.') | |||
| + str(self.kernel_size) + ', should be a int or tuple and equal to or greater than 1.') | |||
| if in_channels % group != 0: | |||
| raise ValueError('Attr \'in_channels\' of \'Conv2D\' Op must be divisible by ' | |||
| 'attr \'group\' of \'Conv2D\' Op.') | |||
| if out_channels % group != 0: | |||
| raise ValueError('Attr \'out_channels\' of \'Conv2D\' Op must be divisible by ' | |||
| 'attr \'group\' of \'Conv2D\' Op.') | |||
| self.weight = Parameter(initializer( | |||
| weight_init, [out_channels, in_channels // group, *kernel_size]), | |||
| name='weight') | |||
| name='weight') | |||
| if check_bool(has_bias): | |||
| self.bias = Parameter(_initializer( | |||
| bias_init, [out_channels]), name='bias') | |||
| @@ -97,10 +101,11 @@ class _Conv(Cell): | |||
| if bias_init != 'zeros': | |||
| logger.warning("Value of 'has_bias' is False, value of 'bias_init' will be ignored.") | |||
| self.bias = None | |||
| def construct(self, *inputs): | |||
| raise NotImplementedError | |||
| class Conv2d_Thor(_Conv): | |||
| def __init__(self, | |||
| in_channels, | |||
| @@ -120,7 +125,7 @@ class Conv2d_Thor(_Conv): | |||
| bias_init='zeros'): | |||
| self.thor = True | |||
| ksizes = (1, kernel_size, kernel_size, 1) | |||
| self.hw = kernel_size*kernel_size | |||
| self.hw = kernel_size * kernel_size | |||
| strides = (1, stride, stride, 1) | |||
| kernel_size = twice(kernel_size) | |||
| super(Conv2d_Thor, self).__init__( | |||
| @@ -146,26 +151,37 @@ class Conv2d_Thor(_Conv): | |||
| dilation=self.dilation, | |||
| group=self.group | |||
| ) | |||
| self.img2col = CusImg2Col(ksizes = ksizes, strides = strides) | |||
| self.img2col = CusImg2Col(ksizes=ksizes, strides=strides) | |||
| self.cube_matmul = CusMatMulCube(transpose_a=True) | |||
| self.matrix_combine = CusMatrixCombine() | |||
| self.cholesky = CusCholeskyTrsm() | |||
| self.transpose02314 = CusTranspose02314() | |||
| self.matrix_A_dim = self.in_channels*self.kernel_size[0]*self.kernel_size[1] | |||
| self.matrix_A_dim = self.in_channels * self.kernel_size[0] * self.kernel_size[1] | |||
| self.matrix_G_dim = self.out_channels | |||
| self.matrix_A_device_shape, self.matrix_A_device_dim = caculate_device_shape(self.matrix_A_dim, self.in_channels, True) | |||
| self.matrix_G_device_shape, self.matrix_G_device_dim = caculate_device_shape(self.matrix_G_dim, self.in_channels, False) | |||
| self.matrix_A_device_temp_shape = (self.matrix_A_device_shape[0], self.matrix_A_device_shape[2], self.matrix_A_device_shape[1], self.matrix_A_device_shape[3]) | |||
| self.matrix_G_device_temp_shape = (self.matrix_G_device_shape[0], self.matrix_G_device_shape[2], self.matrix_G_device_shape[1], self.matrix_G_device_shape[3]) | |||
| self.matrix_A_inv = Parameter(Tensor(np.reshape(np.identity(self.matrix_A_device_dim).astype(np.float16), self.matrix_A_device_shape)), name='matrix_A_inv', requires_grad=False) | |||
| self.matrix_A_device_shape, self.matrix_A_device_dim = caculate_device_shape(self.matrix_A_dim, | |||
| self.in_channels, True) | |||
| self.matrix_G_device_shape, self.matrix_G_device_dim = caculate_device_shape(self.matrix_G_dim, | |||
| self.in_channels, False) | |||
| self.matrix_A_device_temp_shape = ( | |||
| self.matrix_A_device_shape[0], self.matrix_A_device_shape[2], self.matrix_A_device_shape[1], | |||
| self.matrix_A_device_shape[3]) | |||
| self.matrix_G_device_temp_shape = ( | |||
| self.matrix_G_device_shape[0], self.matrix_G_device_shape[2], self.matrix_G_device_shape[1], | |||
| self.matrix_G_device_shape[3]) | |||
| self.matrix_A_inv = Parameter( | |||
| Tensor(np.reshape(np.identity(self.matrix_A_device_dim).astype(np.float16), self.matrix_A_device_shape)), | |||
| name='matrix_A_inv', requires_grad=False) | |||
| self.A_inv_max = Parameter(initializer(0, [1], mstype.float32), name="A_inv_max", requires_grad=False) | |||
| self.matrix_G_inv = Parameter(Tensor(np.reshape(np.identity(self.matrix_G_device_dim).astype(np.float16), self.matrix_G_device_shape)), name="matrix_G_inv", requires_grad=False) | |||
| self.matrix_G_inv = Parameter( | |||
| Tensor(np.reshape(np.identity(self.matrix_G_device_dim).astype(np.float16), self.matrix_G_device_shape)), | |||
| name="matrix_G_inv", requires_grad=False) | |||
| self.G_inv_max = Parameter(initializer(0, [1], mstype.float32), name="G_inv_max", requires_grad=False) | |||
| self.fake_G = Tensor(np.reshape(np.identity(self.matrix_G_device_dim).astype(np.float16), self.matrix_G_device_shape)) | |||
| self.fake_G_inv_max = Tensor(np.zeros([1,]).astype(np.float32)) | |||
| self.fake_G = Tensor( | |||
| np.reshape(np.identity(self.matrix_G_device_dim).astype(np.float16), self.matrix_G_device_shape)) | |||
| self.fake_G_inv_max = Tensor(np.zeros([1, ]).astype(np.float32)) | |||
| self.shape = P.Shape() | |||
| self.reshape = P.Reshape() | |||
| self.transpose = P.Transpose() | |||
| @@ -178,9 +194,10 @@ class Conv2d_Thor(_Conv): | |||
| self.channels_slice_flag = False | |||
| if self.in_channels % C0 != 0: | |||
| self.channels_slice_flag = True | |||
| self.padA_flag = False | |||
| if (self.matrix_A_dim // self.diag_block_dim) * self.diag_block_dim != self.matrix_A_dim and self.matrix_A_dim > self.diag_block_dim: | |||
| if ( | |||
| self.matrix_A_dim // self.diag_block_dim) * self.diag_block_dim != self.matrix_A_dim and self.matrix_A_dim > self.diag_block_dim: | |||
| self.padA_flag = True | |||
| pad_dim = self.diag_block_dim - self.matrix_A_dim % self.diag_block_dim | |||
| self.padA = P.Pad(((0, pad_dim), (0, pad_dim))) | |||
| @@ -191,16 +208,16 @@ class Conv2d_Thor(_Conv): | |||
| self.slice = P.Slice() | |||
| self.gather = P.GatherV2() | |||
| self.freq = Tensor(frequency, mstype.int32) | |||
| self.loss_scale = Tensor(1/loss_scale, mstype.float16) | |||
| self.loss_scale = Tensor(1 / loss_scale, mstype.float16) | |||
| self.axis = 0 | |||
| dampingA_dim = self.matrix_A_dim | |||
| if (self.matrix_A_dim % self.diag_block_dim) != 0 and self.matrix_A_dim > self.diag_block_dim: | |||
| dampingA_dim = (self.matrix_A_dim // self.diag_block_dim + 1) * self.diag_block_dim | |||
| dampingG_dim = self.matrix_G_dim | |||
| if (self.matrix_G_dim % self.diag_block_dim) != 0 and self.matrix_G_dim > self.diag_block_dim: | |||
| dampingG_dim = (self.matrix_G_dim // self.diag_block_dim + 1) * self.diag_block_dim | |||
| self.dampingA = Tensor(np.identity(dampingA_dim), mstype.float32) | |||
| self.dampingG = Tensor(np.identity(dampingG_dim), mstype.float32) | |||
| self.fused_abs_max1 = CusFusedAbsMax1([self.matrix_A_dim, self.matrix_A_dim]) | |||
| @@ -211,50 +228,50 @@ class Conv2d_Thor(_Conv): | |||
| self.getG = P.InsertGradientOf(self.save_gradient) | |||
| def save_gradient(self, dout): | |||
| out = dout | |||
| dout = self.mul(dout, self.loss_scale) | |||
| dout = self.mul(dout, 32.0) | |||
| dout = self.transpose02314(dout) | |||
| dout_shape = self.shape(dout) | |||
| normalizer = dout_shape[0] | |||
| matrix_G = self.cube_matmul(dout, dout) | |||
| normalizer = self.cast(normalizer, ms.float32) | |||
| matrix_G = self.mul(matrix_G, 1.0/normalizer) | |||
| damping_step = self.gather(self.damping, self.cov_step, 0) | |||
| self.cov_step = self.cov_step + self.freq | |||
| damping_step = self.cast(damping_step, mstype.float32) | |||
| damping = self.mul(damping_step, 32.0/normalizer) | |||
| damping = self.sqrt(damping) | |||
| dampingG = self.cast(self.dampingG, mstype.float32) | |||
| matrix_G = matrix_G + damping * dampingG | |||
| matrix_G_inv = self.cholesky(matrix_G) | |||
| matrix_G_inv = self.vector_matmul(matrix_G_inv, matrix_G_inv) | |||
| matrix_G_inv_max = self.fused_abs_max2(matrix_G_inv) | |||
| matrix_G_inv_max = self.fused_abs_max2(matrix_G_inv_max) | |||
| self.G_inv_max = matrix_G_inv_max | |||
| matrix_G_inv = self.matrix_combine(matrix_G_inv) | |||
| matrix_G_inv_shape = self.shape(matrix_G_inv) | |||
| matrix_G_inv = self.reshape(matrix_G_inv, self.matrix_G_device_temp_shape) | |||
| matrix_G_inv = self.transpose(matrix_G_inv, (2, 0, 1, 3)) | |||
| matrix_G = self.cast(matrix_G_inv, mstype.float16) | |||
| self.matrix_G_inv = matrix_G | |||
| return out | |||
| out = dout | |||
| dout = self.mul(dout, self.loss_scale) | |||
| dout = self.mul(dout, 32.0) | |||
| dout = self.transpose02314(dout) | |||
| dout_shape = self.shape(dout) | |||
| normalizer = dout_shape[0] | |||
| matrix_G = self.cube_matmul(dout, dout) | |||
| normalizer = self.cast(normalizer, ms.float32) | |||
| matrix_G = self.mul(matrix_G, 1.0 / normalizer) | |||
| damping_step = self.gather(self.damping, self.cov_step, 0) | |||
| self.cov_step = self.cov_step + self.freq | |||
| damping_step = self.cast(damping_step, mstype.float32) | |||
| damping = self.mul(damping_step, 32.0 / normalizer) | |||
| damping = self.sqrt(damping) | |||
| dampingG = self.cast(self.dampingG, mstype.float32) | |||
| matrix_G = matrix_G + damping * dampingG | |||
| matrix_G_inv = self.cholesky(matrix_G) | |||
| matrix_G_inv = self.vector_matmul(matrix_G_inv, matrix_G_inv) | |||
| matrix_G_inv_max = self.fused_abs_max2(matrix_G_inv) | |||
| matrix_G_inv_max = self.fused_abs_max2(matrix_G_inv_max) | |||
| self.G_inv_max = matrix_G_inv_max | |||
| matrix_G_inv = self.matrix_combine(matrix_G_inv) | |||
| matrix_G_inv_shape = self.shape(matrix_G_inv) | |||
| matrix_G_inv = self.reshape(matrix_G_inv, self.matrix_G_device_temp_shape) | |||
| matrix_G_inv = self.transpose(matrix_G_inv, (2, 0, 1, 3)) | |||
| matrix_G = self.cast(matrix_G_inv, mstype.float16) | |||
| self.matrix_G_inv = matrix_G | |||
| return out | |||
| def construct(self, x): | |||
| if self.thor: | |||
| matrix_A = self.img2col(x) | |||
| matrix_A_shape = self.shape(matrix_A) | |||
| normalizer = matrix_A_shape[0] | |||
| matrix_A = self.cube_matmul(matrix_A, matrix_A) | |||
| if self.channels_slice_flag: | |||
| matrix_A = self.reshape(matrix_A, (self.hw, C0, self.hw, C0)) | |||
| matrix_A = self.slice(matrix_A, (0, 0, 0, 0), (self.hw, self.in_channels, self.hw, self.in_channels)) | |||
| matrix_A = self.reshape(matrix_A, (self.matrix_A_dim, self.matrix_A_dim)) | |||
| normalizer = self.cast(normalizer, ms.float32) | |||
| matrix_A = self.mul(matrix_A, 1.0/normalizer) | |||
| matrix_A = self.mul(matrix_A, 1.0 / normalizer) | |||
| if self.padA_flag: | |||
| matrix_A = self.padA(matrix_A) | |||
| damping_step = self.gather(self.damping, self.cov_step, self.axis) | |||
| @@ -273,7 +290,7 @@ class Conv2d_Thor(_Conv): | |||
| in_channels = self.in_channels | |||
| if self.padA_flag: | |||
| matrix_A_inv = self.slice(matrix_A_inv, (0, 0), (self.matrix_A_dim, self.matrix_A_dim)) | |||
| if self.device_shape_pad_flag: | |||
| matrix_A_inv = self.reshape(matrix_A_inv, (self.hw, self.in_channels, self.hw, self.in_channels)) | |||
| matrix_A_inv = self.device_shape_pad(matrix_A_inv) | |||
| @@ -286,31 +303,32 @@ class Conv2d_Thor(_Conv): | |||
| out = self.getG(out) | |||
| else: | |||
| out = self.conv2d(x, self.weight) | |||
| return out | |||
| def extra_repr(self): | |||
| s = 'input_channels={}, output_channels={}, kernel_size={},' \ | |||
| 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ | |||
| 'stride={}, pad_mode={}, padding={}, dilation={}, ' \ | |||
| 'group={}, data_format={}, has_bias={},' \ | |||
| 'weight_init={}, bias_init={}'.format( | |||
| self.in_channels, | |||
| self.out_channels, | |||
| self.kernel_size, | |||
| self.stride, | |||
| self.pad_mode, | |||
| self.padding, | |||
| self.dilation, | |||
| self.group, | |||
| self.data_format, | |||
| self.has_bias, | |||
| self.weight, | |||
| self.bias) | |||
| 'weight_init={}, bias_init={}'.format( | |||
| self.in_channels, | |||
| self.out_channels, | |||
| self.kernel_size, | |||
| self.stride, | |||
| self.pad_mode, | |||
| self.padding, | |||
| self.dilation, | |||
| self.group, | |||
| self.data_format, | |||
| self.has_bias, | |||
| self.weight, | |||
| self.bias) | |||
| if self.has_bias: | |||
| s += ', bias={}'.format(self.bias) | |||
| return s | |||
| class Dense_Thor(Cell): | |||
| @cell_attr_register(attrs=['has_bias', 'activation']) | |||
| def __init__(self, | |||
| @@ -330,30 +348,30 @@ class Dense_Thor(Cell): | |||
| self.thor = True | |||
| if isinstance(weight_init, Tensor): | |||
| if weight_init.dim() != 2 or weight_init.shape()[0] != out_channels or \ | |||
| weight_init.shape()[1] != in_channels: | |||
| weight_init.shape()[1] != in_channels: | |||
| raise ValueError("weight_init shape error") | |||
| self.weight = Parameter(initializer(weight_init, [out_channels, in_channels]), name="weight") | |||
| if self.has_bias: | |||
| if isinstance(bias_init, Tensor): | |||
| if bias_init.dim() != 1 or bias_init.shape()[0] != out_channels: | |||
| raise ValueError("bias_init shape error") | |||
| self.bias = Parameter(initializer(bias_init, [out_channels]), name="bias") | |||
| self.matmul = P.MatMul(transpose_b=True) | |||
| self.bias_add = P.BiasAdd() | |||
| self.activation = get_activation(activation) | |||
| self.activation_flag = self.activation is not None | |||
| self.matrix_A_inv = Parameter(Tensor(np.zeros([128, 128, 16, 16]).astype(np.float16)), name='matrix_A_inv', | |||
| requires_grad=False) | |||
| self.matrix_G_inv = Parameter(Tensor(np.zeros([63, 63, 16, 16]).astype(np.float16)), name="matrix_G_inv", | |||
| requires_grad=False) | |||
| self.fake_G = Tensor(np.zeros([63, 63, 16, 16]).astype(np.float16)) | |||
| self.matmul = P.MatMul(transpose_b=True) | |||
| self.cube_matmul = CusMatMulCube(transpose_a=True) | |||
| self.matrix_combine = CusMatrixCombine() | |||
| @@ -365,7 +383,7 @@ class Dense_Thor(Cell): | |||
| self.mul = P.Mul() | |||
| self.cast = P.Cast() | |||
| self.damping = Tensor(damping) | |||
| self.loss_scale = Tensor(1/loss_scale, mstype.float16) | |||
| self.loss_scale = Tensor(1 / loss_scale, mstype.float16) | |||
| self.vector_matmul = CusBatchMatMul() | |||
| self.pad = P.Pad(((0, 24), (0, 24))) | |||
| self.pad1 = P.Pad(((0, 8), (0, 8))) | |||
| @@ -415,14 +433,14 @@ class Dense_Thor(Cell): | |||
| matrix_G_inv = self.cast(matrix_G_inv, mstype.float16) | |||
| self.matrix_G_inv = matrix_G_inv | |||
| return out | |||
| def construct(self, x): | |||
| if self.thor: | |||
| inputs = self.cube_matmul(x, x) | |||
| normalizer = 32 | |||
| normalizer = self.cast(normalizer, ms.float32) | |||
| matrix_A = self.mul(inputs, 1.0 / normalizer) | |||
| damping_step = self.gather(self.damping, self.cov_step, self.axis) | |||
| damping_step = self.cast(damping_step, mstype.float32) | |||
| damping = self.sqrt(damping_step) | |||
| @@ -430,11 +448,11 @@ class Dense_Thor(Cell): | |||
| matrix_A = matrix_A + damping * dampingA | |||
| matrix_A_inv = self.cholesky(matrix_A) | |||
| matrix_A_inv = self.vector_matmul(matrix_A_inv, matrix_A_inv) | |||
| matrix_A_inv_max = self.fused_abs_max2(matrix_A_inv) | |||
| matrix_A_inv_max = self.fused_abs_max2(matrix_A_inv_max) | |||
| self.A_inv_max = matrix_A_inv_max | |||
| matrix_A_inv = self.matrix_combine(matrix_A_inv) | |||
| matrix_A_inv_shape = self.shape(matrix_A_inv) | |||
| matrix_A_inv = self.reshape(matrix_A_inv, (matrix_A_inv_shape[0] / 16, 16, matrix_A_inv_shape[0] / 16, 16)) | |||
| @@ -446,20 +464,20 @@ class Dense_Thor(Cell): | |||
| output = self.getG(output) | |||
| else: | |||
| output = self.matmul(x, self.weight) | |||
| if self.has_bias: | |||
| output = self.bias_add(output, self.bias) | |||
| if self.activation_flag: | |||
| return self.activation(output) | |||
| return output | |||
| def extend_repr(self): | |||
| str_info = 'in_channels={}, out_channels={}, weight={}, has_bias={}' \ | |||
| .format(self.in_channels, self.out_channels, self.weight, self.has_bias) | |||
| .format(self.in_channels, self.out_channels, self.weight, self.has_bias) | |||
| if self.has_bias: | |||
| str_info = str_info + ', bias={}'.format(self.bias) | |||
| if self.activation_flag: | |||
| str_info = str_info + ', activation={}'.format(self.activation) | |||
| return str_info | |||
| @@ -13,62 +13,54 @@ | |||
| # limitations under the License. | |||
| # ============================================================================ | |||
| """train_imagenet.""" | |||
| import os | |||
| import argparse | |||
| import os | |||
| import random | |||
| import mindspore.dataset.engine as de | |||
| import numpy as np | |||
| from dataset_imagenet import create_dataset | |||
| from lr_generator import get_lr, warmup_cosine_annealing_lr | |||
| from config_imagenet import config | |||
| from mindspore import context | |||
| from mindspore import Tensor | |||
| from mindspore import context | |||
| from mindspore.communication.management import init | |||
| from mindspore.parallel._auto_parallel_context import auto_parallel_context | |||
| from mindspore.nn.optim.momentum import Momentum | |||
| from mindspore.nn.loss import SoftmaxCrossEntropyWithLogits | |||
| from mindspore.train.model import ParallelMode | |||
| from mindspore.train.callback import ModelCheckpoint, CheckpointConfig, LossMonitor, TimeMonitor | |||
| from mindspore.train.loss_scale_manager import FixedLossScaleManager | |||
| import mindspore.dataset.engine as de | |||
| from mindspore.communication.management import init | |||
| import math | |||
| import mindspore.nn as nn | |||
| from crossentropy import CrossEntropy | |||
| from var_init import default_recurisive_init, KaimingNormal | |||
| from mindspore.common import initializer as weight_init | |||
| from second_order.thor import THOR | |||
| from mindspore.train.model import ParallelMode | |||
| from second_order.model_second_order import Model | |||
| from second_order.resnet import resnet50 | |||
| from mindspore.train.serialization import load_checkpoint, load_param_into_net | |||
| from second_order.thor import THOR | |||
| from config_imagenet import config | |||
| from crossentropy import CrossEntropy | |||
| from dataset_imagenet import create_dataset | |||
| from lr_generator import get_lr, warmup_cosine_annealing_lr | |||
| random.seed(1) | |||
| np.random.seed(1) | |||
| de.config.set_seed(1) | |||
| parser = argparse.ArgumentParser(description='Image classification') | |||
| parser.add_argument('--run_distribute', type=bool, default=False, help='Run distribute') | |||
| parser.add_argument('--device_num', type=int, default=1, help='Device num.') | |||
| parser.add_argument('--do_train', type=bool, default=True, help='Do train or not.') | |||
| parser.add_argument('--do_eval', type=bool, default=False, help='Do eval or not.') | |||
| parser.add_argument('--dataset_path', type=str, default=None, help='Dataset path') | |||
| args_opt = parser.parse_args() | |||
| device_id = int(os.getenv('DEVICE_ID')) | |||
| context.set_context(mode=context.GRAPH_MODE, device_target="Ascend", save_graphs=True, device_id=device_id) | |||
| context.set_context(enable_task_sink=True) | |||
| context.set_context(enable_loop_sink=True) | |||
| context.set_context(enable_mem_reuse=True) | |||
| def get_second_order_lr(global_step, lr_init, decay, total_epochs, steps_per_epoch): | |||
| lr_each_step = [] | |||
| total_steps = steps_per_epoch * total_epochs | |||
| for i in range(total_steps): | |||
| epoch = (i+1)/steps_per_epoch | |||
| base = (1.0 - float(epoch)/total_epochs)**decay | |||
| epoch = (i + 1) / steps_per_epoch | |||
| base = (1.0 - float(epoch) / total_epochs) ** decay | |||
| lr = lr_init * base | |||
| lr_each_step.append(lr) | |||
| current_step = global_step | |||
| @@ -77,11 +69,12 @@ def get_second_order_lr(global_step, lr_init, decay, total_epochs, steps_per_epo | |||
| learning_rate = lr_each_step[current_step:] | |||
| return learning_rate | |||
| def get_second_order_damping(global_step, damping_init, decay_rate, total_epochs, steps_per_epoch): | |||
| damping_each_step = [] | |||
| total_steps = steps_per_epoch * total_epochs | |||
| for step in range(total_steps): | |||
| epoch = (step+1) / steps_per_epoch | |||
| epoch = (step + 1) / steps_per_epoch | |||
| damping = damping_init * (decay_rate ** (epoch / 10)) | |||
| damping_each_step.append(damping) | |||
| @@ -91,6 +84,7 @@ def get_second_order_damping(global_step, damping_init, decay_rate, total_epochs | |||
| print("damping_is=========", damping) | |||
| return damping | |||
| if __name__ == '__main__': | |||
| if args_opt.do_eval: | |||
| print("eval") | |||
| @@ -104,7 +98,7 @@ if __name__ == '__main__': | |||
| init() | |||
| else: | |||
| print(" ") | |||
| epoch_size = config.epoch_size | |||
| damping = get_second_order_damping(0, 0.03, 0.87, 50, 5004) | |||
| net = resnet50(class_num=config.class_num, damping=damping, loss_scale=config.loss_scale, | |||
| @@ -128,8 +122,8 @@ if __name__ == '__main__': | |||
| config.eta_min)) | |||
| else: | |||
| lr = Tensor(get_lr(global_step=0, lr_init=config.lr_init, lr_end=config.lr_end, lr_max=config.lr_max, | |||
| warmup_epochs=config.warmup_epochs, total_epochs=epoch_size, steps_per_epoch=step_size, | |||
| lr_decay_mode='poly')) | |||
| warmup_epochs=config.warmup_epochs, total_epochs=epoch_size, steps_per_epoch=step_size, | |||
| lr_decay_mode='poly')) | |||
| opt = THOR(filter(lambda x: x.requires_grad, net.get_parameters()), lr, | |||
| config.momentum, damping, config.frequency, | |||
| filter(lambda x: 'matrix_A' in x.name, net.get_parameters()), | |||
| @@ -137,8 +131,9 @@ if __name__ == '__main__': | |||
| filter(lambda x: 'spatial_norm' in x.name, net.get_parameters()), | |||
| config.weight_decay, config.loss_scale) | |||
| model = Model(net, loss_fn=loss, optimizer=opt, amp_level='O2', loss_scale_manager=loss_scale, keep_batchnorm_fp32=False, metrics={'acc'}, frequency=config.frequency) | |||
| model = Model(net, loss_fn=loss, optimizer=opt, amp_level='O2', loss_scale_manager=loss_scale, | |||
| keep_batchnorm_fp32=False, metrics={'acc'}, frequency=config.frequency) | |||
| time_cb = TimeMonitor(data_size=step_size) | |||
| loss_cb = LossMonitor() | |||
| cb = [time_cb, loss_cb] | |||