Fix case for upper and lower padding when strides are present. (#11)

* Fix case for upper and lower padding when strides are present.

* Address comments.

* Code clean-up.

* Fix tests.
This commit is contained in:
Gheorghe-Teodor Bercea 2020-03-10 16:58:05 -04:00 committed by GitHub
parent fe3279e721
commit e8a0b47e10
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2 changed files with 90 additions and 44 deletions

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@ -782,15 +782,15 @@ void ONNXConvNoBiasOp::inferShapes() {
auto dataTy = X().getType().cast<RankedTensorType>(); auto dataTy = X().getType().cast<RankedTensorType>();
auto weightTy = W().getType().cast<RankedTensorType>(); auto weightTy = W().getType().cast<RankedTensorType>();
auto dataShape = dataTy.getShape(); auto inDataShape = dataTy.getShape();
auto weightShape = weightTy.getShape(); auto weightShape = weightTy.getShape();
// Lowest supported convolution is a one dimensional convolution. // Lowest supported convolution is a one dimensional convolution.
if (dataShape.size() < 3) if (inDataShape.size() < 3)
emitError("Data input shape must be at least (NxCxD1)"); emitError("Data input shape must be at least (NxCxD1)");
// Check that shape of weight and data have same length. // Check that shape of weight and data have same length.
if (dataShape.size() != weightShape.size()) if (inDataShape.size() != weightShape.size())
emitError("Weight size not compatible with data size"); emitError("Weight size not compatible with data size");
// Required attribute auto_pad defaults to NOTSET. // Required attribute auto_pad defaults to NOTSET.
@ -799,8 +799,8 @@ void ONNXConvNoBiasOp::inferShapes() {
int64_t group = int64_t group =
ONNXConvNoBiasOp::group().getSExtValue(); //.getLimitedValue(); ONNXConvNoBiasOp::group().getSExtValue(); //.getLimitedValue();
// Check that the X.shape[1] == (W.shape[1] * group) == C condition holds. // Check that the X.shape[1] == (W.shape[1] * group) == C condition holds.
if (dataShape[1] != -1 && weightShape[1] != -1 && if (inDataShape[1] != -1 && weightShape[1] != -1 &&
dataShape[1] != (weightShape[1] * group)) inDataShape[1] != (weightShape[1] * group))
emitError("Channel dimension mismatch"); emitError("Channel dimension mismatch");
// Note: the value of the group attribut only impacts the way the // Note: the value of the group attribut only impacts the way the
@ -811,7 +811,7 @@ void ONNXConvNoBiasOp::inferShapes() {
// //
SmallVector<int64_t, 2> dims; SmallVector<int64_t, 2> dims;
// Insert batch size. // Insert batch size.
dims.emplace_back(dataShape[0]); dims.emplace_back(inDataShape[0]);
// Insert number of filters being applied (number of output channels). // Insert number of filters being applied (number of output channels).
dims.emplace_back(weightShape[0]); dims.emplace_back(weightShape[0]);
@ -821,22 +821,22 @@ void ONNXConvNoBiasOp::inferShapes() {
// //
SmallVector<int64_t, 2> outSpatialDims; SmallVector<int64_t, 2> outSpatialDims;
// Number of spatial dimensions. // Number of spatial dimensions.
int32_t nDims = dataShape.size() - 2; int32_t nSpatialDims = inDataShape.size() - 2;
// Initialize dimenions based on the input spatial dimensions. // Initialize dimenions based on the input spatial dimensions.
for (int i = 2; i < dataShape.size(); ++i) for (int i = 2; i < inDataShape.size(); ++i)
outSpatialDims.emplace_back(dataShape[i]); outSpatialDims.emplace_back(inDataShape[i]);
// Use kernel_shape attribute if present otherwise use size from weight // Use kernel_shape attribute if present otherwise use size from weight
// argument. // argument.
SmallVector<int64_t, 2> kernelDims; SmallVector<int64_t, 2> kernelDims;
if (auto kernelShape = kernel_shapeAttr()) { if (auto kernelShape = kernel_shapeAttr()) {
if (ArrayAttrSize(kernelShape) != nDims) if (ArrayAttrSize(kernelShape) != nSpatialDims)
emitError("kernel_shape length incompatible with spatial dimensions"); emitError("kernel_shape length incompatible with spatial dimensions");
for (int i = 0; i < nDims; ++i) for (int i = 0; i < nSpatialDims; ++i)
kernelDims.emplace_back(ArrayAttrIntVal(kernelShape, i)); kernelDims.emplace_back(ArrayAttrIntVal(kernelShape, i));
} else { } else {
for (int i = 0; i < nDims; ++i) for (int i = 0; i < nSpatialDims; ++i)
kernelDims.emplace_back(weightShape[i + 2]); kernelDims.emplace_back(weightShape[i + 2]);
} }
@ -852,43 +852,70 @@ void ONNXConvNoBiasOp::inferShapes() {
// From a dimensionality perspective the kernel size becomes the dilated // From a dimensionality perspective the kernel size becomes the dilated
// kernel size. // kernel size.
if (auto dilations = dilationsAttr()) { if (auto dilations = dilationsAttr()) {
if (ArrayAttrSize(dilations) != nDims) if (ArrayAttrSize(dilations) != nSpatialDims)
emitError("dilations length incompatible with spatial dimensions"); emitError("dilations length incompatible with spatial dimensions");
for (int i = 0; i < nDims; ++i) for (int i = 0; i < nSpatialDims; ++i)
kernelDims[i] = kernelDims[i] =
(kernelDims[i] + 1) * ArrayAttrIntVal(dilations, i) - 1; (kernelDims[i] + 1) * ArrayAttrIntVal(dilations, i) - 1;
} }
// Subtract kernel dimensions from input data dimensions. // Subtract kernel dimensions from input data dimensions.
for (int i = 0; i < nDims; ++i) for (int i = 0; i < nSpatialDims; ++i)
outSpatialDims[i] -= kernelDims[i]; outSpatialDims[i] -= kernelDims[i];
// Array which holds the padding information.
SmallVector<int64_t, 2> actualPads(2 * nSpatialDims, 0);
auto stridesAttr = ONNXConvNoBiasOp::stridesAttr();
// Add padding information. // Add padding information.
if (autoPad == "NOTSET") { if (autoPad == "NOTSET") {
// Use pads to to determine the padding. If attribute is not // Use pads to to determine the padding. If attribute is not
// present then pads is considered to be all zeros (no padding). // present then pads is considered to be all zeros (no padding).
if (auto pads = padsAttr()) { if (auto pads = padsAttr()) {
// pads consists of two entries for each spatial axis. // pads consists of two entries for each spatial axis.
if (ArrayAttrSize(pads) != 2 * nDims) if (ArrayAttrSize(pads) != 2 * nSpatialDims)
emitError("pads size is not twice the spatial size"); emitError("pads size is not twice the spatial size");
for (int i = 0; i < nDims; ++i) { for (int i = 0; i < nSpatialDims; ++i) {
// Padding for beginning of axis. // Padding for beginning of axis.
outSpatialDims[i] += ArrayAttrIntVal(pads, i); outSpatialDims[i] += ArrayAttrIntVal(pads, i);
// Padding for end of axis. // Padding for end of axis.
outSpatialDims[i] += ArrayAttrIntVal(pads, i + nDims); outSpatialDims[i] += ArrayAttrIntVal(pads, i + nSpatialDims);
} }
} }
} else if (autoPad == "SAME_UPPER" || autoPad == "SAME_LOWER") { } else if (autoPad == "SAME_UPPER" || autoPad == "SAME_LOWER") {
// Pad input so that output size matches input size. // Pad input so that output size matches input size.
// Each spatial dimension needs to be padded by a total of: // Each spatial dimension needs to be padded by a total of:
// //
// K - 1 // stride * (InDim - 1) + KerDim - InDim
// //
// where K is a kernel spatial dimension. // where K is a kernel spatial dimension.
// Pad as if stride is 1. for (int i = 0; i < nSpatialDims; ++i) {
for (int i = 0; i < nDims; ++i) // If strides are given use them otherwise stride is 1.
outSpatialDims[i] += kernelDims[i] - 1; int64_t stride = 1;
if (stridesAttr)
stride = ArrayAttrIntVal(stridesAttr, i);
// Compute necessary padding. The input dimensions are stored in
// inDataShape.
int64_t totalPadding = stride * (inDataShape[i + 2] - 1) +
kernelDims[i] - inDataShape[i + 2];
// Adjust current output value with the value of the padding.
// When dividing by stride later on, the output dimension should
// be equal to the input dimension.
outSpatialDims[i] += totalPadding;
// Record the upper and lower axis padding.
actualPads[i] = actualPads[i + nSpatialDims] = totalPadding / 2;
if (totalPadding % 2 != 0) {
if (autoPad == "SAME_LOWER") {
actualPads[i]++;
} else {
actualPads[i + nSpatialDims]++;
}
}
}
} else if (autoPad == "VALID") { } else if (autoPad == "VALID") {
// No padding // No padding
} else { } else {
@ -896,18 +923,34 @@ void ONNXConvNoBiasOp::inferShapes() {
} }
// Strides // Strides
if (auto strides = ONNXConvNoBiasOp::stridesAttr()) { if (stridesAttr) {
if (ArrayAttrSize(strides) != nDims) if (ArrayAttrSize(stridesAttr) != nSpatialDims)
emitError("strides length incompatible with spatial dimensions"); emitError("strides length incompatible with spatial dimensions");
for (int i = 0; i < nDims; ++i) { for (int i = 0; i < nSpatialDims; ++i) {
int64_t stride = ArrayAttrIntVal(strides, i); int64_t stride = ArrayAttrIntVal(stridesAttr, i);
outSpatialDims[i] = floor(outSpatialDims[i] / stride); outSpatialDims[i] = floor(outSpatialDims[i] / stride);
} }
} }
for (int i = 0; i < nDims; ++i) for (int i = 0; i < nSpatialDims; ++i)
outSpatialDims[i] += 1; outSpatialDims[i] += 1;
// Check input and output sizes match.
if (autoPad == "SAME_UPPER" || autoPad == "SAME_LOWER") {
for (int i = 0; i < nSpatialDims; ++i)
if (outSpatialDims[i] != inDataShape[i + 2])
emitError("input and output spatial dimension mismatch");
// Set pads values in attributes.
auto builder = mlir::Builder(this->getContext());
ArrayRef<int64_t> defaultRefs(actualPads);
padsAttr(builder.getI64ArrayAttr(defaultRefs));
// Change auto padding attribute to NOTSET since padding values
// are now explicitly included in the operation.
auto_padAttr(builder.getStringAttr("NOTSET"));
}
dims.append(outSpatialDims.begin(), outSpatialDims.end()); dims.append(outSpatialDims.begin(), outSpatialDims.end());
getResult().setType(RankedTensorType::get(dims, dataTy.getElementType())); getResult().setType(RankedTensorType::get(dims, dataTy.getElementType()));
} }

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@ -195,7 +195,7 @@ func @test_conv_no_bias_4(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
// CHECK-LABEL: test_conv_no_bias_4 // CHECK-LABEL: test_conv_no_bias_4
// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32> // CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, pads = [2, 4, 3, 5]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
// CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32> // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
} }
@ -204,7 +204,7 @@ func @test_conv_no_bias_5(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
// CHECK-LABEL: test_conv_no_bias_5 // CHECK-LABEL: test_conv_no_bias_5
// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_LOWER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32> // CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, pads = [3, 5, 2, 4]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
// CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32> // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
} }
@ -238,8 +238,8 @@ func @test_conv_no_bias_8(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7x
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
// CHECK-LABEL: test_conv_no_bias_8 // CHECK-LABEL: test_conv_no_bias_8
// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x16x22xf32> // CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, pads = [18, 66, 18, 66], strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x32x64xf32>
// CHECK: return [[RES_ATTR]] : tensor<1x5x16x22xf32> // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
} }
/// dilations attribute. /// dilations attribute.
@ -269,27 +269,30 @@ func @test_conv_no_bias_10(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7
func @test_conv_no_bias_11(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> { func @test_conv_no_bias_11(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
%0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32> %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
}
// CHECK-LABEL: test_conv_no_bias_11 // CHECK-LABEL: test_conv_no_bias_11
// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", dilations = [2, 3], group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x32x64xf32> // CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", dilations = [2, 3], group = 1 : i64, pads = [6, 11, 6, 11]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x32x64xf32>
// CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32> // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
}
/// Test PadConstantValuePad
/// Test PadConstantValuePad_1
func @test_PadConstantValuePad_1(%arg0 : tensor<16x13xf32>) -> tensor<*xf32> { func @test_PadConstantValuePad_1(%arg0 : tensor<16x13xf32>) -> tensor<*xf32> {
%0 = "onnx.PadConstantValuePad"(%arg0) {constant_value = 0.000000e+00 : f32, mode = "constant", pads = [0, 2, 0, 0]} : (tensor<16x13xf32>) -> tensor<*xf32> %0 = "onnx.PadConstantValuePad"(%arg0) {constant_value = 0.000000e+00 : f32, mode = "constant", pads = [0, 2, 0, 0]} : (tensor<16x13xf32>) -> tensor<*xf32>
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
}
// CHECK-LABEL: test_PadConstantValuePad_1
// CHECK: [[RES:%.+]] = "onnx.PadConstantValuePad"(%arg0) {constant_value = 0.000000e+00 : f32, mode = "constant", pads = [0, 2, 0, 0]} : (tensor<16x13xf32>) -> tensor<18x13xf32>
// CHECK: return [[RES]] : tensor<18x13xf32>
/// Test PadConstantPad_1 // CHECK-LABEL: test_PadConstantValuePad_1
// CHECK: [[RES:%.+]] = "onnx.PadConstantValuePad"(%arg0) {constant_value = 0.000000e+00 : f32, mode = "constant", pads = [0, 2, 0, 0]} : (tensor<16x13xf32>) -> tensor<18x13xf32>
// CHECK: return [[RES]] : tensor<18x13xf32>
}
/// Test PadConstantPad
func @test_PadConstantPad_1(%arg0 : tensor<16x13xf32>, %arg1 : tensor<*xf32>) -> tensor<*xf32> { func @test_PadConstantPad_1(%arg0 : tensor<16x13xf32>, %arg1 : tensor<*xf32>) -> tensor<*xf32> {
%0 = "onnx.PadConstantPad"(%arg0, %arg1) {mode = "constant", pads = [0, 2, 3, 1]} : (tensor<16x13xf32>, tensor<*xf32>) -> tensor<*xf32> %0 = "onnx.PadConstantPad"(%arg0, %arg1) {mode = "constant", pads = [0, 2, 3, 1]} : (tensor<16x13xf32>, tensor<*xf32>) -> tensor<*xf32>
"std.return"(%0) : (tensor<*xf32>) -> () "std.return"(%0) : (tensor<*xf32>) -> ()
}
// CHECK-LABEL: test_PadConstantPad_1
// CHECK: [[RES:%.+]] = "onnx.PadConstantPad"(%arg0, %arg1) {mode = "constant", pads = [0, 2, 3, 1]} : (tensor<16x13xf32>, tensor<*xf32>) -> tensor<18x17xf32>
// CHECK: return [[RES]] : tensor<18x17xf32>
// CHECK-LABEL: test_PadConstantPad_1
// CHECK: [[RES:%.+]] = "onnx.PadConstantPad"(%arg0, %arg1) {mode = "constant", pads = [0, 2, 3, 1]} : (tensor<16x13xf32>, tensor<*xf32>) -> tensor<18x17xf32>
// CHECK: return [[RES]] : tensor<18x17xf32>
}