# Copyright (c) ONNX Project Contributors # # SPDX-License-Identifier: Apache-2.0 from __future__ import annotations import numpy as np import onnx from onnx.backend.test.case.base import Base from onnx.backend.test.case.node import expect from onnx.defs import AI_ONNX_PREVIEW_TRAINING_DOMAIN def apply_adagrad(r, t, x, g, h, norm_coefficient, epsilon, decay_factor): # Compute adjusted learning-rate. r_ = r / (1 + t * decay_factor) # Add gradient of regularization term. g_regularized = norm_coefficient * x + g # Update squared accumulated gradient. h_new = h + g_regularized * g_regularized # Compute ADAGRAD's gradient scaling factors h_sqrt = np.sqrt(h_new) + epsilon # Apply ADAGRAD update rule. x_new = x - r_ * g_regularized / h_sqrt return (x_new.astype(x.dtype), h_new.astype(h.dtype)) class Adagrad(Base): @staticmethod def export_adagrad() -> None: # Define operator attributes. norm_coefficient = 0.001 epsilon = 1e-5 decay_factor = 0.1 # Create operator. node = onnx.helper.make_node( "Adagrad", inputs=["R", "T", "X", "G", "H"], outputs=["X_new", "H_new"], norm_coefficient=norm_coefficient, epsilon=epsilon, decay_factor=decay_factor, domain=AI_ONNX_PREVIEW_TRAINING_DOMAIN, ) # Define operator inputs. r = np.array(0.1, dtype=np.float32) # scalar t = np.array(0, dtype=np.int64) # scalar x = np.array([1.0], dtype=np.float32) g = np.array([-1.0], dtype=np.float32) h = np.array([2.0], dtype=np.float32) # Compute expected outputs of Adagrad. x_new, h_new = apply_adagrad( r, t, x, g, h, norm_coefficient, epsilon, decay_factor ) # Check results. expect( node, inputs=[r, t, x, g, h], outputs=[x_new, h_new], name="test_adagrad", opset_imports=[ onnx.helper.make_opsetid(AI_ONNX_PREVIEW_TRAINING_DOMAIN, 1) ], ) @staticmethod def export_adagrad_multiple() -> None: # Define operator attributes. norm_coefficient = 0.001 epsilon = 1e-5 decay_factor = 0.1 node = onnx.helper.make_node( "Adagrad", inputs=["R", "T", "X1", "X2", "G1", "G2", "H1", "H2"], outputs=["X1_new", "X2_new", "H1_new", "H2_new"], norm_coefficient=norm_coefficient, epsilon=epsilon, decay_factor=decay_factor, domain=AI_ONNX_PREVIEW_TRAINING_DOMAIN, ) # Define operator inputs. r = np.array(0.1, dtype=np.float32) # scalar t = np.array(0, dtype=np.int64) # scalar x1 = np.array([1.0], dtype=np.float32) g1 = np.array([-1.0], dtype=np.float32) h1 = np.array([2.0], dtype=np.float32) x2 = np.array([1.0, 2.0], dtype=np.float32) g2 = np.array([-1.0, -3.0], dtype=np.float32) h2 = np.array([4.0, 1.0], dtype=np.float32) # Compute expected outputs of Adagrad. x1_new, h1_new = apply_adagrad( r, t, x1, g1, h1, norm_coefficient, epsilon, decay_factor ) x2_new, h2_new = apply_adagrad( r, t, x2, g2, h2, norm_coefficient, epsilon, decay_factor ) # Check results. expect( node, inputs=[r, t, x1, x2, g1, g2, h1, h2], outputs=[x1_new, x2_new, h1_new, h2_new], name="test_adagrad_multiple", opset_imports=[ onnx.helper.make_opsetid(AI_ONNX_PREVIEW_TRAINING_DOMAIN, 1) ], )