From af3a5c22303afd901d6017fdf8891667262906ec Mon Sep 17 00:00:00 2001 From: "A. Unique TensorFlower" Date: Fri, 6 Jul 2018 17:45:53 -0700 Subject: Go: Update generated wrapper functions for TensorFlow ops. PiperOrigin-RevId: 203546015 --- tensorflow/go/op/wrappers.go | 202 +++++++++++++++++++++---------------------- 1 file changed, 101 insertions(+), 101 deletions(-) (limited to 'tensorflow/go') diff --git a/tensorflow/go/op/wrappers.go b/tensorflow/go/op/wrappers.go index 221fd27275..8109fbdcda 100644 --- a/tensorflow/go/op/wrappers.go +++ b/tensorflow/go/op/wrappers.go @@ -3114,6 +3114,107 @@ func DeepCopy(scope *Scope, x tf.Output) (y tf.Output) { return op.Output(0) } +// PackAttr is an optional argument to Pack. +type PackAttr func(optionalAttr) + +// PackAxis sets the optional axis attribute to value. +// +// value: Dimension along which to pack. Negative values wrap around, so the +// valid range is `[-(R+1), R+1)`. +// If not specified, defaults to 0 +func PackAxis(value int64) PackAttr { + return func(m optionalAttr) { + m["axis"] = value + } +} + +// Packs a list of `N` rank-`R` tensors into one rank-`(R+1)` tensor. +// +// Packs the `N` tensors in `values` into a tensor with rank one higher than each +// tensor in `values`, by packing them along the `axis` dimension. +// Given a list of tensors of shape `(A, B, C)`; +// +// if `axis == 0` then the `output` tensor will have the shape `(N, A, B, C)`. +// if `axis == 1` then the `output` tensor will have the shape `(A, N, B, C)`. +// Etc. +// +// For example: +// +// ``` +// # 'x' is [1, 4] +// # 'y' is [2, 5] +// # 'z' is [3, 6] +// pack([x, y, z]) => [[1, 4], [2, 5], [3, 6]] # Pack along first dim. +// pack([x, y, z], axis=1) => [[1, 2, 3], [4, 5, 6]] +// ``` +// +// This is the opposite of `unpack`. +// +// Arguments: +// values: Must be of same shape and type. +// +// Returns The packed tensor. +func Pack(scope *Scope, values []tf.Output, optional ...PackAttr) (output tf.Output) { + if scope.Err() != nil { + return + } + attrs := map[string]interface{}{} + for _, a := range optional { + a(attrs) + } + opspec := tf.OpSpec{ + Type: "Pack", + Input: []tf.Input{ + tf.OutputList(values), + }, + Attrs: attrs, + } + op := scope.AddOperation(opspec) + return op.Output(0) +} + +// Concatenates a list of `N` tensors along the first dimension. +// +// The input tensors are all required to have size 1 in the first dimension. +// +// For example: +// +// ``` +// # 'x' is [[1, 4]] +// # 'y' is [[2, 5]] +// # 'z' is [[3, 6]] +// parallel_concat([x, y, z]) => [[1, 4], [2, 5], [3, 6]] # Pack along first dim. +// ``` +// +// The difference between concat and parallel_concat is that concat requires all +// of the inputs be computed before the operation will begin but doesn't require +// that the input shapes be known during graph construction. Parallel concat +// will copy pieces of the input into the output as they become available, in +// some situations this can provide a performance benefit. +// +// Arguments: +// values: Tensors to be concatenated. All must have size 1 in the first dimension +// and same shape. +// shape: the final shape of the result; should be equal to the shapes of any input +// but with the number of input values in the first dimension. +// +// Returns The concatenated tensor. +func ParallelConcat(scope *Scope, values []tf.Output, shape tf.Shape) (output tf.Output) { + if scope.Err() != nil { + return + } + attrs := map[string]interface{}{"shape": shape} + opspec := tf.OpSpec{ + Type: "ParallelConcat", + Input: []tf.Input{ + tf.OutputList(values), + }, + Attrs: attrs, + } + op := scope.AddOperation(opspec) + return op.Output(0) +} + // Computes the mean along sparse segments of a tensor. // // Read @{$math_ops#Segmentation$the section on segmentation} for an explanation of @@ -14318,65 +14419,6 @@ func TensorArraySplitV2(scope *Scope, handle tf.Output, value tf.Output, lengths return op.Output(0) } -// PackAttr is an optional argument to Pack. -type PackAttr func(optionalAttr) - -// PackAxis sets the optional axis attribute to value. -// -// value: Dimension along which to pack. Negative values wrap around, so the -// valid range is `[-(R+1), R+1)`. -// If not specified, defaults to 0 -func PackAxis(value int64) PackAttr { - return func(m optionalAttr) { - m["axis"] = value - } -} - -// Packs a list of `N` rank-`R` tensors into one rank-`(R+1)` tensor. -// -// Packs the `N` tensors in `values` into a tensor with rank one higher than each -// tensor in `values`, by packing them along the `axis` dimension. -// Given a list of tensors of shape `(A, B, C)`; -// -// if `axis == 0` then the `output` tensor will have the shape `(N, A, B, C)`. -// if `axis == 1` then the `output` tensor will have the shape `(A, N, B, C)`. -// Etc. -// -// For example: -// -// ``` -// # 'x' is [1, 4] -// # 'y' is [2, 5] -// # 'z' is [3, 6] -// pack([x, y, z]) => [[1, 4], [2, 5], [3, 6]] # Pack along first dim. -// pack([x, y, z], axis=1) => [[1, 2, 3], [4, 5, 6]] -// ``` -// -// This is the opposite of `unpack`. -// -// Arguments: -// values: Must be of same shape and type. -// -// Returns The packed tensor. -func Pack(scope *Scope, values []tf.Output, optional ...PackAttr) (output tf.Output) { - if scope.Err() != nil { - return - } - attrs := map[string]interface{}{} - for _, a := range optional { - a(attrs) - } - opspec := tf.OpSpec{ - Type: "Pack", - Input: []tf.Input{ - tf.OutputList(values), - }, - Attrs: attrs, - } - op := scope.AddOperation(opspec) - return op.Output(0) -} - // Reorders a SparseTensor into the canonical, row-major ordering. // // Note that by convention, all sparse ops preserve the canonical ordering along @@ -30668,45 +30710,3 @@ func DecodeWav(scope *Scope, contents tf.Output, optional ...DecodeWavAttr) (aud op := scope.AddOperation(opspec) return op.Output(0), op.Output(1) } - -// Concatenates a list of `N` tensors along the first dimension. -// -// The input tensors are all required to have size 1 in the first dimension. -// -// For example: -// -// ``` -// # 'x' is [[1, 4]] -// # 'y' is [[2, 5]] -// # 'z' is [[3, 6]] -// parallel_concat([x, y, z]) => [[1, 4], [2, 5], [3, 6]] # Pack along first dim. -// ``` -// -// The difference between concat and parallel_concat is that concat requires all -// of the inputs be computed before the operation will begin but doesn't require -// that the input shapes be known during graph construction. Parallel concat -// will copy pieces of the input into the output as they become available, in -// some situations this can provide a performance benefit. -// -// Arguments: -// values: Tensors to be concatenated. All must have size 1 in the first dimension -// and same shape. -// shape: the final shape of the result; should be equal to the shapes of any input -// but with the number of input values in the first dimension. -// -// Returns The concatenated tensor. -func ParallelConcat(scope *Scope, values []tf.Output, shape tf.Shape) (output tf.Output) { - if scope.Err() != nil { - return - } - attrs := map[string]interface{}{"shape": shape} - opspec := tf.OpSpec{ - Type: "ParallelConcat", - Input: []tf.Input{ - tf.OutputList(values), - }, - Attrs: attrs, - } - op := scope.AddOperation(opspec) - return op.Output(0) -} -- cgit v1.2.3