/** * 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. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "minddata/dataset/include/transforms.h" #include "minddata/dataset/include/vision.h" #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/image_utils.h" #endif // Kernel image headers (in alphabetical order) #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/auto_contrast_op.h" #include "minddata/dataset/kernels/image/bounding_box_augment_op.h" #endif #include "minddata/dataset/kernels/image/center_crop_op.h" #include "minddata/dataset/kernels/image/crop_op.h" #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/cutmix_batch_op.h" #include "minddata/dataset/kernels/image/cut_out_op.h" #endif #include "minddata/dataset/kernels/image/decode_op.h" #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/equalize_op.h" #include "minddata/dataset/kernels/image/hwc_to_chw_op.h" #include "minddata/dataset/kernels/image/invert_op.h" #include "minddata/dataset/kernels/image/mixup_batch_op.h" #endif #include "minddata/dataset/kernels/image/normalize_op.h" #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/pad_op.h" #include "minddata/dataset/kernels/image/random_affine_op.h" #include "minddata/dataset/kernels/image/random_color_op.h" #include "minddata/dataset/kernels/image/random_color_adjust_op.h" #include "minddata/dataset/kernels/image/random_crop_and_resize_op.h" #include "minddata/dataset/kernels/image/random_crop_op.h" #include "minddata/dataset/kernels/image/random_crop_decode_resize_op.h" #include "minddata/dataset/kernels/image/random_crop_with_bbox_op.h" #include "minddata/dataset/kernels/image/random_crop_and_resize_with_bbox_op.h" #include "minddata/dataset/kernels/image/random_horizontal_flip_op.h" #include "minddata/dataset/kernels/image/random_horizontal_flip_with_bbox_op.h" #include "minddata/dataset/kernels/image/random_posterize_op.h" #include "minddata/dataset/kernels/image/random_resize_op.h" #include "minddata/dataset/kernels/image/random_resize_with_bbox_op.h" #include "minddata/dataset/kernels/image/random_rotation_op.h" #include "minddata/dataset/kernels/image/random_select_subpolicy_op.h" #include "minddata/dataset/kernels/image/random_sharpness_op.h" #include "minddata/dataset/kernels/image/random_solarize_op.h" #include "minddata/dataset/kernels/image/random_vertical_flip_op.h" #include "minddata/dataset/kernels/image/random_vertical_flip_with_bbox_op.h" #include "minddata/dataset/kernels/image/rescale_op.h" #endif #include "minddata/dataset/kernels/image/resize_op.h" #ifndef ENABLE_ANDROID #include "minddata/dataset/kernels/image/resize_with_bbox_op.h" #include "minddata/dataset/kernels/image/rgba_to_bgr_op.h" #include "minddata/dataset/kernels/image/rgba_to_rgb_op.h" #include "minddata/dataset/kernels/image/soft_dvpp/soft_dvpp_decode_random_crop_resize_jpeg_op.h" #include "minddata/dataset/kernels/image/soft_dvpp/soft_dvpp_decode_resize_jpeg_op.h" #include "minddata/dataset/kernels/image/swap_red_blue_op.h" #include "minddata/dataset/kernels/image/uniform_aug_op.h" #endif namespace mindspore { namespace dataset { // Transform operations for computer vision. namespace vision { #ifndef ENABLE_ANDROID // FUNCTIONS TO CREATE VISION TRANSFORM OPERATIONS // (In alphabetical order) // Function to create AutoContrastOperation. std::shared_ptr AutoContrast(float cutoff, std::vector ignore) { auto op = std::make_shared(cutoff, ignore); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create BoundingBoxAugmentOperation. std::shared_ptr BoundingBoxAugment(std::shared_ptr transform, float ratio) { auto op = std::make_shared(transform, ratio); // Input validation return op->ValidateParams() ? op : nullptr; } #endif // Function to create CenterCropOperation. std::shared_ptr CenterCrop(std::vector size) { auto op = std::make_shared(size); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create CropOperation. std::shared_ptr Crop(std::vector coordinates, std::vector size) { auto op = std::make_shared(coordinates, size); // Input validation return op->ValidateParams() ? op : nullptr; } #ifndef ENABLE_ANDROID // Function to create CutMixBatchOperation. std::shared_ptr CutMixBatch(ImageBatchFormat image_batch_format, float alpha, float prob) { auto op = std::make_shared(image_batch_format, alpha, prob); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create CutOutOp. std::shared_ptr CutOut(int32_t length, int32_t num_patches) { auto op = std::make_shared(length, num_patches); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create DecodeOperation. std::shared_ptr Decode(bool rgb) { auto op = std::make_shared(rgb); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create EqualizeOperation. std::shared_ptr Equalize() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create HwcToChwOperation. std::shared_ptr HWC2CHW() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create InvertOperation. std::shared_ptr Invert() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create MixUpBatchOperation. std::shared_ptr MixUpBatch(float alpha) { auto op = std::make_shared(alpha); // Input validation return op->ValidateParams() ? op : nullptr; } #endif // Function to create NormalizeOperation. std::shared_ptr Normalize(std::vector mean, std::vector std) { auto op = std::make_shared(mean, std); // Input validation return op->ValidateParams() ? op : nullptr; } #ifndef ENABLE_ANDROID // Function to create PadOperation. std::shared_ptr Pad(std::vector padding, std::vector fill_value, BorderType padding_mode) { auto op = std::make_shared(padding, fill_value, padding_mode); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomAffineOperation. std::shared_ptr RandomAffine(const std::vector °rees, const std::vector &translate_range, const std::vector &scale_range, const std::vector &shear_ranges, InterpolationMode interpolation, const std::vector &fill_value) { auto op = std::make_shared(degrees, translate_range, scale_range, shear_ranges, interpolation, fill_value); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomColorOperation. std::shared_ptr RandomColor(float t_lb, float t_ub) { auto op = std::make_shared(t_lb, t_ub); // Input validation return op->ValidateParams() ? op : nullptr; } std::shared_ptr RandomColorOperation::Build() { std::shared_ptr tensor_op = std::make_shared(t_lb_, t_ub_); return tensor_op; } // Function to create RandomColorAdjustOperation. std::shared_ptr RandomColorAdjust(std::vector brightness, std::vector contrast, std::vector saturation, std::vector hue) { auto op = std::make_shared(brightness, contrast, saturation, hue); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomCropOperation. std::shared_ptr RandomCrop(std::vector size, std::vector padding, bool pad_if_needed, std::vector fill_value, BorderType padding_mode) { auto op = std::make_shared(size, padding, pad_if_needed, fill_value, padding_mode); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomCropDecodeResizeOperation. std::shared_ptr RandomCropDecodeResize(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) { auto op = std::make_shared(size, scale, ratio, interpolation, max_attempts); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomCropWithBBoxOperation. std::shared_ptr RandomCropWithBBox(std::vector size, std::vector padding, bool pad_if_needed, std::vector fill_value, BorderType padding_mode) { auto op = std::make_shared(size, padding, pad_if_needed, fill_value, padding_mode); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomHorizontalFlipOperation. std::shared_ptr RandomHorizontalFlip(float prob) { auto op = std::make_shared(prob); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomHorizontalFlipOperation. std::shared_ptr RandomHorizontalFlipWithBBox(float prob) { auto op = std::make_shared(prob); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomPosterizeOperation. std::shared_ptr RandomPosterize(const std::vector &bit_range) { auto op = std::make_shared(bit_range); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomResizeOperation. std::shared_ptr RandomResize(std::vector size) { auto op = std::make_shared(size); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomResizeWithBBoxOperation. std::shared_ptr RandomResizeWithBBox(std::vector size) { auto op = std::make_shared(size); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomResizedCropOperation. std::shared_ptr RandomResizedCrop(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) { auto op = std::make_shared(size, scale, ratio, interpolation, max_attempts); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomResizedCropOperation. std::shared_ptr RandomResizedCropWithBBox(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) { auto op = std::make_shared(size, scale, ratio, interpolation, max_attempts); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomRotationOperation. std::shared_ptr RandomRotation(std::vector degrees, InterpolationMode resample, bool expand, std::vector center, std::vector fill_value) { auto op = std::make_shared(degrees, resample, expand, center, fill_value); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomSharpnessOperation. std::shared_ptr RandomSharpness(std::vector degrees) { auto op = std::make_shared(degrees); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomSolarizeOperation. std::shared_ptr RandomSolarize(std::vector threshold) { auto op = std::make_shared(threshold); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomSelectSubpolicyOperation. std::shared_ptr RandomSelectSubpolicy( std::vector, double>>> policy) { auto op = std::make_shared(policy); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomVerticalFlipOperation. std::shared_ptr RandomVerticalFlip(float prob) { auto op = std::make_shared(prob); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RandomVerticalFlipWithBBoxOperation. std::shared_ptr RandomVerticalFlipWithBBox(float prob) { auto op = std::make_shared(prob); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RescaleOperation. std::shared_ptr Rescale(float rescale, float shift) { auto op = std::make_shared(rescale, shift); // Input validation return op->ValidateParams() ? op : nullptr; } #endif // Function to create ResizeOperation. std::shared_ptr Resize(std::vector size, InterpolationMode interpolation) { auto op = std::make_shared(size, interpolation); // Input validation return op->ValidateParams() ? op : nullptr; } #ifndef ENABLE_ANDROID // Function to create ResizeWithBBoxOperation. std::shared_ptr ResizeWithBBox(std::vector size, InterpolationMode interpolation) { auto op = std::make_shared(size, interpolation); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RgbaToBgrOperation. std::shared_ptr RGBA2BGR() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create RgbaToRgbOperation. std::shared_ptr RGBA2RGB() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create SoftDvppDecodeRandomCropResizeJpegOperation. std::shared_ptr SoftDvppDecodeRandomCropResizeJpeg( std::vector size, std::vector scale, std::vector ratio, int32_t max_attempts) { auto op = std::make_shared(size, scale, ratio, max_attempts); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create SoftDvppDecodeResizeJpegOperation. std::shared_ptr SoftDvppDecodeResizeJpeg(std::vector size) { auto op = std::make_shared(size); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create SwapRedBlueOperation. std::shared_ptr SwapRedBlue() { auto op = std::make_shared(); // Input validation return op->ValidateParams() ? op : nullptr; } // Function to create UniformAugOperation. std::shared_ptr UniformAugment(std::vector> transforms, int32_t num_ops) { auto op = std::make_shared(transforms, num_ops); // Input validation return op->ValidateParams() ? op : nullptr; } #endif /* ####################################### Derived TensorOperation classes ################################# */ // (In alphabetical order) #ifndef ENABLE_ANDROID // AutoContrastOperation AutoContrastOperation::AutoContrastOperation(float cutoff, std::vector ignore) : cutoff_(cutoff), ignore_(ignore) {} Status AutoContrastOperation::ValidateParams() { if (cutoff_ < 0 || cutoff_ > 100) { std::string err_msg = "AutoContrast: cutoff has to be between 0 and 100, got: " + std::to_string(cutoff_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (uint32_t single_ignore : ignore_) { if (single_ignore > 255) { std::string err_msg = "AutoContrast: invalid size, ignore has to be between 0 and 255, got: " + std::to_string(single_ignore); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } return Status::OK(); } std::shared_ptr AutoContrastOperation::Build() { std::shared_ptr tensor_op = std::make_shared(cutoff_, ignore_); return tensor_op; } // BoundingBoxAugmentOperation BoundingBoxAugmentOperation::BoundingBoxAugmentOperation(std::shared_ptr transform, float ratio) : transform_(transform), ratio_(ratio) {} Status BoundingBoxAugmentOperation::ValidateParams() { RETURN_IF_NOT_OK(ValidateVectorTransforms("BoundingBoxAugment", {transform_})); RETURN_IF_NOT_OK(ValidateProbability("BoundingBoxAugment", ratio_)); return Status::OK(); } std::shared_ptr BoundingBoxAugmentOperation::Build() { std::shared_ptr tensor_op = std::make_shared(transform_->Build(), ratio_); return tensor_op; } #endif // CenterCropOperation CenterCropOperation::CenterCropOperation(std::vector size) : size_(size) {} Status CenterCropOperation::ValidateParams() { if (size_.empty() || size_.size() > 2) { std::string err_msg = "CenterCrop: size vector has incorrect size."; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // We have to limit crop size due to library restrictions, optimized to only iterate over size_ once for (int32_t i = 0; i < size_.size(); ++i) { if (size_[i] <= 0) { std::string err_msg = "CenterCrop: invalid size, size must be greater than 0, got: " + std::to_string(size_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[i] == INT_MAX) { std::string err_msg = "CenterCrop: invalid size, size too large, got: " + std::to_string(size_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } return Status::OK(); } std::shared_ptr CenterCropOperation::Build() { int32_t crop_height = size_[0]; int32_t crop_width = size_[0]; // User has specified crop_width. if (size_.size() == 2) { crop_width = size_[1]; } std::shared_ptr tensor_op = std::make_shared(crop_height, crop_width); return tensor_op; } // CropOperation. CropOperation::CropOperation(std::vector coordinates, std::vector size) : coordinates_(coordinates), size_(size) {} Status CropOperation::ValidateParams() { // Do some input validation. if (coordinates_.size() != 2) { std::string err_msg = "Crop: coordinates must be a vector of two values"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // we don't check the coordinates here because we don't have access to image dimensions if (size_.empty() || size_.size() > 2) { std::string err_msg = "Crop: size must be a vector of one or two values"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // We have to limit crop size due to library restrictions, optimized to only iterate over size_ once for (int32_t i = 0; i < size_.size(); ++i) { if (size_[i] <= 0) { std::string err_msg = "Crop: invalid size, size must be greater than 0, got: " + std::to_string(size_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[i] == INT_MAX) { std::string err_msg = "Crop: invalid size, size too large, got: " + std::to_string(size_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } for (int32_t j = 0; j < coordinates_.size(); ++j) { if (coordinates_[j] < 0) { std::string err_msg = "Crop: invalid coordinates, coordinates must be greater than 0, got: " + std::to_string(coordinates_[j]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } return Status::OK(); } std::shared_ptr CropOperation::Build() { int32_t x, y, height, width; x = coordinates_[0]; y = coordinates_[1]; height = size_[0]; width = size_[0]; // User has specified crop_width. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared(x, y, height, width); return tensor_op; } #ifndef ENABLE_ANDROID // CutMixBatchOperation CutMixBatchOperation::CutMixBatchOperation(ImageBatchFormat image_batch_format, float alpha, float prob) : image_batch_format_(image_batch_format), alpha_(alpha), prob_(prob) {} Status CutMixBatchOperation::ValidateParams() { if (alpha_ <= 0) { std::string err_msg = "CutMixBatch: alpha must be a positive floating value however it is: " + std::to_string(alpha_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (prob_ < 0 || prob_ > 1) { std::string err_msg = "CutMixBatch: Probability has to be between 0 and 1."; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr CutMixBatchOperation::Build() { std::shared_ptr tensor_op = std::make_shared(image_batch_format_, alpha_, prob_); return tensor_op; } // CutOutOperation CutOutOperation::CutOutOperation(int32_t length, int32_t num_patches) : length_(length), num_patches_(num_patches) {} Status CutOutOperation::ValidateParams() { if (length_ <= 0) { std::string err_msg = "CutOut: length must be positive, got: " + std::to_string(length_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (num_patches_ <= 0) { std::string err_msg = "CutOut: number of patches must be positive, got: " + std::to_string(num_patches_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr CutOutOperation::Build() { std::shared_ptr tensor_op = std::make_shared(length_, length_, num_patches_, false, 0, 0, 0); return tensor_op; } // DecodeOperation DecodeOperation::DecodeOperation(bool rgb) : rgb_(rgb) {} Status DecodeOperation::ValidateParams() { return Status::OK(); } std::shared_ptr DecodeOperation::Build() { return std::make_shared(rgb_); } // EqualizeOperation Status EqualizeOperation::ValidateParams() { return Status::OK(); } std::shared_ptr EqualizeOperation::Build() { return std::make_shared(); } // HwcToChwOperation Status HwcToChwOperation::ValidateParams() { return Status::OK(); } std::shared_ptr HwcToChwOperation::Build() { return std::make_shared(); } // InvertOperation Status InvertOperation::ValidateParams() { return Status::OK(); } std::shared_ptr InvertOperation::Build() { return std::make_shared(); } // MixUpOperation MixUpBatchOperation::MixUpBatchOperation(float alpha) : alpha_(alpha) {} Status MixUpBatchOperation::ValidateParams() { if (alpha_ <= 0) { std::string err_msg = "MixUpBatch: alpha must be a positive floating value however it is: " + std::to_string(alpha_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr MixUpBatchOperation::Build() { return std::make_shared(alpha_); } #endif // NormalizeOperation NormalizeOperation::NormalizeOperation(std::vector mean, std::vector std) : mean_(mean), std_(std) {} Status NormalizeOperation::ValidateParams() { if (mean_.size() != 3) { std::string err_msg = "Normalize: mean vector has incorrect size: " + std::to_string(mean_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (std_.size() != 3) { std::string err_msg = "Normalize: std vector has incorrect size: " + std::to_string(std_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // check std/mean value for (int32_t i = 0; i < std_.size(); ++i) { if (std_[i] < 0.0f || std_[i] > 255.0f || CmpFloat(std_[i], 0.0f)) { std::string err_msg = "Normalize: std vector has incorrect value: " + std::to_string(std_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (mean_[i] < 0.0f || mean_[i] > 255.0f || CmpFloat(mean_[i], 0.0f)) { std::string err_msg = "Normalize: mean vector has incorrect value: " + std::to_string(mean_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } return Status::OK(); } std::shared_ptr NormalizeOperation::Build() { return std::make_shared(mean_[0], mean_[1], mean_[2], std_[0], std_[1], std_[2]); } #ifndef ENABLE_ANDROID // PadOperation PadOperation::PadOperation(std::vector padding, std::vector fill_value, BorderType padding_mode) : padding_(padding), fill_value_(fill_value), padding_mode_(padding_mode) {} Status PadOperation::ValidateParams() { // padding RETURN_IF_NOT_OK(ValidateVectorPadding("Pad", padding_)); // fill_value RETURN_IF_NOT_OK(ValidateVectorFillvalue("Pad", fill_value_)); return Status::OK(); } std::shared_ptr PadOperation::Build() { int32_t pad_top, pad_bottom, pad_left, pad_right; switch (padding_.size()) { case 1: pad_left = padding_[0]; pad_top = padding_[0]; pad_right = padding_[0]; pad_bottom = padding_[0]; break; case 2: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[0]; pad_bottom = padding_[1]; break; default: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[2]; pad_bottom = padding_[3]; } uint8_t fill_r, fill_g, fill_b; fill_r = fill_value_[0]; fill_g = fill_value_[0]; fill_b = fill_value_[0]; if (fill_value_.size() == 3) { fill_r = fill_value_[0]; fill_g = fill_value_[1]; fill_b = fill_value_[2]; } std::shared_ptr tensor_op = std::make_shared(pad_top, pad_bottom, pad_left, pad_right, padding_mode_, fill_r, fill_g, fill_b); return tensor_op; } // RandomAffineOperation RandomAffineOperation::RandomAffineOperation(const std::vector °rees, const std::vector &translate_range, const std::vector &scale_range, const std::vector &shear_ranges, InterpolationMode interpolation, const std::vector &fill_value) : degrees_(degrees), translate_range_(translate_range), scale_range_(scale_range), shear_ranges_(shear_ranges), interpolation_(interpolation), fill_value_(fill_value) { random_op_ = true; } Status RandomAffineOperation::ValidateParams() { // Degrees if (degrees_.size() != 2) { std::string err_msg = "RandomAffine: degrees expecting size 2, got: degrees.size() = " + std::to_string(degrees_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (degrees_[0] > degrees_[1]) { std::string err_msg = "RandomAffine: minimum of degrees range is greater than maximum: min = " + std::to_string(degrees_[0]) + ", max = " + std::to_string(degrees_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // Translate if (translate_range_.size() != 2 && translate_range_.size() != 4) { std::string err_msg = "RandomAffine: translate_range expecting size 2 or 4, got: translate_range.size() = " + std::to_string(translate_range_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_[0] > translate_range_[1]) { std::string err_msg = "RandomAffine: minimum of translate range on x is greater than maximum: min = " + std::to_string(translate_range_[0]) + ", max = " + std::to_string(translate_range_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_[0] < -1 || translate_range_[0] > 1) { std::string err_msg = "RandomAffine: minimum of translate range on x is out of range of [-1, 1], value = " + std::to_string(translate_range_[0]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_[1] < -1 || translate_range_[1] > 1) { std::string err_msg = "RandomAffine: maximum of translate range on x is out of range of [-1, 1], value = " + std::to_string(translate_range_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_.size() == 4) { if (translate_range_[2] > translate_range_[3]) { std::string err_msg = "RandomAffine: minimum of translate range on y is greater than maximum: min = " + std::to_string(translate_range_[2]) + ", max = " + std::to_string(translate_range_[3]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_[2] < -1 || translate_range_[2] > 1) { std::string err_msg = "RandomAffine: minimum of translate range on y is out of range of [-1, 1], value = " + std::to_string(translate_range_[2]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (translate_range_[3] < -1 || translate_range_[3] > 1) { std::string err_msg = "RandomAffine: maximum of translate range on y is out of range of [-1, 1], value = " + std::to_string(translate_range_[3]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } // Scale if (scale_range_.size() != 2) { std::string err_msg = "RandomAffine: scale_range vector has incorrect size: scale_range.size() = " + std::to_string(scale_range_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < scale_range_.size(); ++i) { if (scale_range_[i] <= 0) { std::string err_msg = "RandomAffine: scale must be greater than 0, got: " + std::to_string(fill_value_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (scale_range_[0] > scale_range_[1]) { std::string err_msg = "RandomAffine: minimum of scale range is greater than maximum: min = " + std::to_string(scale_range_[0]) + ", max = " + std::to_string(scale_range_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // Shear if (shear_ranges_.size() != 2 && shear_ranges_.size() != 4) { std::string err_msg = "RandomAffine: shear_ranges expecting size 2 or 4, got: shear_ranges.size() = " + std::to_string(shear_ranges_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (shear_ranges_[0] > shear_ranges_[1]) { std::string err_msg = "RandomAffine: minimum of horizontal shear range is greater than maximum: min = " + std::to_string(shear_ranges_[0]) + ", max = " + std::to_string(shear_ranges_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (shear_ranges_.size() == 4 && shear_ranges_[2] > shear_ranges_[3]) { std::string err_msg = "RandomAffine: minimum of vertical shear range is greater than maximum: min = " + std::to_string(shear_ranges_[2]) + ", max = " + std::to_string(scale_range_[3]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // Fill Value if (fill_value_.size() != 3) { std::string err_msg = "RandomAffine: fill_value vector has incorrect size: fill_value.size() = " + std::to_string(fill_value_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < fill_value_.size(); ++i) { if (fill_value_[i] < 0 || fill_value_[i] > 255) { std::string err_msg = "RandomAffine: fill_value has to be between 0 and 255, got:" + std::to_string(fill_value_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } return Status::OK(); } std::shared_ptr RandomAffineOperation::Build() { if (shear_ranges_.size() == 2) { shear_ranges_.resize(4); } if (translate_range_.size() == 2) { translate_range_.resize(4); } auto tensor_op = std::make_shared(degrees_, translate_range_, scale_range_, shear_ranges_, interpolation_, fill_value_); return tensor_op; } // RandomColorOperation. RandomColorOperation::RandomColorOperation(float t_lb, float t_ub) : t_lb_(t_lb), t_ub_(t_ub) { random_op_ = true; } Status RandomColorOperation::ValidateParams() { // Do some input validation. if (t_lb_ < 0 || t_ub_ < 0) { std::string err_msg = "RandomColor: lower bound or upper bound must be greater than or equal to 0, got t_lb: " + std::to_string(t_lb_) + ", t_ub: " + std::to_string(t_ub_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (t_lb_ > t_ub_) { std::string err_msg = "RandomColor: lower bound must be less or equal to upper bound, got t_lb: " + std::to_string(t_lb_) + ", t_ub: " + std::to_string(t_ub_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } // RandomColorAdjustOperation. RandomColorAdjustOperation::RandomColorAdjustOperation(std::vector brightness, std::vector contrast, std::vector saturation, std::vector hue) : brightness_(brightness), contrast_(contrast), saturation_(saturation), hue_(hue) { random_op_ = true; } Status RandomColorAdjustOperation::ValidateParams() { // brightness if (brightness_.empty() || brightness_.size() > 2) { std::string err_msg = "RandomColorAdjust: brightness must be a vector of one or two values, got: " + std::to_string(brightness_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < brightness_.size(); ++i) { if (brightness_[i] < 0) { std::string err_msg = "RandomColorAdjust: brightness must be greater than or equal to 0, got: " + std::to_string(brightness_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (brightness_.size() == 2 && (brightness_[0] > brightness_[1])) { std::string err_msg = "RandomColorAdjust: brightness lower bound must be less or equal to upper bound, got lb: " + std::to_string(brightness_[0]) + ", ub: " + std::to_string(brightness_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // contrast if (contrast_.empty() || contrast_.size() > 2) { std::string err_msg = "RandomColorAdjust: contrast must be a vector of one or two values, got: " + std::to_string(contrast_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < contrast_.size(); ++i) { if (contrast_[i] < 0) { std::string err_msg = "RandomColorAdjust: contrast must be greater than or equal to 0, got: " + std::to_string(contrast_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (contrast_.size() == 2 && (contrast_[0] > contrast_[1])) { std::string err_msg = "RandomColorAdjust: contrast lower bound must be less or equal to upper bound, got lb: " + std::to_string(contrast_[0]) + ", ub: " + std::to_string(contrast_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // saturation if (saturation_.empty() || saturation_.size() > 2) { std::string err_msg = "RandomColorAdjust: saturation must be a vector of one or two values, got: " + std::to_string(saturation_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < saturation_.size(); ++i) { if (saturation_[i] < 0) { std::string err_msg = "RandomColorAdjust: saturation must be greater than or equal to 0, got: " + std::to_string(saturation_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (saturation_.size() == 2 && (saturation_[0] > saturation_[1])) { std::string err_msg = "RandomColorAdjust: saturation lower bound must be less or equal to upper bound, got lb: " + std::to_string(saturation_[0]) + ", ub: " + std::to_string(saturation_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // hue if (hue_.empty() || hue_.size() > 2) { std::string err_msg = "RandomColorAdjust: hue must be a vector of one or two values, got: " + std::to_string(hue_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < hue_.size(); ++i) { if (hue_[i] < -0.5 || hue_[i] > 0.5) { std::string err_msg = "RandomColorAdjust: hue has to be between -0.5 and 0.5, got: " + std::to_string(hue_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (hue_.size() == 2 && (hue_[0] > hue_[1])) { std::string err_msg = "RandomColorAdjust: hue lower bound must be less or equal to upper bound, got lb: " + std::to_string(hue_[0]) + ", ub: " + std::to_string(hue_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomColorAdjustOperation::Build() { float brightness_lb, brightness_ub, contrast_lb, contrast_ub, saturation_lb, saturation_ub, hue_lb, hue_ub; brightness_lb = brightness_[0]; brightness_ub = brightness_[0]; if (brightness_.size() == 2) brightness_ub = brightness_[1]; contrast_lb = contrast_[0]; contrast_ub = contrast_[0]; if (contrast_.size() == 2) contrast_ub = contrast_[1]; saturation_lb = saturation_[0]; saturation_ub = saturation_[0]; if (saturation_.size() == 2) saturation_ub = saturation_[1]; hue_lb = hue_[0]; hue_ub = hue_[0]; if (hue_.size() == 2) hue_ub = hue_[1]; std::shared_ptr tensor_op = std::make_shared( brightness_lb, brightness_ub, contrast_lb, contrast_ub, saturation_lb, saturation_ub, hue_lb, hue_ub); return tensor_op; } // RandomCropOperation RandomCropOperation::RandomCropOperation(std::vector size, std::vector padding, bool pad_if_needed, std::vector fill_value, BorderType padding_mode) : TensorOperation(true), size_(size), padding_(padding), pad_if_needed_(pad_if_needed), fill_value_(fill_value), padding_mode_(padding_mode) { random_op_ = true; } Status RandomCropOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "RandomCrop: size must be a vector of one or two values"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("RandomCrop", size_)); // padding RETURN_IF_NOT_OK(ValidateVectorPadding("RandomCrop", padding_)); // fill_value RETURN_IF_NOT_OK(ValidateVectorFillvalue("RandomCrop", fill_value_)); return Status::OK(); } std::shared_ptr RandomCropOperation::Build() { int32_t crop_height = size_[0]; int32_t crop_width = size_[0]; // User has specified the crop_width value. if (size_.size() == 2) { crop_width = size_[1]; } int32_t pad_top, pad_bottom, pad_left, pad_right; switch (padding_.size()) { case 1: pad_left = padding_[0]; pad_top = padding_[0]; pad_right = padding_[0]; pad_bottom = padding_[0]; break; case 2: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[0]; pad_bottom = padding_[1]; break; default: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[2]; pad_bottom = padding_[3]; } uint8_t fill_r, fill_g, fill_b; fill_r = fill_value_[0]; fill_g = fill_value_[0]; fill_b = fill_value_[0]; if (fill_value_.size() == 3) { fill_r = fill_value_[0]; fill_g = fill_value_[1]; fill_b = fill_value_[2]; } auto tensor_op = std::make_shared(crop_height, crop_width, pad_top, pad_bottom, pad_left, pad_right, padding_mode_, pad_if_needed_, fill_r, fill_g, fill_b); return tensor_op; } // RandomCropDecodeResizeOperation RandomCropDecodeResizeOperation::RandomCropDecodeResizeOperation(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) : TensorOperation(true), size_(size), scale_(scale), ratio_(ratio), interpolation_(interpolation), max_attempts_(max_attempts) {} Status RandomCropDecodeResizeOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "RandomCropDecodeResize: size vector has incorrect size: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("RandomCropDecodeResize", size_)); // rescale if (scale_.empty() || scale_.size() != 2) { std::string err_msg = "RandomCropDecodeResize: scale vector has incorrect size: " + std::to_string(scale_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < scale_.size(); ++i) { if (scale_[i] < 0) { std::string err_msg = "RandomCropDecodeResize: invalid scale, scale must be greater than or equal to 0, got: " + std::to_string(scale_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[i] == INT_MAX) { std::string err_msg = "RandomCropDecodeResize: invalid scale, scale too large, got: " + std::to_string(scale_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (scale_[0] > scale_[1]) { std::string err_msg = "RandomCropDecodeResize: scale should be in (min,max) format. Got (max,min)."; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // ratio if (ratio_.empty() || ratio_.size() != 2) { std::string err_msg = "RandomCropDecodeResize: ratio vector has incorrect size: " + std::to_string(ratio_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < ratio_.size(); ++i) { if (ratio_[i] < 0) { std::string err_msg = "RandomCropDecodeResize: invalid ratio, ratio must be greater than or equal to 0, got: " + std::to_string(ratio_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[i] == INT_MAX) { std::string err_msg = "RandomCropDecodeResize: invalid ratio, ratio too large, got: " + std::to_string(ratio_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (ratio_[0] > ratio_[1]) { std::string err_msg = "RandomCropDecodeResize: ratio should be in (min,max) format. Got (max,min)."; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // max_attempts if (max_attempts_ < 1) { std::string err_msg = "RandomCropDecodeResize: max_attempts must be greater than or equal to 1, got: " + std::to_string(max_attempts_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomCropDecodeResizeOperation::Build() { int32_t crop_height = size_[0]; int32_t crop_width = size_[0]; // User has specified the crop_width value. if (size_.size() == 2) { crop_width = size_[1]; } float scale_lower_bound = scale_[0]; float scale_upper_bound = scale_[1]; float aspect_lower_bound = ratio_[0]; float aspect_upper_bound = ratio_[1]; auto tensor_op = std::make_shared(crop_height, crop_width, scale_lower_bound, scale_upper_bound, aspect_lower_bound, aspect_upper_bound, interpolation_, max_attempts_); return tensor_op; } // RandomCropWithBBoxOperation RandomCropWithBBoxOperation::RandomCropWithBBoxOperation(std::vector size, std::vector padding, bool pad_if_needed, std::vector fill_value, BorderType padding_mode) : TensorOperation(true), size_(size), padding_(padding), pad_if_needed_(pad_if_needed), fill_value_(fill_value), padding_mode_(padding_mode) {} Status RandomCropWithBBoxOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "RandomCropWithBBox: size must be a vector of one or two values"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("RandomCropWithBBox", size_)); // padding RETURN_IF_NOT_OK(ValidateVectorPadding("RandomCropWithBBox", padding_)); // fill_value RETURN_IF_NOT_OK(ValidateVectorFillvalue("RandomCropWithBBox", fill_value_)); return Status::OK(); } std::shared_ptr RandomCropWithBBoxOperation::Build() { int32_t crop_height = size_[0]; int32_t crop_width = size_[0]; // User has specified the crop_width value. if (size_.size() == 2) { crop_width = size_[1]; } int32_t pad_top, pad_bottom, pad_left, pad_right; switch (padding_.size()) { case 1: pad_left = padding_[0]; pad_top = padding_[0]; pad_right = padding_[0]; pad_bottom = padding_[0]; break; case 2: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[0]; pad_bottom = padding_[1]; break; default: pad_left = padding_[0]; pad_top = padding_[1]; pad_right = padding_[2]; pad_bottom = padding_[3]; } uint8_t fill_r, fill_g, fill_b; fill_r = fill_value_[0]; fill_g = fill_value_[0]; fill_b = fill_value_[0]; if (fill_value_.size() == 3) { fill_r = fill_value_[0]; fill_g = fill_value_[1]; fill_b = fill_value_[2]; } auto tensor_op = std::make_shared(crop_height, crop_width, pad_top, pad_bottom, pad_left, pad_right, padding_mode_, pad_if_needed_, fill_r, fill_g, fill_b); return tensor_op; } // RandomHorizontalFlipOperation RandomHorizontalFlipOperation::RandomHorizontalFlipOperation(float probability) : TensorOperation(true), probability_(probability) {} Status RandomHorizontalFlipOperation::ValidateParams() { RETURN_IF_NOT_OK(ValidateProbability("RandomHorizontalFlip", probability_)); return Status::OK(); } std::shared_ptr RandomHorizontalFlipOperation::Build() { std::shared_ptr tensor_op = std::make_shared(probability_); return tensor_op; } // RandomHorizontalFlipWithBBoxOperation RandomHorizontalFlipWithBBoxOperation::RandomHorizontalFlipWithBBoxOperation(float probability) : TensorOperation(true), probability_(probability) {} Status RandomHorizontalFlipWithBBoxOperation::ValidateParams() { RETURN_IF_NOT_OK(ValidateProbability("RandomHorizontalFlipWithBBox", probability_)); return Status::OK(); } std::shared_ptr RandomHorizontalFlipWithBBoxOperation::Build() { std::shared_ptr tensor_op = std::make_shared(probability_); return tensor_op; } // RandomPosterizeOperation RandomPosterizeOperation::RandomPosterizeOperation(const std::vector &bit_range) : TensorOperation(true), bit_range_(bit_range) {} Status RandomPosterizeOperation::ValidateParams() { if (bit_range_.size() != 2) { std::string err_msg = "RandomPosterize: bit_range needs to be of size 2 but is of size: " + std::to_string(bit_range_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (bit_range_[0] < 1 || bit_range_[0] > 8) { std::string err_msg = "RandomPosterize: min_bit value is out of range [1-8]: " + std::to_string(bit_range_[0]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (bit_range_[1] < 1 || bit_range_[1] > 8) { std::string err_msg = "RandomPosterize: max_bit value is out of range [1-8]: " + std::to_string(bit_range_[1]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (bit_range_[1] < bit_range_[0]) { std::string err_msg = "RandomPosterize: max_bit value is less than min_bit: max =" + std::to_string(bit_range_[1]) + ", min = " + std::to_string(bit_range_[0]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomPosterizeOperation::Build() { std::shared_ptr tensor_op = std::make_shared(bit_range_); return tensor_op; } // RandomResizeOperation RandomResizeOperation::RandomResizeOperation(std::vector size) : TensorOperation(true), size_(size) {} Status RandomResizeOperation::ValidateParams() { // size if (size_.size() != 2 && size_.size() != 1) { std::string err_msg = "RandomResize: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[0] <= 0 || (size_.size() == 2 && size_[1] <= 0)) { std::string err_msg = "RandomResize: size must only contain positive integers."; MS_LOG(ERROR) << "RandomResize: size must only contain positive integers, got: " << size_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomResizeOperation::Build() { // If size is a single value, the smaller edge of the image will be // resized to this value with the same image aspect ratio. int32_t height = size_[0]; int32_t width = 0; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared(height, width); return tensor_op; } // RandomResizeWithBBoxOperation RandomResizeWithBBoxOperation::RandomResizeWithBBoxOperation(std::vector size) : TensorOperation(true), size_(size) {} Status RandomResizeWithBBoxOperation::ValidateParams() { // size if (size_.size() != 2 && size_.size() != 1) { std::string err_msg = "RandomResizeWithBBox: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[0] <= 0 || (size_.size() == 2 && size_[1] <= 0)) { std::string err_msg = "RandomResizeWithBBox: size must only contain positive integers."; MS_LOG(ERROR) << "RandomResizeWithBBox: size must only contain positive integers, got: " << size_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomResizeWithBBoxOperation::Build() { // If size is a single value, the smaller edge of the image will be // resized to this value with the same image aspect ratio. int32_t height = size_[0]; int32_t width = 0; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared(height, width); return tensor_op; } // RandomResizedCropOperation RandomResizedCropOperation::RandomResizedCropOperation(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) : TensorOperation(true), size_(size), scale_(scale), ratio_(ratio), interpolation_(interpolation), max_attempts_(max_attempts) {} Status RandomResizedCropOperation::ValidateParams() { // size if (size_.size() != 2 && size_.size() != 1) { std::string err_msg = "RandomResizedCrop: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[0] <= 0 || (size_.size() == 2 && size_[1] <= 0)) { std::string err_msg = "RandomResizedCrop: size must only contain positive integers."; MS_LOG(ERROR) << "RandomResizedCrop: size must only contain positive integers, got: " << size_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // scale if (scale_.size() != 2) { std::string err_msg = "RandomResizedCrop: scale must be a vector of two values, got: " + std::to_string(scale_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[0] < 0 || scale_[1] < 0) { std::string err_msg = "RandomResizedCrop: scale must be greater than or equal to 0."; MS_LOG(ERROR) << "RandomResizedCrop: scale must be greater than or equal to 0, got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[1] < scale_[0]) { std::string err_msg = "RandomResizedCrop: scale must have a size of two in the format of (min, max)."; MS_LOG(ERROR) << "RandomResizedCrop: scale must have a size of two in the format of (min, max), but got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // ratio if (ratio_.size() != 2) { std::string err_msg = "RandomResizedCrop: ratio must be a vector of two values, got: " + std::to_string(ratio_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[0] < 0 || ratio_[1] < 0) { std::string err_msg = "RandomResizedCrop: ratio must be greater than or equal to 0."; MS_LOG(ERROR) << "RandomResizedCrop: ratio must be greater than or equal to 0, got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[1] < ratio_[0]) { std::string err_msg = "RandomResizedCrop: ratio must have a size of two in the format of (min, max)."; MS_LOG(ERROR) << "RandomResizedCrop: ratio must have a size of two in the format of (min, max), but got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // max_attempts if (max_attempts_ < 1) { std::string err_msg = "RandomResizedCrop: max_attempts must be greater than or equal to 1, got: " + std::to_string(max_attempts_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomResizedCropOperation::Build() { int32_t height = size_[0]; int32_t width = size_[0]; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared( height, width, scale_[0], scale_[1], ratio_[0], ratio_[1], interpolation_, max_attempts_); return tensor_op; } // RandomResizedCropWithBBoxOperation RandomResizedCropWithBBoxOperation::RandomResizedCropWithBBoxOperation(std::vector size, std::vector scale, std::vector ratio, InterpolationMode interpolation, int32_t max_attempts) : size_(size), scale_(scale), ratio_(ratio), interpolation_(interpolation), max_attempts_(max_attempts) {} Status RandomResizedCropWithBBoxOperation::ValidateParams() { // size if (size_.size() != 2 && size_.size() != 1) { std::string err_msg = "RandomResizedCropWithBBox: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[0] <= 0 || (size_.size() == 2 && size_[1] <= 0)) { std::string err_msg = "RandomResizedCropWithBBox: size must only contain positive integers."; MS_LOG(ERROR) << "RandomResizedCropWithBBox: size must only contain positive integers, got: " << size_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // scale if (scale_.size() != 2) { std::string err_msg = "RandomResizedCropWithBBox: scale must be a vector of two values, got: " + std::to_string(scale_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[0] < 0 || scale_[1] < 0) { std::string err_msg = "RandomResizedCropWithBBox: scale must be greater than or equal to 0."; MS_LOG(ERROR) << "RandomResizedCropWithBBox: scale must be greater than or equal to 0, got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[1] < scale_[0]) { std::string err_msg = "RandomResizedCropWithBBox: scale must have a size of two in the format of (min, max)."; MS_LOG(ERROR) << "RandomResizedCropWithBBox: scale must have a size of two in the format of (min, max), but got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // ratio if (ratio_.size() != 2) { std::string err_msg = "RandomResizedCropWithBBox: ratio must be a vector of two values, got: " + std::to_string(ratio_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[0] < 0 || ratio_[1] < 0) { std::string err_msg = "RandomResizedCropWithBBox: ratio must be greater than or equal to 0."; MS_LOG(ERROR) << "RandomResizedCropWithBBox: ratio must be greater than or equal to 0, got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[1] < ratio_[0]) { std::string err_msg = "RandomResizedCropWithBBox: ratio must have a size of two in the format of (min, max)."; MS_LOG(ERROR) << "RandomResizedCropWithBBox: ratio must have a size of two in the format of (min, max), but got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // max_attempts if (max_attempts_ < 1) { std::string err_msg = "RandomResizedCropWithBBox: max_attempts must be greater than or equal to 1, got: " + std::to_string(max_attempts_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomResizedCropWithBBoxOperation::Build() { int32_t height = size_[0]; int32_t width = size_[0]; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared( height, width, scale_[0], scale_[1], ratio_[0], ratio_[1], interpolation_, max_attempts_); return tensor_op; } // Function to create RandomRotationOperation. RandomRotationOperation::RandomRotationOperation(std::vector degrees, InterpolationMode interpolation_mode, bool expand, std::vector center, std::vector fill_value) : TensorOperation(true), degrees_(degrees), interpolation_mode_(interpolation_mode), expand_(expand), center_(center), fill_value_(fill_value) {} Status RandomRotationOperation::ValidateParams() { // degrees if (degrees_.size() != 2 && degrees_.size() != 1) { std::string err_msg = "RandomRotation: degrees must be a vector of one or two values, got: " + std::to_string(degrees_.size()); MS_LOG(ERROR) << "RandomRotation: degrees must be a vector of one or two values, got: " << degrees_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if ((degrees_[1] < degrees_[0]) && (degrees_.size() == 2)) { std::string err_msg = "RandomRotation: degrees must be in the format of (min, max), got: (" + std::to_string(degrees_[0]) + ", " + std::to_string(degrees_[1]) + ")"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } else if ((degrees_[0] < 0) && degrees_.size() == 1) { std::string err_msg = "RandomRotation: if degrees only has one value, it must be greater than or equal to 0, got: " + std::to_string(degrees_[0]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // center if (center_.empty() || center_.size() != 2) { std::string err_msg = "RandomRotation: center must be a vector of two values, got: " + std::to_string(center_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // fill_value RETURN_IF_NOT_OK(ValidateVectorFillvalue("RandomRotation", fill_value_)); return Status::OK(); } std::shared_ptr RandomRotationOperation::Build() { float start_degree, end_degree; if (degrees_.size() == 1) { start_degree = -degrees_[0]; end_degree = degrees_[0]; } else if (degrees_.size() == 2) { start_degree = degrees_[0]; end_degree = degrees_[1]; } uint8_t fill_r, fill_g, fill_b; fill_r = fill_value_[0]; fill_g = fill_value_[0]; fill_b = fill_value_[0]; if (fill_value_.size() == 3) { fill_r = fill_value_[0]; fill_g = fill_value_[1]; fill_b = fill_value_[2]; } std::shared_ptr tensor_op = std::make_shared( start_degree, end_degree, center_[0], center_[1], interpolation_mode_, expand_, fill_r, fill_g, fill_b); return tensor_op; } // RandomSelectSubpolicyOperation. RandomSelectSubpolicyOperation::RandomSelectSubpolicyOperation( std::vector, double>>> policy) : TensorOperation(true), policy_(policy) {} Status RandomSelectSubpolicyOperation::ValidateParams() { if (policy_.empty()) { std::string err_msg = "RandomSelectSubpolicy: policy must not be empty"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < policy_.size(); i++) { if (policy_[i].empty()) { std::string err_msg = "RandomSelectSubpolicy: policy[" + std::to_string(i) + "] must not be empty"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t j = 0; j < policy_[i].size(); j++) { if (policy_[i][j].first == nullptr) { std::string transform_pos = "[" + std::to_string(i) + "]" + "[" + std::to_string(j) + "]"; std::string err_msg = "RandomSelectSubpolicy: transform in policy" + transform_pos + " must not be null"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (policy_[i][j].second < 0.0 || policy_[i][j].second > 1.0) { std::string transform_pos = "[" + std::to_string(i) + "]" + "[" + std::to_string(j) + "]"; std::string err_msg = "RandomSelectSubpolicy: probability of transform in policy" + transform_pos + " must be between 0.0 and 1.0, got: " + std::to_string(policy_[i][j].second); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } } return Status::OK(); } std::shared_ptr RandomSelectSubpolicyOperation::Build() { std::vector policy_tensor_ops; for (int32_t i = 0; i < policy_.size(); i++) { Subpolicy sub_policy_tensor_ops; for (int32_t j = 0; j < policy_[i].size(); j++) { sub_policy_tensor_ops.push_back(std::make_pair(policy_[i][j].first->Build(), policy_[i][j].second)); } policy_tensor_ops.push_back(sub_policy_tensor_ops); } std::shared_ptr tensor_op = std::make_shared(policy_tensor_ops); return tensor_op; } // Function to create RandomSharpness. RandomSharpnessOperation::RandomSharpnessOperation(std::vector degrees) : TensorOperation(true), degrees_(degrees) {} Status RandomSharpnessOperation::ValidateParams() { if (degrees_.size() != 2 || degrees_[0] < 0 || degrees_[1] < 0) { std::string err_msg = "RandomSharpness: degrees must be a vector of two values and greater than or equal to 0."; MS_LOG(ERROR) << "RandomSharpness: degrees must be a vector of two values and greater than or equal to 0, got: " << degrees_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (degrees_[1] < degrees_[0]) { std::string err_msg = "RandomSharpness: degrees must be in the format of (min, max)."; MS_LOG(ERROR) << "RandomSharpness: degrees must be in the format of (min, max), got: " << degrees_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomSharpnessOperation::Build() { std::shared_ptr tensor_op = std::make_shared(degrees_[0], degrees_[1]); return tensor_op; } // RandomSolarizeOperation. RandomSolarizeOperation::RandomSolarizeOperation(std::vector threshold) : TensorOperation(true), threshold_(threshold) {} Status RandomSolarizeOperation::ValidateParams() { if (threshold_.size() != 2) { std::string err_msg = "RandomSolarize: threshold must be a vector of two values, got: " + std::to_string(threshold_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } for (int32_t i = 0; i < threshold_.size(); ++i) { if (threshold_[i] < 0 || threshold_[i] > 255) { std::string err_msg = "RandomSolarize: threshold has to be between 0 and 255, got:" + std::to_string(threshold_[i]); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } } if (threshold_[0] > threshold_[1]) { std::string err_msg = "RandomSolarize: threshold must be passed in a (min, max) format"; MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RandomSolarizeOperation::Build() { std::shared_ptr tensor_op = std::make_shared(threshold_); return tensor_op; } // RandomVerticalFlipOperation RandomVerticalFlipOperation::RandomVerticalFlipOperation(float probability) : TensorOperation(true), probability_(probability) {} Status RandomVerticalFlipOperation::ValidateParams() { RETURN_IF_NOT_OK(ValidateProbability("RandomVerticalFlip", probability_)); return Status::OK(); } std::shared_ptr RandomVerticalFlipOperation::Build() { std::shared_ptr tensor_op = std::make_shared(probability_); return tensor_op; } // RandomVerticalFlipWithBBoxOperation RandomVerticalFlipWithBBoxOperation::RandomVerticalFlipWithBBoxOperation(float probability) : TensorOperation(true), probability_(probability) {} Status RandomVerticalFlipWithBBoxOperation::ValidateParams() { RETURN_IF_NOT_OK(ValidateProbability("RandomVerticalFlipWithBBox", probability_)); return Status::OK(); } std::shared_ptr RandomVerticalFlipWithBBoxOperation::Build() { std::shared_ptr tensor_op = std::make_shared(probability_); return tensor_op; } // RescaleOperation RescaleOperation::RescaleOperation(float rescale, float shift) : rescale_(rescale), shift_(shift) {} Status RescaleOperation::ValidateParams() { if (rescale_ < 0) { std::string err_msg = "Rescale: rescale must be greater than or equal to 0, got: " + std::to_string(rescale_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr RescaleOperation::Build() { std::shared_ptr tensor_op = std::make_shared(rescale_, shift_); return tensor_op; } #endif // ResizeOperation ResizeOperation::ResizeOperation(std::vector size, InterpolationMode interpolation) : size_(size), interpolation_(interpolation) {} Status ResizeOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "Resize: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("Resize", size_)); return Status::OK(); } std::shared_ptr ResizeOperation::Build() { // If size is a single value, the smaller edge of the image will be // resized to this value with the same image aspect ratio. int32_t height = size_[0]; int32_t width = 0; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } return std::make_shared(height, width, interpolation_); } #ifndef ENABLE_ANDROID // ResizeWithBBoxOperation ResizeWithBBoxOperation::ResizeWithBBoxOperation(std::vector size, InterpolationMode interpolation) : size_(size), interpolation_(interpolation) {} Status ResizeWithBBoxOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "ResizeWithBBox: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("Resize", size_)); return Status::OK(); } std::shared_ptr ResizeWithBBoxOperation::Build() { int32_t height = size_[0]; int32_t width = 0; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } return std::make_shared(height, width, interpolation_); } // RgbaToBgrOperation. RgbaToBgrOperation::RgbaToBgrOperation() {} Status RgbaToBgrOperation::ValidateParams() { return Status::OK(); } std::shared_ptr RgbaToBgrOperation::Build() { std::shared_ptr tensor_op = std::make_shared(); return tensor_op; } // RgbaToRgbOperation. RgbaToRgbOperation::RgbaToRgbOperation() {} Status RgbaToRgbOperation::ValidateParams() { return Status::OK(); } std::shared_ptr RgbaToRgbOperation::Build() { std::shared_ptr tensor_op = std::make_shared(); return tensor_op; } // SoftDvppDecodeRandomCropResizeJpegOperation SoftDvppDecodeRandomCropResizeJpegOperation::SoftDvppDecodeRandomCropResizeJpegOperation(std::vector size, std::vector scale, std::vector ratio, int32_t max_attempts) : size_(size), scale_(scale), ratio_(ratio), max_attempts_(max_attempts) {} Status SoftDvppDecodeRandomCropResizeJpegOperation::ValidateParams() { // size if (size_.size() != 2 && size_.size() != 1) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (size_[0] <= 0 || (size_.size() == 2 && size_[1] <= 0)) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: size must only contain positive integers."; MS_LOG(ERROR) << "SoftDvppDecodeRandomCropResizeJpeg: size must only contain positive integers, got: " << size_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // scale if (scale_.size() != 2) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: scale must be a vector of two values, got: " + std::to_string(scale_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[0] < 0 || scale_[1] < 0) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: scale must be greater than or equal to 0."; MS_LOG(ERROR) << "SoftDvppDecodeRandomCropResizeJpeg: scale must be greater than or equal to 0, got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (scale_[1] < scale_[0]) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: scale must be in the format of (min, max)."; MS_LOG(ERROR) << "SoftDvppDecodeRandomCropResizeJpeg: scale must be in the format of (min, max), but got: " << scale_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // ratio if (ratio_.size() != 2) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: ratio must be a vector of two values, got: " + std::to_string(ratio_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[0] < 0 || ratio_[1] < 0) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: ratio must be greater than or equal to 0."; MS_LOG(ERROR) << "SoftDvppDecodeRandomCropResizeJpeg: ratio must be greater than or equal to 0, got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } if (ratio_[1] < ratio_[0]) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: ratio must be in the format of (min, max)."; MS_LOG(ERROR) << "SoftDvppDecodeRandomCropResizeJpeg: ratio must be in the format of (min, max), but got: " << ratio_; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // max_attempts if (max_attempts_ < 1) { std::string err_msg = "SoftDvppDecodeRandomCropResizeJpeg: max_attempts must be greater than or equal to 1, got: " + std::to_string(max_attempts_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr SoftDvppDecodeRandomCropResizeJpegOperation::Build() { int32_t height = size_[0]; int32_t width = size_[0]; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } auto tensor_op = std::make_shared(height, width, scale_[0], scale_[1], ratio_[0], ratio_[1], max_attempts_); return tensor_op; } // SoftDvppDecodeResizeJpegOperation SoftDvppDecodeResizeJpegOperation::SoftDvppDecodeResizeJpegOperation(std::vector size) : size_(size) {} Status SoftDvppDecodeResizeJpegOperation::ValidateParams() { // size if (size_.empty() || size_.size() > 2) { std::string err_msg = "SoftDvppDecodeResizeJpeg: size must be a vector of one or two values, got: " + std::to_string(size_.size()); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } RETURN_IF_NOT_OK(ValidateVectorPositive("SoftDvppDecodeResizeJpeg", size_)); return Status::OK(); } std::shared_ptr SoftDvppDecodeResizeJpegOperation::Build() { // If size is a single value, the smaller edge of the image will be // resized to this value with the same image aspect ratio. int32_t height = size_[0]; int32_t width = 0; // User specified the width value. if (size_.size() == 2) { width = size_[1]; } std::shared_ptr tensor_op = std::make_shared(height, width); return tensor_op; } // SwapRedBlueOperation. SwapRedBlueOperation::SwapRedBlueOperation() {} Status SwapRedBlueOperation::ValidateParams() { return Status::OK(); } std::shared_ptr SwapRedBlueOperation::Build() { std::shared_ptr tensor_op = std::make_shared(); return tensor_op; } // UniformAugOperation UniformAugOperation::UniformAugOperation(std::vector> transforms, int32_t num_ops) : transforms_(transforms), num_ops_(num_ops) {} Status UniformAugOperation::ValidateParams() { // transforms RETURN_IF_NOT_OK(ValidateVectorTransforms("UniformAug", transforms_)); if (num_ops_ > transforms_.size()) { std::string err_msg = "UniformAug: num_ops is greater than transforms size, but got: " + std::to_string(num_ops_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } // num_ops if (num_ops_ <= 0) { std::string err_msg = "UniformAug: num_ops must be greater than 0, but got: " + std::to_string(num_ops_); MS_LOG(ERROR) << err_msg; RETURN_STATUS_SYNTAX_ERROR(err_msg); } return Status::OK(); } std::shared_ptr UniformAugOperation::Build() { std::vector> tensor_ops; (void)std::transform(transforms_.begin(), transforms_.end(), std::back_inserter(tensor_ops), [](std::shared_ptr op) -> std::shared_ptr { return op->Build(); }); std::shared_ptr tensor_op = std::make_shared(tensor_ops, num_ops_); return tensor_op; } #endif } // namespace vision } // namespace dataset } // namespace mindspore