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cudnnDeConvolution_algofindfw.go
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package gocudnn
/*
#include <cudnn.h>
*/
import "C"
import (
"fmt"
"unsafe"
"github.com/dereklstinson/cutil"
)
//DeConvFwdAlgoPerformance is a struct that holds the performance of the algorithm
type DeConvFwdAlgoPerformance struct {
Algo DeConvFwdAlgo `json:"algo,omitempty"`
Status Status `json:"status,omitempty"`
Time float32 `json:"time,omitempty"`
Memory uint `json:"memory,omitempty"`
Determinism Determinism `json:"determinism,omitempty"`
MathType MathType `json:"math_type,omitempty"`
}
func (cb DeConvFwdAlgoPerformance) String() string {
return fmt.Sprintf("DeConvFwdAlgoPerformance{\n%v,\n%v,\nTime: %v,\nMemory: %v,\n%v,\n%v,\n}\n", cb.Algo, cb.Status, cb.Time, cb.Memory, cb.Determinism, cb.MathType)
}
func convertDeConvFwdAlgoPerformance(input C.cudnnConvolutionBwdDataAlgoPerf_t) DeConvFwdAlgoPerformance {
var x DeConvFwdAlgoPerformance
x.Algo = DeConvFwdAlgo(input.algo)
x.Status = Status(input.status)
x.Time = float32(input.time)
x.Memory = uint(input.memory)
x.Determinism = Determinism(input.determinism)
x.MathType = MathType(input.mathType)
return x
}
//Algo returns an Algorithm Struct
func (c DeConvFwdAlgo) Algo() Algorithm {
return makealgorithmforbwddata(c.c())
}
//GetForwardAlgorithmMaxCount returns the max number of Algorithm
func (c *DeConvolutionD) getForwardAlgorithmMaxCount(handle *Handle) (int32, error) {
var count C.int
var err error
if handle.w != nil {
err = handle.w.Work(func() error {
return Status(C.cudnnGetConvolutionBackwardDataAlgorithmMaxCount(handle.x, &count)).error("(c *ConvolutionD) getForwardAlgorithmMaxCount(handle *Handle)")
})
} else {
err = Status(C.cudnnGetConvolutionBackwardDataAlgorithmMaxCount(handle.x, &count)).error("(c *ConvolutionD) getForwardAlgorithmMaxCount(handle *Handle)")
}
return int32(count), err
}
//FindForwardAlgorithm will find the top performing algoriths and return the best algorithms in accending order they are limited to the number passed in requestedAlgoCount.
//So if 4 is passed through in requestedAlgoCount, then it will return the top 4 performers in the ConvFwdAlgoPerformance struct. using this could possible give the user cheat level performance :-)
func (c *DeConvolutionD) FindForwardAlgorithm(
handle *Handle,
xD *TensorD,
wD *FilterD,
yD *TensorD,
) ([]DeConvFwdAlgoPerformance, error) {
requestedAlgoCount, err := c.getForwardAlgorithmMaxCount(handle)
if err != nil {
return nil, err
}
perfResults := make([]C.cudnnConvolutionBwdDataAlgoPerf_t, requestedAlgoCount)
var actualalgocount C.int
if handle.w != nil {
err = handle.w.Work(func() error {
return Status(C.cudnnFindConvolutionBackwardDataAlgorithm(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
C.int(requestedAlgoCount),
&actualalgocount,
&perfResults[0],
)).error("(c *ConvolutionD) FindBackwardDataAlgorithm")
})
} else {
err = Status(C.cudnnFindConvolutionBackwardDataAlgorithm(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
C.int(requestedAlgoCount),
&actualalgocount,
&perfResults[0],
)).error("(c *ConvolutionD) FindBackwardDataAlgorithm")
}
if err != nil {
return nil, err
}
results := make([]DeConvFwdAlgoPerformance, int32(actualalgocount))
for i := int32(0); i < int32(actualalgocount); i++ {
results[i] = convertDeConvFwdAlgoPerformance(perfResults[i])
}
return results, err
}
//FindForwardAlgorithmEx finds some algorithms with memory
func (c *DeConvolutionD) FindForwardAlgorithmEx(
handle *Handle,
xD *TensorD,
x cutil.Mem,
wD *FilterD,
w cutil.Mem,
yD *TensorD,
y cutil.Mem,
wspace cutil.Mem,
wspaceSIBlimit uint) ([]DeConvFwdAlgoPerformance, error) {
reqAlgoCount, err := c.getForwardAlgorithmMaxCount(handle)
if err != nil {
return nil, err
}
perfResults := make([]C.cudnnConvolutionBwdDataAlgoPerf_t, reqAlgoCount)
var actualalgocount C.int
if handle.w != nil {
err = handle.w.Work(func() error {
if wspace == nil {
return Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w.Ptr(),
xD.descriptor, x.Ptr(),
c.descriptor,
yD.descriptor, y.Ptr(),
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], nil, C.size_t(0))).error("(c *DeConvolutionD) FindForwardAlgorithmEx")
}
return Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w.Ptr(),
xD.descriptor, x.Ptr(),
c.descriptor,
yD.descriptor, y.Ptr(),
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], wspace.Ptr(), C.size_t(wspaceSIBlimit))).error("(c *DeConvolutionD) FindForwardAlgorithmEx")
})
} else {
if wspace == nil {
err = Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w.Ptr(),
xD.descriptor, x.Ptr(),
c.descriptor,
yD.descriptor, y.Ptr(),
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], nil, C.size_t(0))).error("(c *DeConvolutionD) FindForwardAlgorithmEx")
} else {
err = Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w.Ptr(),
xD.descriptor, x.Ptr(),
c.descriptor,
yD.descriptor, y.Ptr(),
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], wspace.Ptr(), C.size_t(wspaceSIBlimit))).error("(c *DeConvolutionD) FindForwardAlgorithmEx")
}
}
if err != nil {
return nil, err
}
results := make([]DeConvFwdAlgoPerformance, int32(actualalgocount))
for i := int32(0); i < int32(actualalgocount); i++ {
results[i] = convertDeConvFwdAlgoPerformance(perfResults[i])
}
return results, err
}
//FindForwardAlgorithmExUS is like FindForwardAlgorithmEx but uses unsafe.Pointer instead of cutil.Mem
func (c *DeConvolutionD) FindForwardAlgorithmExUS(
handle *Handle,
xD *TensorD,
x unsafe.Pointer,
wD *FilterD,
w unsafe.Pointer,
yD *TensorD,
y unsafe.Pointer,
wspace unsafe.Pointer,
wspaceSIBlimit uint) ([]DeConvFwdAlgoPerformance, error) {
reqAlgoCount, err := c.getForwardAlgorithmMaxCount(handle)
if err != nil {
return nil, err
}
perfResults := make([]C.cudnnConvolutionBwdDataAlgoPerf_t, reqAlgoCount)
var actualalgocount C.int
if handle.w != nil {
err = handle.w.Work(func() error {
return Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w,
xD.descriptor, x,
c.descriptor,
yD.descriptor, y,
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], wspace, C.size_t(wspaceSIBlimit))).error(" (c *DeConvolutionD) FindForwardAlgorithmExUS")
})
} else {
err = Status(C.cudnnFindConvolutionBackwardDataAlgorithmEx(
handle.x,
wD.descriptor, w,
xD.descriptor, x,
c.descriptor,
yD.descriptor, y,
C.int(reqAlgoCount), &actualalgocount,
&perfResults[0], wspace, C.size_t(wspaceSIBlimit))).error(" (c *DeConvolutionD) FindForwardAlgorithmExUS")
}
if err != nil {
return nil, err
}
results := make([]DeConvFwdAlgoPerformance, int32(actualalgocount))
for i := int32(0); i < int32(actualalgocount); i++ {
results[i] = convertDeConvFwdAlgoPerformance(perfResults[i])
}
return results, err
}
//GetForwardAlgorithm gives a good algo with the limits given to it
func (c *DeConvolutionD) GetForwardAlgorithm(
handle *Handle,
xD *TensorD,
wD *FilterD,
yD *TensorD,
pref DeConvolutionForwardPref,
wspaceSIBlimit uint) (DeConvFwdAlgo, error) {
var algo C.cudnnConvolutionBwdDataAlgo_t
var err error
if handle.w != nil {
err = handle.w.Work(func() error {
return Status(C.cudnnGetConvolutionBackwardDataAlgorithm(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
pref.c(), (C.size_t)(wspaceSIBlimit), &algo)).error("(c *DeConvolutionD) GetForwardAlgorithm")
})
} else {
err = Status(C.cudnnGetConvolutionBackwardDataAlgorithm(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
pref.c(), (C.size_t)(wspaceSIBlimit), &algo)).error("(c *DeConvolutionD) GetForwardAlgorithm")
}
return DeConvFwdAlgo(algo), err
}
//GetForwardAlgorithmV7 will find the top performing algoriths and return the best algorithms in accending order they are limited to the number passed in requestedAlgoCount.
//So if 4 is passed through in requestedAlgoCount, then it will return the top 4 performers in the ConvFwdAlgoPerformance struct. using this could possible give the user cheat level performance :-)
func (c *DeConvolutionD) GetForwardAlgorithmV7(
handle *Handle,
xD *TensorD,
wD *FilterD,
yD *TensorD,
) ([]DeConvFwdAlgoPerformance, error) {
requestedAlgoCount, err := c.getForwardAlgorithmMaxCount(handle)
if err != nil {
return nil, err
}
perfResults := make([]C.cudnnConvolutionBwdDataAlgoPerf_t, requestedAlgoCount)
var actualalgocount C.int
if handle.w != nil {
err = handle.w.Work(func() error {
return Status(C.cudnnGetConvolutionBackwardDataAlgorithm_v7(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
C.int(requestedAlgoCount),
&actualalgocount,
&perfResults[0])).error("(c *DeConvolutionD) GetForwardAlgorithmV7")
})
} else {
err = Status(C.cudnnGetConvolutionBackwardDataAlgorithm_v7(
handle.x,
wD.descriptor,
xD.descriptor,
c.descriptor,
yD.descriptor,
C.int(requestedAlgoCount),
&actualalgocount,
&perfResults[0])).error("(c *DeConvolutionD) GetForwardAlgorithmV7")
}
if err != nil {
return nil, err
}
results := make([]DeConvFwdAlgoPerformance, int32(actualalgocount))
for i := int32(0); i < int32(actualalgocount); i++ {
results[i] = convertDeConvFwdAlgoPerformance(perfResults[i])
}
return results, err
}
func (c DeConvFwdAlgo) String() string {
switch c {
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_0):
return fmt.Sprint("DeConvFwdAlgo0")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_1):
return fmt.Sprint("DeConvFwdAlgo1")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_FFT):
return fmt.Sprint("DeConvFwdAlgoFFT")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_FFT_TILING):
return fmt.Sprint("DeConvFwdAlgoFFTTiling")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_WINOGRAD):
return fmt.Sprint("DeConvFwdAlgoWinograd")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_WINOGRAD_NONFUSED):
return fmt.Sprint("DeConvFwdAlgoWinoGradNonFused")
case DeConvFwdAlgo(C.CUDNN_CONVOLUTION_BWD_DATA_ALGO_COUNT):
return fmt.Sprint("DeConvFwdAlgoCount")
default:
return fmt.Sprint("Not supported")
}
}