未验证 提交 12bf0502 编写于 作者: Y Yiqun Liu 提交者: GitHub

Implement FunctionTraits to support two kinds of elementwise functor and...

Implement FunctionTraits to support two kinds of elementwise functor and remove some old codes for broadcast. (#35688)
上级 3493c46e
......@@ -24,15 +24,15 @@ struct CudaAbsFunctor;
template <typename T>
struct CudaAbsFunctor<T, math::Complex<T, math::Real<T>>> {
__device__ __forceinline__ math::Real<T> operator()(const T* args) const {
return abs(args[0]);
__device__ __forceinline__ math::Real<T> operator()(const T& x) const {
return abs(x);
}
};
template <typename T>
struct CudaAbsFunctor<T, math::NoComplex<T, math::Real<T>>> {
__device__ __forceinline__ T operator()(const T* args) const {
return std::abs(args[0]);
__device__ __forceinline__ T operator()(const T& x) const {
return std::abs(x);
}
};
......
......@@ -24,9 +24,8 @@ struct CudaReluFunctor : public BaseActivationFunctor<T> {
T zero = static_cast<T>(0.0f);
// relu(x) = max(x, 0)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] > zero ? args[0] : zero;
__device__ __forceinline__ T operator()(const T& x) const {
return x > zero ? x : zero;
}
};
......@@ -35,10 +34,8 @@ struct CudaReluGradFunctor : public BaseActivationFunctor<T> {
T zero = static_cast<T>(0.0f);
// dx = dout * (out > 0)
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return args[1] > zero ? args[0] : zero;
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return out > zero ? dout : zero;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -54,9 +51,8 @@ struct CudaLeakyReluFunctor : public BaseActivationFunctor<T> {
}
// leakyrelu(x) = x > 0 ? x : alpha * x
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] > zero ? args[0] : static_cast<T>(alpha) * args[0];
__device__ __forceinline__ T operator()(const T& x) const {
return x > zero ? x : static_cast<T>(alpha) * x;
}
};
......@@ -70,10 +66,8 @@ struct CudaLeakyReluGradFunctor : public BaseActivationFunctor<T> {
}
// dx = dout * (x > 0 ? 1 : alpha)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[1] > zero ? args[0] : static_cast<T>(alpha) * args[0];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return x > zero ? dout : static_cast<T>(alpha) * dout;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -85,9 +79,8 @@ struct CudaSigmoidFunctor : public BaseActivationFunctor<T> {
MPType one = static_cast<MPType>(1.0f);
// sigmoid(x) = 1 / (1 + exp(-x))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(one / (one + exp(-x)));
}
};
......@@ -97,10 +90,8 @@ struct CudaSigmoidGradFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// dx = dout * out * (1 - out)
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] * args[1] * (one - args[1]);
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return dout * out * (one - out);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -108,14 +99,12 @@ struct CudaSigmoidGradFunctor : public BaseActivationFunctor<T> {
template <typename T>
struct CudaSiluFunctor : public BaseActivationFunctor<T> {
// MPType means Compute Type
using MPType = typename details::MPTypeTrait<T>::Type;
MPType one = static_cast<MPType>(1.0f);
// silu(x) = x / (1 + exp(-x))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(x / (one + exp(-x)));
}
};
......@@ -126,11 +115,10 @@ struct CudaSiluGradFunctor : public BaseActivationFunctor<T> {
MPType one = static_cast<MPType>(1.0f);
// dx = dout * (1 + exp(-x) + x * exp(-x) / (1 + exp(-x))^2)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType temp = one / (one + exp(-x));
return static_cast<T>(dout * (temp * (one + x * (one - temp))));
}
......@@ -147,9 +135,8 @@ struct CudaLogSigmoidFunctor : public BaseActivationFunctor<T> {
// For numerical stability,
// logsigmoid(x) =
// - (max(-x, 0) + log(exp(-max(-x, 0)) + exp(-x - max(-x, 0))))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
MPType temp = x > zero ? zero : -x;
return static_cast<T>(-temp - log(exp(-temp) + exp(-x - temp)));
}
......@@ -164,11 +151,10 @@ struct CudaLogSigmoidGradFunctor : public BaseActivationFunctor<T> {
// For numerical stability:
// dx = dout * exp(-x - max(-x, 0)) / (exp(-max(-x, 0)) + exp(-x - max(-x,
// 0)))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType temp1 = x > zero ? zero : -x;
MPType temp2 = exp(-x - temp1);
return static_cast<T>(dout * (temp2 / (exp(-temp1) + temp2)));
......@@ -182,9 +168,8 @@ struct CudaAtanFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// atan(x) = atan(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(atan(x));
}
};
......@@ -194,10 +179,8 @@ struct CudaAtanGradFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// dx = dout / (1 + x^2)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / (one + args[1] * args[1]);
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout / (one + x * x);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -214,9 +197,7 @@ struct CudaSoftShrinkFunctor : public BaseActivationFunctor<T> {
// softshrink(x) = x - lambda, if x > lambda;
// x + lambda, if x < -lambda;
// 0, otherwise.
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[0];
__device__ __forceinline__ T operator()(const T& x) const {
T l = static_cast<T>(lambda);
T temp1 = static_cast<T>(x > l);
T temp2 = static_cast<T>(x < -l);
......@@ -234,12 +215,9 @@ struct CudaSoftShrinkGradFunctor : public BaseActivationFunctor<T> {
}
// dx = dout, if x > lambda or x < -lambda else 0
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
T l = static_cast<T>(lambda);
return (x >= -l && x <= l) ? zero : args[0];
return (x >= -l && x <= l) ? zero : dout;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -250,9 +228,8 @@ struct CudaCeilFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// ceil(x) = ceil(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(ceil(x));
}
};
......@@ -262,9 +239,8 @@ struct CudaFloorFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// floor(x) = floor(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(floor(x));
}
};
......@@ -274,17 +250,16 @@ struct CudaRoundFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// round(x) = round(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(round(x));
}
};
// grad functor for ceil, floor and round
// GradFunctor for ceil, floor and round
template <typename T>
struct CudaZeroGradFunctor : public BaseActivationFunctor<T> {
__device__ __forceinline__ T operator()(const T* args) const {
__device__ __forceinline__ T operator()(const T& x) const {
return static_cast<T>(0.0f);
}
......@@ -296,9 +271,8 @@ struct CudaCosFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// cos(x) = cos(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(cos(x));
}
};
......@@ -308,11 +282,10 @@ struct CudaCosGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout * (-sin(x))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(-dout * sin(x));
}
......@@ -324,9 +297,8 @@ struct CudaSinFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// sin(x) = sin(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(sin(x));
}
};
......@@ -336,11 +308,10 @@ struct CudaSinGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout * cos(x)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout * cos(x));
}
......@@ -352,9 +323,8 @@ struct CudaTanFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// tan(x) = tan(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(tan(x));
}
};
......@@ -364,11 +334,10 @@ struct CudaTanGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout / cos(x)^2
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout / (cos(x) * cos(x)));
}
......@@ -380,9 +349,8 @@ struct CudaAsinFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// asin(x) = asin(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(asin(x));
}
};
......@@ -393,11 +361,10 @@ struct CudaAsinGradFunctor : public BaseActivationFunctor<T> {
MPType one = static_cast<MPType>(1.0f);
// dx = dout / sqrt(1 - x^2)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout / sqrt(one - x * x));
}
......@@ -409,9 +376,8 @@ struct CudaAcosFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// acos(x) = acos(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(acos(x));
}
};
......@@ -422,11 +388,10 @@ struct CudaAcosGradFunctor : public BaseActivationFunctor<T> {
MPType one = static_cast<MPType>(1.0f);
// dx = -dout / sqrt(1 - x^2)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(-dout / sqrt(one - x * x));
}
......@@ -438,9 +403,8 @@ struct CudaCoshFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// cosh(x) = cosh(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(cosh(x));
}
};
......@@ -450,11 +414,10 @@ struct CudaCoshGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout * sinh(x)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout * sinh(x));
}
......@@ -466,9 +429,8 @@ struct CudaSinhFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// sinh(x) = sinh(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(sinh(x));
}
};
......@@ -478,11 +440,10 @@ struct CudaSinhGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout * cosh(x)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout * cosh(x));
}
......@@ -494,9 +455,8 @@ struct CudaTanhFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// tanh(x) = tanh(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(tanh(x));
}
};
......@@ -506,11 +466,7 @@ struct CudaTanhGradFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// dx = dout * (1 - out^2)
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
T dout = static_cast<T>(args[0]);
T out = static_cast<T>(args[1]);
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return dout * (one - out * out);
}
......@@ -522,19 +478,14 @@ struct CudaReciprocalFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// reciprocal(x) = 1 / x
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return one / args[0];
}
__device__ __forceinline__ T operator()(const T& x) const { return one / x; }
};
template <typename T>
struct CudaReciprocalGradFunctor : public BaseActivationFunctor<T> {
// dx = -dout * out^2
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return -args[0] * args[1] * args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return -dout * out * out;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -545,9 +496,8 @@ struct CudaExpFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// exp(x) = exp(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(exp(x));
}
};
......@@ -555,10 +505,8 @@ struct CudaExpFunctor : public BaseActivationFunctor<T> {
template <typename T>
struct CudaExpGradFunctor : public BaseActivationFunctor<T> {
// dx = dout * out
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] * args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return dout * out;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -569,9 +517,8 @@ struct CudaExpm1Functor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// expm1(x) = expm1(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(expm1(x));
}
};
......@@ -579,10 +526,8 @@ struct CudaExpm1Functor : public BaseActivationFunctor<T> {
template <typename T>
struct CudaExpm1GradFunctor : public BaseActivationFunctor<T> {
// dx = dout * out
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] * args[1] + args[0];
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return dout * out + dout;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -593,9 +538,8 @@ struct CudaLogFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// log(x) = log(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(log(x));
}
};
......@@ -603,10 +547,8 @@ struct CudaLogFunctor : public BaseActivationFunctor<T> {
template <typename T>
struct CudaLogGradFunctor : public BaseActivationFunctor<T> {
// dx = dout / x
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout / x;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -615,10 +557,7 @@ struct CudaLogGradFunctor : public BaseActivationFunctor<T> {
template <typename T>
struct CudaSquareFunctor : public BaseActivationFunctor<T> {
// square(x) = x * x
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] * args[0];
}
__device__ __forceinline__ T operator()(const T& x) const { return x * x; }
};
template <typename T>
......@@ -626,10 +565,8 @@ struct CudaSquareGradFunctor : public BaseActivationFunctor<T> {
T two = static_cast<T>(2.0f);
// dx = dout * 2 * x
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] * two * args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout * two * x;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -640,9 +577,8 @@ struct CudaSqrtFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// sqrt(x) = sqrt(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(sqrt(x));
}
};
......@@ -652,10 +588,8 @@ struct CudaSqrtGradFunctor : public BaseActivationFunctor<T> {
T one_half = static_cast<T>(0.5f);
// dx = dout * 0.5 / out
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
return one_half * args[0] / args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return one_half * dout / out;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -666,9 +600,8 @@ struct CudaRsqrtFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// rsqrt(x) = rsqrt(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(rsqrt(x));
}
};
......@@ -677,12 +610,9 @@ template <typename T>
struct CudaRsqrtGradFunctor : public BaseActivationFunctor<T> {
T minus_one_half = static_cast<T>(-0.5f);
// dx = dout * -0.5 / out^3
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
T out = args[1];
return minus_one_half * args[0] * out * out * out;
// dx = -0.5 * dout * out^3
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return minus_one_half * dout * out * out * out;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -694,9 +624,8 @@ struct CudaLog1pFunctor : public BaseActivationFunctor<T> {
MPType one = static_cast<MPType>(1.0f);
// log1p(x) = log(1 + x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(log(one + x));
}
};
......@@ -706,10 +635,8 @@ struct CudaLog1pGradFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// dx = dout / (1 + x)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / (one + args[1]);
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout / (one + x);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -720,9 +647,8 @@ struct CudaLog2Functor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// log2(x) = log2(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(log2(x));
}
};
......@@ -733,10 +659,8 @@ struct CudaLog2GradFunctor : public BaseActivationFunctor<T> {
T log_two = static_cast<T>(log(static_cast<MPType>(2.0f)));
// dx = dout / (x * log(2))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / (args[1] * log_two);
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout / (x * log_two);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -747,9 +671,8 @@ struct CudaLog10Functor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// log10(x) = log10(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(log10(x));
}
};
......@@ -760,10 +683,8 @@ struct CudaLog10GradFunctor : public BaseActivationFunctor<T> {
T log_ten = static_cast<T>(log(static_cast<MPType>(10.0f)));
// dx = dout / (x * log(10))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / (args[1] * log_ten);
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return dout / (x * log_ten);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -779,9 +700,7 @@ struct CudaBReluFunctor : public BaseActivationFunctor<T> {
}
// brelu(x) = min(max(x, t_min), t_max)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[0];
__device__ __forceinline__ T operator()(const T& x) const {
T t_min_cast = static_cast<T>(t_min);
T t_max_cast = static_cast<T>(t_max);
T temp_max = x > t_min_cast ? x : t_min_cast;
......@@ -801,11 +720,7 @@ struct CudaBReluGradFunctor : public BaseActivationFunctor<T> {
}
// dx = (x > t_min && x < t_max) ? dout : 0
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T dout = args[0];
T x = args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
T t_min_cast = static_cast<T>(t_min);
T t_max_cast = static_cast<T>(t_max);
return (x > t_min_cast && x < t_max_cast) ? dout : zero;
......@@ -825,10 +740,9 @@ struct CudaSoftReluFunctor : public BaseActivationFunctor<T> {
}
// soft_relu(x) = log(1 + exp(max(min(x, threshold), -threshold)))
// Inputs: args[0], the input x
// threshold should not be negative
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
MPType t = static_cast<MPType>(threshold);
MPType temp_min = x < t ? x : t;
MPType temp_max = temp_min > -t ? temp_min : -t;
......@@ -847,12 +761,11 @@ struct CudaSoftReluGradFunctor : public BaseActivationFunctor<T> {
}
// dx = (out > -threshold && out < threshold) ? dout * (1 - exp(-out)) : 0
// Inputs: args[0], the input dout
// args[1], the input out
// threshold should not be negative
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType out = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_out) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType out = static_cast<MPType>(arg_out);
MPType t = static_cast<MPType>(threshold);
return (out > -t && out < t) ? static_cast<T>(dout * (one - exp(-out)))
: static_cast<T>(0.0f);
......@@ -872,9 +785,8 @@ struct CudaSTanhFunctor : public BaseActivationFunctor<T> {
}
// stanh(x) = b * tanh(a * x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
MPType a = static_cast<MPType>(scale_a);
MPType b = static_cast<MPType>(scale_b);
return static_cast<T>(b * tanh(a * x));
......@@ -893,11 +805,10 @@ struct CudaSTanhGradFunctor : public BaseActivationFunctor<T> {
}
// dx = dout * a * b * (1 - tanh(a * x) * tanh(a * x))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType a = static_cast<MPType>(scale_a);
MPType b = static_cast<MPType>(scale_b);
MPType temp = tanh(a * x);
......@@ -919,9 +830,8 @@ struct CudaSoftplusFunctor : public BaseActivationFunctor<T> {
}
// softplus(x) = beta * x > threshold ? x : log(1 + exp(beta * x)) / beta
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
MPType b = static_cast<MPType>(beta);
MPType t = static_cast<MPType>(threshold);
MPType x_beta = x * beta;
......@@ -941,15 +851,14 @@ struct CudaSoftplusGradFunctor : public BaseActivationFunctor<T> {
}
// dx = x * beta > threshold ? dout : dout / (1 + exp(-beta * x))
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType b = static_cast<MPType>(beta);
MPType t = static_cast<MPType>(threshold);
MPType x_beta = x * beta;
return x_beta > t ? args[0] : static_cast<T>(dout / (one + exp(-x_beta)));
return x_beta > t ? arg_dout : static_cast<T>(dout / (one + exp(-x_beta)));
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -960,9 +869,8 @@ struct CudaSoftsignFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// softsign(x) = x / (1 + abs(x))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] / (one + abs(args[0]));
__device__ __forceinline__ T operator()(const T& x) const {
return x / (one + abs(x));
}
};
......@@ -971,11 +879,9 @@ struct CudaSoftsignGradFunctor : public BaseActivationFunctor<T> {
T one = static_cast<T>(1.0f);
// dx = dout / (1 + abs(x))^2
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T temp = one + abs(args[1]);
return args[0] / (temp * temp);
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
T temp = one + abs(x);
return dout / (temp * temp);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -991,10 +897,9 @@ struct CudaRelu6Functor : public BaseActivationFunctor<T> {
}
// relu6(x) = min(max(0, x), 6)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
__device__ __forceinline__ T operator()(const T& x) const {
T t = static_cast<T>(threshold);
return args[0] <= zero ? zero : (args[0] < t ? args[0] : t);
return x <= zero ? zero : (x < t ? x : t);
}
};
......@@ -1008,11 +913,9 @@ struct CudaRelu6GradFunctor : public BaseActivationFunctor<T> {
}
// dx = (out > 0 && out < t) ? dout : 0
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
T t = static_cast<T>(threshold);
return (args[1] > zero && args[1] < t) ? args[0] : zero;
return (out > zero && out < t) ? dout : zero;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -1023,9 +926,8 @@ struct CudaTanhShrinkFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// tanhshrink(x) = x - tanh(x)
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(x - tanh(x));
}
};
......@@ -1035,11 +937,10 @@ struct CudaTanhShrinkGradFunctor : public BaseActivationFunctor<T> {
using MPType = typename details::MPTypeTrait<T>::Type;
// dx = dout * tanh(x)^2
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
return static_cast<T>(dout * tanh(x) * tanh(x));
}
......@@ -1056,9 +957,7 @@ struct CudaHardShrinkFunctor : public BaseActivationFunctor<T> {
}
// hadrshrink(x) = (x > -threshold && x < threshold) ? 0 : x
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[0];
__device__ __forceinline__ T operator()(const T& x) const {
T t = static_cast<T>(threshold);
return (x > -t && x < t) ? zero : x;
}
......@@ -1074,12 +973,9 @@ struct CudaHardShrinkGradFunctor : public BaseActivationFunctor<T> {
}
// dx = (x > -threshold && x < threshold) ? 0 : dout
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
T t = static_cast<T>(threshold);
return (x > -t && x < t) ? zero : args[0];
return (x > -t && x < t) ? zero : dout;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -1099,9 +995,8 @@ struct CudaHardSigmoidFunctor : public BaseActivationFunctor<T> {
// hard_sigmoid(x) = 0, when x <= -3
// 1, when x >= 3
// x * slope + offset, otherwise
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T temp = args[0] * static_cast<T>(slope) + static_cast<T>(offset);
__device__ __forceinline__ T operator()(const T& x) const {
T temp = x * static_cast<T>(slope) + static_cast<T>(offset);
T temp_max = temp > zero ? temp : zero;
T temp_min = temp_max < one ? temp_max : one;
return temp_min;
......@@ -1120,11 +1015,8 @@ struct CudaHardSigmoidGradFunctor : public BaseActivationFunctor<T> {
}
// dx = (out > 0 && out < 1) ? dout * slope : 0
// Inputs: args[0], the input dout
// args[1], the input out
__device__ __forceinline__ T operator()(const T* args) const {
T out = args[1];
return (out > zero && out < one) ? args[0] * static_cast<T>(slope) : zero;
__device__ __forceinline__ T operator()(const T& dout, const T& out) const {
return (out > zero && out < one) ? dout * static_cast<T>(slope) : zero;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepOut; }
......@@ -1141,9 +1033,8 @@ struct CudaSwishFunctor : public BaseActivationFunctor<T> {
}
// swish(x) = x / (1 + exp(-beta * x))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType x = static_cast<MPType>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
MPType x = static_cast<MPType>(arg_x);
MPType b = static_cast<MPType>(beta);
return static_cast<T>(x / (one + exp(-b * x)));
}
......@@ -1160,11 +1051,10 @@ struct CudaSwishGradFunctor : public BaseActivationFunctor<T> {
}
// dx = dout * (1 + exp(-b * x) + b * x * exp(-b * x) / (1 + exp(-b * x))^2)
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType b = static_cast<MPType>(beta);
MPType temp1 = one / (one + exp(-b * x));
MPType out = x * temp1;
......@@ -1186,9 +1076,8 @@ struct CudaThresholdedReluFunctor : public BaseActivationFunctor<T> {
}
// thresholded_relu(x) = x > threshold ? x : 0
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[0] > static_cast<T>(threshold) ? args[0] : zero;
__device__ __forceinline__ T operator()(const T& x) const {
return x > static_cast<T>(threshold) ? x : zero;
}
};
......@@ -1202,10 +1091,8 @@ struct CudaThresholdedReluGradFunctor : public BaseActivationFunctor<T> {
}
// dx = x > threshold ? dout : 0
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
return args[1] > static_cast<T>(threshold) ? args[0] : zero;
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
return x > static_cast<T>(threshold) ? dout : zero;
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -1226,9 +1113,7 @@ struct CudaHardSwishFunctor : public BaseActivationFunctor<T> {
// x , when x >= threshold - offset
// x * (x + offset) / scale, otherwise
// threshold = scale = 6, offset = 3 by default
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[0];
__device__ __forceinline__ T operator()(const T& x) const {
T t = static_cast<T>(threshold);
T temp = x + static_cast<T>(offset);
T temp_max = temp > zero ? temp : zero;
......@@ -1254,15 +1139,12 @@ struct CudaHardSwishGradFunctor : public BaseActivationFunctor<T> {
// dout , when x >= threshold - offset
// dout * (2 * x / scale + offset / scale), otherwise
// threshold = scale = 6, offset = 3 by default
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
T x = args[1];
__device__ __forceinline__ T operator()(const T& dout, const T& x) const {
T o = static_cast<T>(offset);
T s = static_cast<T>(scale);
T temp1 = static_cast<T>(x + o > zero);
T temp2 = static_cast<T>(x + o < static_cast<T>(threshold));
return args[0] * (temp1 * temp2 * (two * x + o) / s + one - temp2);
return dout * (temp1 * temp2 * (two * x + o) / s + one - temp2);
}
static constexpr ActBwdOpFwdDeps FwdDeps() { return kDepX; }
......@@ -1280,9 +1162,8 @@ struct CudaELUFunctor : public BaseActivationFunctor<T> {
}
// elu(x) = max(0, x) + min(0, alpha * (exp(x) - 1))
// Inputs: args[0], the input x
__device__ __forceinline__ T operator()(const T* args) const {
CT x = static_cast<CT>(args[0]);
__device__ __forceinline__ T operator()(const T& arg_x) const {
CT x = static_cast<CT>(arg_x);
CT temp = static_cast<CT>(alpha) * (exp(x) - one);
CT res = (x > zero ? x : zero) + (temp > zero ? zero : temp);
return static_cast<T>(res);
......@@ -1304,11 +1185,10 @@ struct CudaELUGradFunctor : public BaseActivationFunctor<T> {
// dx = dout * alpha * x.exp(), if alpha > 0 and x <= 0
// dx = dout * (1 + alpha * x.exp()), if alpha <= 0 and x > 0
// dx = 0, if alpha <= 0 and x <=0
// Inputs: args[0], the input dout
// args[1], the input x
__device__ __forceinline__ T operator()(const T* args) const {
MPType dout = static_cast<MPType>(args[0]);
MPType x = static_cast<MPType>(args[1]);
__device__ __forceinline__ T operator()(const T& arg_dout,
const T& arg_x) const {
MPType dout = static_cast<MPType>(arg_dout);
MPType x = static_cast<MPType>(arg_x);
MPType a = static_cast<MPType>(alpha);
MPType temp_a_pos = static_cast<MPType>(alpha > 0.0f);
MPType temp_a_neg = static_cast<MPType>(alpha <= 0.0f);
......
......@@ -18,60 +18,46 @@ limitations under the License. */
namespace paddle {
namespace operators {
#define BITWISE_BINARY_FUNCTOR(func, expr, bool_expr) \
template <typename T> \
struct Bitwise##func##CUDAFunctor { \
using ELEM_TYPE = T; \
HOSTDEVICE T operator()(const T* args) const { \
return args[0] expr args[1]; \
} \
}; \
\
template <> \
struct Bitwise##func##CUDAFunctor<bool> { \
using ELEM_TYPE = bool; \
HOSTDEVICE bool operator()(const bool* args) const { \
return args[0] bool_expr args[1]; \
} \
};
BITWISE_BINARY_FUNCTOR(And, &, &&)
BITWISE_BINARY_FUNCTOR(Or, |, ||)
BITWISE_BINARY_FUNCTOR(Xor, ^, !=)
#undef BITWISE_BINARY_FUNCTOR
template <typename Functor>
class BinaryBitwiseOpKernel<platform::CUDADeviceContext, Functor>
: public framework::OpKernel<typename Functor::ELEM_TYPE> {
public:
void Compute(const framework::ExecutionContext& ctx) const override {
using T = typename Functor::ELEM_TYPE;
template <typename T>
struct BitwiseNotCUDAFunctor {
using ELEM_TYPE = T;
HOSTDEVICE T operator()(const T* args) const { return ~args[0]; }
};
auto* x = ctx.Input<framework::Tensor>("X");
auto* y = ctx.Input<framework::Tensor>("Y");
auto* out = ctx.Output<framework::Tensor>("Out");
out->mutable_data<T>(ctx.GetPlace());
template <>
struct BitwiseNotCUDAFunctor<bool> {
using ELEM_TYPE = bool;
HOSTDEVICE bool operator()(const bool* args) const { return !args[0]; }
auto functor = Functor();
std::vector<const framework::Tensor*> ins = {x, y};
std::vector<framework::Tensor*> outs = {out};
const auto& cuda_ctx =
ctx.template device_context<platform::CUDADeviceContext>();
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, T>(
cuda_ctx, ins, &outs, -1, functor);
}
};
template <typename Functor>
class BinaryBitwiseOpKernel<platform::CUDADeviceContext, Functor>
class UnaryBitwiseOpKernel<platform::CUDADeviceContext, Functor>
: public framework::OpKernel<typename Functor::ELEM_TYPE> {
public:
using T = typename Functor::ELEM_TYPE;
void Compute(const framework::ExecutionContext& ctx) const override {
using T = typename Functor::ELEM_TYPE;
auto* x = ctx.Input<framework::Tensor>("X");
auto* out = ctx.Output<framework::Tensor>("Out");
out->mutable_data<T>(ctx.GetPlace());
auto functor = Functor();
std::vector<const framework::Tensor*> ins;
std::vector<framework::Tensor*> outs;
std::vector<const framework::Tensor*> ins = {x};
std::vector<framework::Tensor*> outs = {out};
const auto& cuda_ctx =
ctx.template device_context<platform::CUDADeviceContext>();
int axis = PackTensorsIntoVector<T>(ctx, &ins, &outs);
if (ins.size() == 1) {
LaunchElementwiseCudaKernel<ElementwiseType::kUnary, T, T>(
cuda_ctx, ins, &outs, axis, functor);
} else {
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, T>(
cuda_ctx, ins, &outs, axis, functor);
}
LaunchSameDimsElementwiseCudaKernel<ElementwiseType::kUnary, T, T>(
cuda_ctx, ins, &outs, functor);
}
};
......@@ -81,7 +67,7 @@ class BinaryBitwiseOpKernel<platform::CUDADeviceContext, Functor>
namespace ops = ::paddle::operators;
namespace plat = ::paddle::platform;
REGISTER_BINARY_BITWISE_KERNEL(bitwise_and, CUDA, ops::BitwiseAndCUDAFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_or, CUDA, ops::BitwiseOrCUDAFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_xor, CUDA, ops::BitwiseXorCUDAFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_not, CUDA, ops::BitwiseNotCUDAFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_and, CUDA, ops::BitwiseAndFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_or, CUDA, ops::BitwiseOrFunctor);
REGISTER_BINARY_BITWISE_KERNEL(bitwise_xor, CUDA, ops::BitwiseXorFunctor);
REGISTER_UNARY_BITWISE_KERNEL(bitwise_not, CUDA, ops::BitwiseNotFunctor);
......@@ -17,9 +17,6 @@ limitations under the License. */
#include "paddle/fluid/operators/elementwise/elementwise_op_impl.cu.h"
#include "paddle/fluid/operators/reduce_ops/cub_reduce.h"
namespace ops = paddle::operators;
namespace plat = paddle::platform;
namespace paddle {
namespace operators {
......@@ -38,23 +35,6 @@ struct BitwiseAdd {
}
};
template <typename T, typename Enable = void>
struct CudaEqualReduceFunctor {
using ELEM_TYPE = T;
HOSTDEVICE bool operator()(const T args[]) const {
return (args[0] == args[1]);
}
};
template <typename T>
struct CudaEqualReduceFunctor<
T, typename std::enable_if<std::is_floating_point<T>::value>::type> {
using ELEM_TYPE = T;
HOSTDEVICE bool operator()(const T args[]) const {
return fabs(static_cast<double>(args[0] - args[1])) < 1e-8;
}
};
template <typename DeviceContext, typename Functor>
class CompareReduceOpKernel
: public framework::OpKernel<typename Functor::ELEM_TYPE> {
......@@ -97,6 +77,9 @@ class CompareReduceOpKernel
} // namespace operators
} // namespace paddle
namespace ops = paddle::operators;
namespace plat = paddle::platform;
#define REGISTER_COMPARE_REDUCE_CUDA_KERNEL(op_type, functor) \
REGISTER_OP_CUDA_KERNEL( \
op_type, \
......@@ -109,5 +92,5 @@ class CompareReduceOpKernel
ops::CompareReduceOpKernel<plat::CUDADeviceContext, \
ops::functor<double>>);
REGISTER_COMPARE_REDUCE_CUDA_KERNEL(equal_all, CudaEqualReduceFunctor)
REGISTER_COMPARE_REDUCE_CUDA_KERNEL(equal_all, EqualReduceFunctor)
#undef REGISTER_COMPARE_REDUCE_CUDA_KERNEL
......@@ -21,46 +21,11 @@ namespace plat = paddle::platform;
namespace paddle {
namespace operators {
#define DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(func, op) \
template <typename T, typename Enable = void> \
struct func { \
using ELEMENT_TYPE = T; \
inline HOSTDEVICE bool operator()(const T* args) const { \
return args[0] op args[1]; \
} \
};
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaLessThanFunctor, <)
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaLessEqualFunctor, <=)
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaGreaterThanFunctor, >)
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaGreaterEqualFunctor, >=)
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaEqualFunctor, ==)
DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT(CudaNotEqualFunctor, !=)
#undef DEFINE_CMP_BINARY_FUNCTOR_WITH_PONTER_INPUT
template <typename T>
struct CudaEqualFunctor<
T, typename std::enable_if<std::is_floating_point<T>::value>::type> {
using ELEMENT_TYPE = T;
HOSTDEVICE bool operator()(const T* args) const {
return fabs(static_cast<double>(args[0] - args[1])) < 1e-8;
}
};
template <typename T>
struct CudaNotEqualFunctor<
T, typename std::enable_if<std::is_floating_point<T>::value>::type> {
using ELEMENT_TYPE = T;
HOSTDEVICE bool operator()(const T* args) const {
return fabs(static_cast<double>(args[0] - args[1])) > 1e-8;
}
};
template <typename Functor, typename InverseFunctor>
class CompareOpKernel<platform::CUDADeviceContext, Functor, InverseFunctor>
: public framework::OpKernel<typename Functor::ELEMENT_TYPE> {
: public framework::OpKernel<typename Functor::ELEM_TYPE> {
public:
using InT = typename Functor::ELEMENT_TYPE;
using InT = typename Functor::ELEM_TYPE;
using OutT = bool;
void Compute(const framework::ExecutionContext& ctx) const override {
auto functor = Functor();
......@@ -87,10 +52,10 @@ class CompareOpKernel<platform::CUDADeviceContext, Functor, InverseFunctor>
ops::CompareOpKernel<plat::CUDADeviceContext, ops::func<float>, void>, \
ops::CompareOpKernel<plat::CUDADeviceContext, ops::func<double>, void>);
REGISTER_CUDA_COMPARE_KERNEL(equal, CudaEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(not_equal, CudaNotEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(less_than, CudaLessThanFunctor)
REGISTER_CUDA_COMPARE_KERNEL(less_equal, CudaLessEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(greater_than, CudaGreaterThanFunctor)
REGISTER_CUDA_COMPARE_KERNEL(greater_equal, CudaGreaterEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(equal, EqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(not_equal, NotEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(less_than, LessThanFunctor)
REGISTER_CUDA_COMPARE_KERNEL(less_equal, LessEqualFunctor)
REGISTER_CUDA_COMPARE_KERNEL(greater_than, GreaterThanFunctor)
REGISTER_CUDA_COMPARE_KERNEL(greater_equal, GreaterEqualFunctor)
#undef REGISTER_CUDA_COMPARE_KERNEL
......@@ -11,6 +11,7 @@ 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 "paddle/fluid/operators/elementwise/elementwise_add_op.h"
#include "paddle/fluid/operators/elementwise/elementwise_op_broadcast.cu.h"
#include "paddle/fluid/operators/reduce_ops/reduce_functor_op.h"
......@@ -24,21 +25,6 @@ namespace plat = paddle::platform;
namespace paddle {
namespace operators {
/*
input: an array;
return: the result of the math functor
1. For Unary Op, the length of input array is 1,
e.g. Relu: return args[0] > 0 ? args[0] : 0;
2. For Binary Op, the length of input array is 2,
e.g. Add: return args[0] expr args[1];
*/
template <typename T>
struct CudaAddFunctor {
inline HOSTDEVICE T operator()(const T* args) const {
return args[0] + args[1];
}
};
template <typename T>
class ElementwiseAddKernel<platform::CUDADeviceContext, T>
: public framework::OpKernel<T> {
......@@ -51,7 +37,7 @@ class ElementwiseAddKernel<platform::CUDADeviceContext, T>
int axis = PackTensorsIntoVector<T>(ctx, &ins, &outs);
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, T>(
cuda_ctx, ins, &outs, axis, CudaAddFunctor<T>());
cuda_ctx, ins, &outs, axis, AddFunctor<T>());
}
};
......
......@@ -24,13 +24,6 @@ namespace plat = paddle::platform;
namespace paddle {
namespace operators {
template <typename T>
struct CudaMulFunctor {
inline HOSTDEVICE T operator()(const T* args) const {
return args[0] * args[1];
}
};
template <typename T>
class ElementwiseMulKernel<platform::CUDADeviceContext, T>
: public framework::OpKernel<T> {
......@@ -44,7 +37,7 @@ class ElementwiseMulKernel<platform::CUDADeviceContext, T>
int axis = PackTensorsIntoVector<T>(ctx, &ins, &outs, &x_for_selectedrows);
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, T>(
cuda_ctx, ins, &outs, axis, CudaMulFunctor<T>());
cuda_ctx, ins, &outs, axis, MulFunctor<T>());
}
};
......
......@@ -16,11 +16,10 @@
#include "paddle/fluid/operators/elementwise/elementwise_op_impl.cu.h"
#include "paddle/fluid/operators/kernel_primitives/kernel_primitives.h"
namespace paddle {
namespace operators {
#define MAX_INPUT_NUM 3 // the max num of ET for BroadcacstConfig
namespace kps = paddle::operators::kernel_primitives;
struct DimensionsTransform {
......@@ -46,10 +45,9 @@ struct DimensionsTransform {
axis++;
} else {
PADDLE_THROW(platform::errors::InvalidArgument(
"The %dth dimension of input tensor is expected to be equal "
"with"
"the %dth dimension of output tensor %d or 1, but recieved "
"%d.\n",
"The %d-th dimension of input tensor is expected to be equal "
"with the %d-th dimension of output tensor %d or 1, but "
"recieved %d.",
in_idx + 1, axis + 1, out_dims[axis], in_dim[in_idx]));
}
} while (in_idx < in_dim.size());
......@@ -61,10 +59,9 @@ struct DimensionsTransform {
in_idx++;
} else {
PADDLE_THROW(platform::errors::InvalidArgument(
"The %dth dimension of input tensor is expected to be equal "
"with"
"the %dth dimension of output tensor %d or 1, but recieved "
"%d.\n",
"The %d-th dimension of input tensor is expected to be equal "
"with the %d-th dimension of output tensor %d or 1, but "
"recieved %d.",
in_idx + 1, in_idx + 1, out_dims[in_idx], in_dim[in_idx]));
}
} while (in_idx < dim_size);
......@@ -165,79 +162,71 @@ struct DimensionsTransform {
}
};
template <typename T, int VecSize, int ShapeSize, bool IsBoundary = false>
template <typename T, int VecSize, int Rank, bool IsBoundary = false>
__device__ __forceinline__ void LoadData(
T *dst, const T *__restrict__ src, uint32_t block_offset,
const kps::details::BroadcastConfig<ShapeSize> &config, int numel, int num,
const kps::details::BroadcastConfig<Rank> &config, int numel, int num,
bool need_broadcast) {
// numel : whole num of output
// num: how many data will be deal with in this time
if (need_broadcast) {
kps::ReadDataBc<T, VecSize, 1, 1, ShapeSize, IsBoundary>(
dst, src, block_offset, config, numel, 1, 1);
kps::ReadDataBc<T, VecSize, 1, 1, Rank, IsBoundary>(dst, src, block_offset,
config, numel, 1, 1);
} else {
kps::ReadData<T, VecSize, 1, 1, IsBoundary>(dst, src + block_offset, num);
}
}
template <ElementwiseType ET, typename InT, typename OutT, int ShapeSize,
int VecSize, typename Functor, bool IsBoundary = false>
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize,
int Rank, bool IsBoundary = false>
__device__ void DealSegment(
const framework::Array<const InT *__restrict__, ET> &in, OutT *out,
const framework::Array<bool, MAX_INPUT_NUM> &use_broadcast, uint32_t numel,
const framework::Array<kps::details::BroadcastConfig<ShapeSize>,
MAX_INPUT_NUM> &configlists,
const framework::Array<const InT *__restrict__, Arity> &ins, OutT *out,
const framework::Array<bool, Arity> &use_broadcast, uint32_t numel,
const framework::Array<kps::details::BroadcastConfig<Rank>, Arity> &configs,
int num, Functor func) {
InT args[ET][VecSize];
InT args[Arity][VecSize];
OutT result[VecSize];
int block_offset = blockIdx.x * blockDim.x * VecSize;
// load
#pragma unroll
for (int i = 0; i < ET; i++) {
for (int i = 0; i < Arity; i++) {
kps::Init<InT, VecSize>(args[i], static_cast<InT>(1.0f));
LoadData<InT, VecSize, ShapeSize, IsBoundary>(args[i], in[i], block_offset,
configlists[i], numel, num,
LoadData<InT, VecSize, Rank, IsBoundary>(args[i], ins[i], block_offset,
configs[i], numel, num,
use_broadcast[i]);
}
// compute
if (ET == kUnary) {
kps::ElementwiseUnary<InT, OutT, VecSize, 1, 1, Functor>(result, args[0],
func);
} else if (ET == kBinary) {
kps::ElementwiseBinary<InT, OutT, VecSize, 1, 1, Functor>(result, args[0],
args[1], func);
} else {
kps::ElementwiseTernary<InT, OutT, VecSize, 1, 1, Functor>(
result, args[0], args[1], args[2], func);
}
// compute
const bool kCallElementwiseAny =
platform::FunctionTraits<Functor>::has_pointer_args;
ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, Arity,
kCallElementwiseAny>()(func, args, result);
kps::WriteData<OutT, VecSize, 1, 1, IsBoundary>(out + block_offset, result,
num);
}
template <ElementwiseType ET, typename InT, typename OutT, int ShapeSize,
int VecSize, typename Functor>
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize,
int Rank>
__global__ void BroadcastKernel(
framework::Array<const InT *__restrict__, ET> in, OutT *out,
framework::Array<bool, MAX_INPUT_NUM> use_broadcast, uint32_t numel,
framework::Array<kps::details::BroadcastConfig<ShapeSize>, MAX_INPUT_NUM>
configlists,
framework::Array<const InT *__restrict__, Arity> ins, OutT *out,
framework::Array<bool, Arity> use_broadcast, uint32_t numel,
framework::Array<kps::details::BroadcastConfig<Rank>, Arity> configs,
int main_tid, int tail_tid, Functor func) {
int block_offset = blockIdx.x * blockDim.x * VecSize;
// data offset of this block
if (blockIdx.x < main_tid) {
int num = blockDim.x * VecSize; // blockIdx.x < main_tid
DealSegment<ET, InT, OutT, ShapeSize, VecSize, Functor, false>(
in, out, use_broadcast, numel, configlists, num, func);
DealSegment<InT, OutT, Functor, Arity, VecSize, Rank, false>(
ins, out, use_broadcast, numel, configs, num, func);
} else { // reminder
int num = tail_tid;
DealSegment<ET, InT, OutT, ShapeSize, VecSize, Functor, true>(
in, out, use_broadcast, numel, configlists, num, func);
DealSegment<InT, OutT, Functor, Arity, VecSize, Rank, true>(
ins, out, use_broadcast, numel, configs, num, func);
}
}
template <typename InT, typename OutT, ElementwiseType ET, int VecSize,
int Size, typename Functor>
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize,
int Rank>
void LaunchKernel(const platform::CUDADeviceContext &ctx,
const std::vector<const framework::Tensor *> &ins,
framework::Tensor *out, Functor func,
......@@ -251,53 +240,58 @@ void LaunchKernel(const platform::CUDADeviceContext &ctx,
auto stream = ctx.stream();
OutT *out_data = out->data<OutT>();
framework::Array<kps::details::BroadcastConfig<Size>, MAX_INPUT_NUM>
configlists;
framework::Array<bool, MAX_INPUT_NUM> use_broadcast;
framework::Array<const InT *__restrict__, ET> ins_data;
framework::Array<kps::details::BroadcastConfig<Rank>, Arity> configs;
framework::Array<bool, Arity> use_broadcast;
framework::Array<const InT *__restrict__, Arity> ins_data;
for (int i = 0; i < ET; i++) {
for (int i = 0; i < Arity; i++) {
use_broadcast[i] = (ins[i]->numel() != numel);
ins_data[i] = ins[i]->data<InT>();
if (use_broadcast[i]) {
// get the broadcast config,
// if data shape is[m, n], then you should set data_dim = {n, m}
// eg: out's shape [3, 45, 1]. then out_dims = {1, 45, 3}
configlists[i] = kps::details::BroadcastConfig<Size>(
configs[i] = kps::details::BroadcastConfig<Rank>(
merge_dims.out_dims, merge_dims.in_dims[i], merge_dims.dim_size);
}
}
BroadcastKernel<ET, InT, OutT, Size, VecSize,
Functor><<<blocks, threads, 0, stream>>>(
ins_data, out_data, use_broadcast, numel, configlists, main_tid, tail_tid,
BroadcastKernel<InT, OutT, Functor, Arity, VecSize,
Rank><<<blocks, threads, 0, stream>>>(
ins_data, out_data, use_broadcast, numel, configs, main_tid, tail_tid,
func);
}
template <typename InT, typename OutT, ElementwiseType ET, int VecSize,
typename Functor>
void LaunchBroadcastKernelForDifferentDimSize(
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize>
void LaunchBroadcastKernelForDifferentVecSize(
const platform::CUDADeviceContext &ctx,
const std::vector<const framework::Tensor *> &ins, framework::Tensor *out,
int axis, Functor func) {
const auto merge_dims = DimensionsTransform(ins, out->dims(), axis);
#define DIM_SIZE(size) \
case size: { \
LaunchKernel<InT, OutT, ET, VecSize, size, Functor>(ctx, ins, out, func, \
merge_dims); \
#define CALL_BROADCAST_FOR_DIM_SIZE(rank) \
case rank: { \
LaunchKernel<InT, OutT, Functor, Arity, VecSize, rank>(ctx, ins, out, \
func, merge_dims); \
} break;
switch (merge_dims.dim_size) {
DIM_SIZE(1);
DIM_SIZE(2);
DIM_SIZE(3);
DIM_SIZE(4);
DIM_SIZE(5);
DIM_SIZE(6);
DIM_SIZE(7);
DIM_SIZE(8);
CALL_BROADCAST_FOR_DIM_SIZE(1);
CALL_BROADCAST_FOR_DIM_SIZE(2);
CALL_BROADCAST_FOR_DIM_SIZE(3);
CALL_BROADCAST_FOR_DIM_SIZE(4);
CALL_BROADCAST_FOR_DIM_SIZE(5);
CALL_BROADCAST_FOR_DIM_SIZE(6);
CALL_BROADCAST_FOR_DIM_SIZE(7);
CALL_BROADCAST_FOR_DIM_SIZE(8);
default: {
PADDLE_THROW(platform::errors::InvalidArgument(
"The maximum dimension of input tensor is expected to be less than "
"%d, but recieved %d.\n",
merge_dims.dim_size, framework::DDim::kMaxRank));
}
}
#undef DIM_SIZE
#undef CALL_BROADCAST_FOR_DIM_SIZE
}
template <ElementwiseType ET, typename InT, typename OutT, typename Functor>
......@@ -305,11 +299,21 @@ void LaunchBroadcastElementwiseCudaKernel(
const platform::CUDADeviceContext &ctx,
const std::vector<const framework::Tensor *> &ins,
std::vector<framework::Tensor *> *outs, int axis, Functor func) {
PADDLE_ENFORCE_EQ(ET, ElementwiseType::kBinary,
using Traits = platform::FunctionTraits<Functor>;
const int kArity =
Traits::has_pointer_args ? static_cast<int>(ET) : Traits::arity;
PADDLE_ENFORCE_EQ(ins.size(), kArity,
platform::errors::InvalidArgument(
"Currently, only Support binary calculation, "
"but received %d input tensors.\n",
static_cast<int>(ET)));
"The number of inputs is expected to be equal to the "
"arity of functor. But recieved: the number of inputs "
"is %d, the arity of functor is %d.",
ins.size(), kArity));
PADDLE_ENFORCE_EQ(kArity, 2,
platform::errors::InvalidArgument(
"Currently only broadcast of binary is supported and "
"verified, but received %d.",
kArity));
int in_vec_size = 4;
framework::Tensor *out = (*outs)[0];
for (auto *in : ins) {
......@@ -322,18 +326,18 @@ void LaunchBroadcastElementwiseCudaKernel(
switch (vec_size) {
case 4: {
LaunchBroadcastKernelForDifferentDimSize<InT, OutT, ET, 4>(ctx, ins, out,
axis, func);
LaunchBroadcastKernelForDifferentVecSize<InT, OutT, Functor, kArity, 4>(
ctx, ins, out, axis, func);
break;
}
case 2: {
LaunchBroadcastKernelForDifferentDimSize<InT, OutT, ET, 2>(ctx, ins, out,
axis, func);
LaunchBroadcastKernelForDifferentVecSize<InT, OutT, Functor, kArity, 2>(
ctx, ins, out, axis, func);
break;
}
case 1: {
LaunchBroadcastKernelForDifferentDimSize<InT, OutT, ET, 1>(ctx, ins, out,
axis, func);
LaunchBroadcastKernelForDifferentVecSize<InT, OutT, Functor, kArity, 1>(
ctx, ins, out, axis, func);
break;
}
default: {
......@@ -369,7 +373,5 @@ void LaunchElementwiseCudaKernel(
}
}
#undef MAX_INPUT_NUM
} // namespace operators
} // namespace paddle
......@@ -37,8 +37,10 @@ limitations under the License. */
#endif
#include <thrust/iterator/iterator_adaptor.h>
#include "paddle/fluid/operators/elementwise/elementwise_op_broadcast.cu.h"
#include "paddle/fluid/platform/cuda_device_function.h"
#include "paddle/fluid/platform/cuda_primitives.h"
#ifdef __HIPCC__
constexpr int ELEMWISE_MAX_BLOCK_DIM = 256;
#else
......@@ -278,128 +280,6 @@ void CommonForwardBroadcastCPU(const framework::Tensor *x,
}
}
#if defined(__NVCC__) || defined(__HIPCC__)
template <typename Functor, typename T, typename OutType>
__global__ void ElementwiseKernel(const T *__restrict__ x_data,
const T *__restrict__ y_data,
OutType *__restrict__ out_data, int n,
int post, const size_t total, Functor func) {
int tid = threadIdx.x + blockDim.x * blockIdx.x;
int stride = blockDim.x * gridDim.x;
for (int i = tid; i < total; i += stride) {
int idx = i / post % n;
out_data[i] = func(x_data[i], y_data[idx]);
}
}
template <typename Functor, typename T, typename OutType>
void ComputeElementwiseCUDA(const framework::Tensor *x,
const framework::Tensor *y, framework::Tensor *z,
int pre, int n, int post,
const platform::CUDADeviceContext &ctx,
Functor func, const bool is_xsize_larger = true) {
const T *x_data = x->data<T>();
const T *y_data = y->data<T>();
OutType *out_data = z->mutable_data<OutType>(ctx.GetPlace());
int numel = pre * n * post;
int threads = 256;
int blocks = (numel + threads - 1) / threads;
if (is_xsize_larger) {
ElementwiseKernel<Functor, T,
OutType><<<blocks, threads, 0, ctx.stream()>>>(
x_data, y_data, out_data, n, post, numel, func);
} else {
ElementwiseKernel<Functor, T,
OutType><<<blocks, threads, 0, ctx.stream()>>>(
y_data, x_data, out_data, n, post, numel, func);
}
}
template <typename Functor, typename T, typename OutType = T>
__global__ void CommonForwardBroadcastCUDAKernel(
const int *x_strides_array, const int *y_strides_array,
const int *out_dims_array, const T *x, const T *y, OutType *out,
int out_size, int max_dim, Functor func, const bool is_xsize_larger) {
for (int out_index = blockIdx.x * blockDim.x + threadIdx.x;
out_index < out_size; out_index += blockDim.x * gridDim.x) {
int x_index = 0;
int y_index = 0;
int out_index_quotient = out_index;
int remainder = 0;
#pragma unroll
for (int i = max_dim - 1; i >= 0; --i) {
GetDivMod(out_index_quotient, out_dims_array[i], &out_index_quotient,
&remainder);
x_index += remainder * x_strides_array[i];
y_index += remainder * y_strides_array[i];
}
if (is_xsize_larger) {
out[out_index] = func(x[x_index], y[y_index]);
} else {
out[out_index] = func(y[y_index], x[x_index]);
}
}
}
template <typename Functor, typename T, typename OutType = T>
void CommonForwardBroadcastCUDA(
const framework::Tensor *x, const framework::Tensor *y,
framework::Tensor *z, int *x_dims_array, int *y_dims_array,
int *out_dims_array, int max_dim, const platform::CUDADeviceContext &ctx,
Functor func, const bool is_xsize_larger = true) {
const auto gplace = BOOST_GET_CONST(platform::CUDAPlace, ctx.GetPlace());
auto cplace = platform::CPUPlace();
const T *x_data = x->data<T>();
const T *y_data = y->data<T>();
OutType *out_data = z->mutable_data<OutType>(ctx.GetPlace());
std::vector<int> x_strides_array(max_dim);
std::vector<int> y_strides_array(max_dim);
int x_stride = 1;
int y_stride = 1;
for (int i = max_dim - 1; i >= 0; i--) {
x_strides_array[i] = x_dims_array[i] == 1 ? 0 : x_stride;
y_strides_array[i] = y_dims_array[i] == 1 ? 0 : y_stride;
x_stride *= x_dims_array[i];
y_stride *= y_dims_array[i];
}
int bytes = max_dim * sizeof(int);
auto x_strides_array_tmp = memory::Alloc(ctx, bytes);
int *x_strides_array_gpu =
reinterpret_cast<int *>(x_strides_array_tmp->ptr());
memory::Copy(gplace, x_strides_array_gpu, cplace, x_strides_array.data(),
bytes, ctx.stream());
auto y_strides_array_tmp = memory::Alloc(ctx, bytes);
int *y_strides_array_gpu =
reinterpret_cast<int *>(y_strides_array_tmp->ptr());
memory::Copy(gplace, y_strides_array_gpu, cplace, y_strides_array.data(),
bytes, ctx.stream());
auto out_dims_array_tmp = memory::Alloc(ctx, bytes);
int *out_dims_array_gpu = reinterpret_cast<int *>(out_dims_array_tmp->ptr());
memory::Copy(gplace, out_dims_array_gpu, cplace, out_dims_array, bytes,
ctx.stream());
const int out_size = std::accumulate(out_dims_array, out_dims_array + max_dim,
1, std::multiplies<int>());
dim3 gird_size = dim3(
(out_size + PADDLE_CUDA_THREAD_SIZE - 1) / PADDLE_CUDA_THREAD_SIZE, 1);
dim3 block_size = dim3(PADDLE_CUDA_THREAD_SIZE, 1);
CommonForwardBroadcastCUDAKernel<
Functor, T, OutType><<<gird_size, block_size, 0, ctx.stream()>>>(
x_strides_array_gpu, y_strides_array_gpu, out_dims_array_gpu, x_data,
y_data, out_data, out_size, max_dim, func, is_xsize_larger);
}
#endif // __NVCC__ or __HIPCC__
template <typename T, typename DX_OP, typename DY_OP>
void CommonGradBroadcastCPU(
const framework::Tensor &x, const framework::Tensor &y,
......@@ -1917,21 +1797,10 @@ void CommonElementwiseBroadcastForward(
y_dims_array.data(), out_dims_array.data(), max_dim,
axis);
if (platform::is_gpu_place(ctx.GetPlace())) {
#if defined(__NVCC__) || defined(__HIPCC__)
CommonForwardBroadcastCUDA<Functor, T, OutType>(
x, y, z, x_dims_array.data(), y_dims_array.data(),
out_dims_array.data(), max_dim,
ctx.template device_context<platform::CUDADeviceContext>(), func,
is_xsize_larger);
#endif
} else {
CommonForwardBroadcastCPU<Functor, T, OutType>(
x, y, z, x_dims_array.data(), y_dims_array.data(),
out_dims_array.data(), max_dim,
ctx.template device_context<platform::CPUDeviceContext>(), func,
x, y, z, x_dims_array.data(), y_dims_array.data(), out_dims_array.data(),
max_dim, ctx.template device_context<platform::CPUDeviceContext>(), func,
is_xsize_larger);
}
}
template <typename DeviceContext, typename T, typename DX_OP, typename DY_OP>
......@@ -1975,12 +1844,35 @@ void ElemwiseExplicitGradCompute(const framework::ExecutionContext &ctx,
}
}
// It is a common implementation to compute binary calculation with the support
// of broadcast, supporting both CPU and GPU.
// - CPU implementation cannot support the case when x needs broadcast, thus
// this function need to be called with XxxFunctor and XxxInverseFunctor,
// like paddle/fluid/operators/elementwise/elementwise_add_op.h#L49 - L55.
// - GPU implementation supports all the broadcast cases, thus there is no need
// to define and call with XxxInverseFunctor.
// TODO(liuyiqun): optimize the CPU implementation to support all broadcast
// cases and avoid the need of XxxInverseFunctor.
template <typename Functor, typename DeviceContext, typename T,
typename OutType = T>
void ElementwiseComputeEx(const framework::ExecutionContext &ctx,
const framework::Tensor *x,
const framework::Tensor *y, int axis, Functor func,
framework::Tensor *z) {
if (platform::is_gpu_place(ctx.GetPlace())) {
#if defined(__NVCC__) || defined(__HIPCC__)
std::vector<const framework::Tensor *> ins = {x, y};
std::vector<framework::Tensor *> outs = {z};
z->mutable_data<OutType>(ctx.GetPlace());
const auto &dev_ctx =
ctx.template device_context<platform::CUDADeviceContext>();
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, OutType>(
dev_ctx, ins, &outs, axis, func);
#endif
return;
}
auto x_dims = x->dims();
auto y_dims = y->dims();
bool is_xsize_larger = true;
......@@ -2029,15 +1921,6 @@ void ElementwiseComputeEx(const framework::ExecutionContext &ctx,
return;
}
if (platform::is_gpu_place(ctx.GetPlace())) {
#if defined(__NVCC__) || defined(__HIPCC__)
ComputeElementwiseCUDA<Functor, T, OutType>(
x, y, z, pre, n, post,
ctx.template device_context<platform::CUDADeviceContext>(), func,
is_xsize_larger);
#endif
return;
}
if (post == 1) {
functor.RunRowWise(n, pre);
return;
......
......@@ -11,12 +11,13 @@ 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. */
#pragma once
#include "paddle/fluid/framework/tensor.h"
#include "paddle/fluid/operators/kernel_primitives/kernel_primitives.h"
#include "paddle/fluid/platform/cuda_device_function.h"
#include "paddle/fluid/platform/fast_divmod.h"
#include "paddle/fluid/platform/aligned_vector.h"
#include "paddle/fluid/platform/function_traits.h"
#ifdef __HIPCC__
#define ELEMENTWISE_BLOCK_SIZE 256
......@@ -28,7 +29,8 @@ namespace paddle {
namespace operators {
namespace kps = paddle::operators::kernel_primitives;
enum ElementwiseType { kUnary = 1, kBinary = 2, kTernary = 3 };
enum ElementwiseType { kUnary = 1, kBinary = 2, kTernary = 3, kAny = -1 };
/*
* According to NVIDIA, if number of threads per block is 64/128/256/512,
......@@ -55,7 +57,8 @@ inline int GetThreadsConfig(const platform::CUDADeviceContext &ctx,
}
template <typename InT, typename OutT>
int GetVectorizedSizeForIO(const std::vector<const framework::Tensor *> &ins,
int GetVectorizedSizeForTensors(
const std::vector<const framework::Tensor *> &ins,
const std::vector<framework::Tensor *> &outs) {
int vec_size = 4;
for (auto iter = ins.begin(); iter != ins.end(); ++iter) {
......@@ -69,56 +72,88 @@ int GetVectorizedSizeForIO(const std::vector<const framework::Tensor *> &ins,
return vec_size;
}
template <ElementwiseType ET, int VecSize, typename InT, typename OutT,
typename Functor, bool IsBoundary>
__device__ void DealSegment(
const framework::Array<const InT *__restrict__, ET> &in, OutT *out, int num,
Functor func) {
int data_offset = VecSize * blockIdx.x * blockDim.x;
InT args[ET][VecSize];
OutT result[VecSize];
// load data
#pragma unroll
for (int i = 0; i < ET; i++) {
kps::Init<InT, VecSize>(args[i], static_cast<InT>(1.0f));
kps::ReadData<InT, VecSize, 1, 1, IsBoundary>(args[i], in[i] + data_offset,
num);
template <typename InT, typename OutT, int VecSize, typename Functor, int Arity,
bool CallElementwiseAny = false>
struct ElementwisePrimitiveCaller {
__device__ inline OutT operator()(Functor func, InT (*args)[VecSize],
OutT *result);
};
template <typename InT, typename OutT, int VecSize, typename Functor, int Arity>
struct ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, Arity, true> {
__device__ inline OutT operator()(Functor func, InT (*args)[VecSize],
OutT *result) {
kps::ElementwiseAny<InT, OutT, VecSize, 1, 1, Arity, Functor>(result, args,
func);
}
};
// compute
if (ET == kUnary) {
template <typename InT, typename OutT, int VecSize, typename Functor>
struct ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, 1, false> {
__device__ inline OutT operator()(Functor func, InT (*args)[VecSize],
OutT *result) {
kps::ElementwiseUnary<InT, OutT, VecSize, 1, 1, Functor>(result, args[0],
func);
} else if (ET == kBinary) {
}
};
template <typename InT, typename OutT, int VecSize, typename Functor>
struct ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, 2, false> {
__device__ inline OutT operator()(Functor func, InT (*args)[VecSize],
OutT *result) {
kps::ElementwiseBinary<InT, OutT, VecSize, 1, 1, Functor>(result, args[0],
args[1], func);
} else {
}
};
template <typename InT, typename OutT, int VecSize, typename Functor>
struct ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, 3, false> {
__device__ inline OutT operator()(Functor func, InT **args, OutT *result) {
kps::ElementwiseTernary<InT, OutT, VecSize, 1, 1, Functor>(
result, args[0], args[1], args[2], func);
}
};
// store
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize,
bool IsBoundary>
__device__ void DealSegment(
const framework::Array<const InT *__restrict__, Arity> &in, OutT *out,
int num, Functor func) {
InT args[Arity][VecSize];
OutT result[VecSize];
int data_offset = VecSize * blockIdx.x * blockDim.x;
#pragma unroll
for (int i = 0; i < Arity; i++) {
kps::Init<InT, VecSize>(args[i], static_cast<InT>(1.0f));
kps::ReadData<InT, VecSize, 1, 1, IsBoundary>(args[i], in[i] + data_offset,
num);
}
const bool kCallElementwiseAny =
platform::FunctionTraits<Functor>::has_pointer_args;
ElementwisePrimitiveCaller<InT, OutT, VecSize, Functor, Arity,
kCallElementwiseAny>()(func, args, result);
kps::WriteData<OutT, VecSize, 1, 1, IsBoundary>(out + data_offset, result,
num);
}
template <ElementwiseType ET, int VecSize, typename InT, typename OutT,
typename Functor>
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize>
__global__ void ElementVectorizeKernel(
framework::Array<const InT *__restrict__, ET> in, OutT *out, int size,
framework::Array<const InT *__restrict__, Arity> ins, OutT *out, int size,
Functor func) {
int data_offset = VecSize * blockIdx.x * blockDim.x;
int num = size - data_offset;
// the num this time have to deal with
if (VecSize * blockDim.x > num) { // reminder segment
DealSegment<ET, VecSize, InT, OutT, Functor, true>(in, out, num, func);
DealSegment<InT, OutT, Functor, Arity, VecSize, true>(ins, out, num, func);
} else { // complete segment
DealSegment<ET, VecSize, InT, OutT, Functor, false>(in, out, num, func);
DealSegment<InT, OutT, Functor, Arity, VecSize, false>(ins, out, num, func);
}
}
template <ElementwiseType ET, typename InT, typename OutT, typename Functor,
int VecSize>
template <typename InT, typename OutT, typename Functor, int Arity, int VecSize>
void ElementwiseCudaKernel(const platform::CUDADeviceContext &ctx,
const std::vector<const framework::Tensor *> &ins,
std::vector<framework::Tensor *> *outs,
......@@ -129,14 +164,14 @@ void ElementwiseCudaKernel(const platform::CUDADeviceContext &ctx,
((numel + VecSize - 1) / VecSize + block_size - 1) / block_size;
auto stream = ctx.stream();
OutT *out = (*outs)[0]->data<OutT>();
framework::Array<const InT *__restrict__, ET> in;
for (int i = 0; i < ET; i++) {
in[i] = ins[i]->data<InT>();
OutT *out_data = (*outs)[0]->data<OutT>();
framework::Array<const InT *__restrict__, Arity> ins_data;
for (int i = 0; i < Arity; i++) {
ins_data[i] = ins[i]->data<InT>();
}
ElementVectorizeKernel<ET, VecSize, InT, OutT,
Functor><<<grid_size, block_size, 0, stream>>>(
in, out, numel, func);
ElementVectorizeKernel<InT, OutT, Functor, Arity,
VecSize><<<grid_size, block_size, 0, stream>>>(
ins_data, out_data, numel, func);
}
template <ElementwiseType ET, typename InT, typename OutT, typename Functor>
......@@ -144,17 +179,30 @@ void LaunchSameDimsElementwiseCudaKernel(
const platform::CUDADeviceContext &ctx,
const std::vector<const framework::Tensor *> &ins,
std::vector<framework::Tensor *> *outs, Functor func) {
using Traits = platform::FunctionTraits<Functor>;
const int kArity =
Traits::has_pointer_args ? static_cast<int>(ET) : Traits::arity;
PADDLE_ENFORCE_EQ(ins.size(), kArity,
platform::errors::InvalidArgument(
"The number of inputs is expected to be equal to the "
"arity of functor. But recieved: the number of inputs "
"is %d, the arity of functor is %d.",
ins.size(), kArity));
// calculate the max vec_size for all ins and outs
int vec_size = GetVectorizedSizeForIO<InT, OutT>(ins, *outs);
int vec_size = GetVectorizedSizeForTensors<InT, OutT>(ins, *outs);
switch (vec_size) {
case 4:
ElementwiseCudaKernel<ET, InT, OutT, Functor, 4>(ctx, ins, outs, func);
ElementwiseCudaKernel<InT, OutT, Functor, kArity, 4>(ctx, ins, outs,
func);
break;
case 2:
ElementwiseCudaKernel<ET, InT, OutT, Functor, 2>(ctx, ins, outs, func);
ElementwiseCudaKernel<InT, OutT, Functor, kArity, 2>(ctx, ins, outs,
func);
break;
case 1:
ElementwiseCudaKernel<ET, InT, OutT, Functor, 1>(ctx, ins, outs, func);
ElementwiseCudaKernel<InT, OutT, Functor, kArity, 1>(ctx, ins, outs,
func);
break;
default: {
PADDLE_THROW(platform::errors::Unimplemented(
......
......@@ -22,13 +22,6 @@ namespace plat = paddle::platform;
namespace paddle {
namespace operators {
template <typename T>
struct CudaSubFunctor {
inline HOSTDEVICE T operator()(const T* args) const {
return args[0] - args[1];
}
};
template <typename T>
class ElementwiseSubKernel<platform::CUDADeviceContext, T>
: public framework::OpKernel<T> {
......@@ -41,7 +34,7 @@ class ElementwiseSubKernel<platform::CUDADeviceContext, T>
int axis = PackTensorsIntoVector<T>(ctx, &ins, &outs);
LaunchElementwiseCudaKernel<ElementwiseType::kBinary, T, T>(
cuda_ctx, ins, &outs, axis, CudaSubFunctor<T>());
cuda_ctx, ins, &outs, axis, SubFunctor<T>());
}
};
......
......@@ -52,10 +52,8 @@ template <typename T>
using ReduceParamType = typename CudnnDataType<T>::BatchNormParamType;
template <typename T>
struct CudaAddFunctor {
inline HOSTDEVICE T operator()(const T* args) const {
return args[0] + args[1];
}
struct AddFunctor {
inline HOSTDEVICE T operator()(const T& a, const T& b) const { return a + b; }
};
template <typename InT, typename OutT, int ShapeSize, int VecSize,
......@@ -128,7 +126,7 @@ void LaunchBiasAddFwKernel(const platform::CUDADeviceContext& ctx, int m, int n,
std::vector<int64_t> out_dims = {n, m};
configlists[1] = kps::details::BroadcastConfig<2>(out_dims, input1_dims, 2);
auto func = CudaAddFunctor<T>();
auto func = AddFunctor<T>();
auto stream = ctx.stream();
switch (vec_size) {
case 4: {
......
......@@ -21,7 +21,6 @@
#include <hip/hip_fp16.h>
#endif
// #include <algorithm>
#include "paddle/fluid/platform/cuda_device_function.h"
#include "paddle/fluid/platform/float16.h"
......@@ -135,53 +134,114 @@ __device__ __forceinline__ T BlockYReduce(T val, ReduceOp reducer) {
} // namespace details
/*************************** Compute Function****************************/
/**
* @brief unary function
* @param
* T: data type of in
* OutT: data type of out
* NX: the cols of in
* NY: the rows of in
* BlockSize: the config of this device
* OpFunc: compute functor which have an operator() as following
* template <typename T, typename OutT>
* struct XxxFunctor {
* HOSTDEVICE OutT operator()(const T& a) const {
* return ...;
* }
* };
*/
template <typename T, typename OutT, int NX, int NY, int BlockSize,
class OpFunc>
__device__ __forceinline__ void ElementwiseUnary(OutT* out, const T* in,
OpFunc compute) {
#pragma unroll
for (int idx = 0; idx < NX * NY; idx++) {
out[idx] = static_cast<OutT>(compute(in[idx]));
}
}
/**
* @brief binary function, in1 and in2 have same shape
* @param
* @param
* T: data type of in1, in2
* OutT: data type of out
* NX: the cols of in1, in2
* NY: the rows of in1, in2
* BlockSize: the config of this device
* OpFunc: compute functor eg: in1 + in2, in1 - in2
* OpFunc: compute functor which have an operator() as following
* template <typename T, typename OutT>
* struct XxxFunctor {
* HOSTDEVICE OutT operator()(const T& a, const T& b) const {
* return ...;
* }
* };
*/
template <typename T, typename OutT, int NX, int NY, int BlockSize,
class OpFunc>
__device__ __forceinline__ void ElementwiseBinary(OutT* out, const T* in1,
const T* in2,
OpFunc compute) {
T args[2];
#pragma unroll
for (int idx = 0; idx < NX * NY; ++idx) {
args[0] = in1[idx];
args[1] = in2[idx];
out[idx] = static_cast<OutT>(compute(args));
out[idx] = static_cast<OutT>(compute(in1[idx], in2[idx]));
}
}
/**
* @brief ternary function, in1, in2 and in3 have same shape
* @param
* @param
* T: data type of in1, in2, in3
* OutT: data type of out
* NX: the cols of in1, in2
* NY: the rows of in1, in2
* BlockSize: the config of this device
* OpFunc: compute functor eg: out = in1 * in2 + in3
* OpFunc: compute functor which have an operator() as following
* template <typename T, typename OutT>
* struct XxxFunctor {
* HOSTDEVICE OutT operator()(const T& a, const T& b, const T& c) const {
* return ...;
* }
* };
*/
template <typename T, typename OutT, int NX, int NY, int BlockSize,
class OpFunc>
__device__ __forceinline__ void ElementwiseTernary(OutT* out, const T* in1,
const T* in2, const T* in3,
OpFunc compute) {
T args[3];
#pragma unroll
for (int idx = 0; idx < NX * NY; ++idx) {
args[0] = in1[idx];
args[1] = in2[idx];
args[2] = in3[idx];
out[idx] = static_cast<OutT>(compute(in1[idx], in2[idx], in3[idx]));
}
}
/**
* @brief a general function for elementwise computation, all inputs have
* the same shape.
* @param
* T: data type of in1, in2, in3
* OutT: data type of out
* NX: the cols of in1, in2
* NY: the rows of in1, in2
* BlockSize: the config of this device
* OpFunc: compute functor which have an operator() as following
* template <typename T, typename OutT>
* struct XxxFunctor {
* HOSTDEVICE OutT operator()(const T* args) const {
* return ...;
* }
* };
*/
template <typename T, typename OutT, int NX, int NY, int BlockSize, int Arity,
class OpFunc>
__device__ __forceinline__ void ElementwiseAny(OutT* out, T (*ins)[NX * NY],
OpFunc compute) {
T args[Arity];
#pragma unroll
for (int idx = 0; idx < NX * NY; ++idx) {
#pragma unroll
for (int j = 0; j < Arity; ++j) {
args[j] = ins[j][idx];
}
out[idx] = static_cast<OutT>(compute(args));
}
}
......@@ -189,7 +249,7 @@ __device__ __forceinline__ void ElementwiseTernary(OutT* out, const T* in1,
/**
* @brief cycle binary function, in1's shape size is [1, NX], in2's shape size
* is [NY, NX], out's shape size is [NY, NX]
* @param
* @param
* T: data type of in1, in2
* OutT: data type of out
* NX: the cols of in1, in2
......@@ -211,26 +271,6 @@ __device__ __forceinline__ void CycleBinary(OutT* out, const T* in1,
}
}
/**
* @brief unary function
* @param:
* T: data type of in
* OutT: data type of out
* NX: the cols of in
* NY: the rows of in
* BlockSize: the config of this device
* OpFunc: compute functor eg: relu, exp
*/
template <typename T, typename OutT, int NX, int NY, int BlockSize,
class OpFunc>
__device__ __forceinline__ void ElementwiseUnary(OutT* out, const T* in,
OpFunc compute) {
#pragma unroll
for (int idx = 0; idx < NX * NY; idx++) {
out[idx] = static_cast<OutT>(compute(in + idx));
}
}
/**
* @brief reduce function, in's shape size is [NX, NY].
* If ReduceMode == kLocalMode then reduce NX, the shape of out is [NY, 1],
......@@ -238,7 +278,7 @@ __device__ __forceinline__ void ElementwiseUnary(OutT* out, const T* in,
* shape of out is [NY, NX]. If reduce_last_dim is false and reduce_num was
* split, BlockYReduce will be called. If reduce_last_dim is true and
* reduce_num was split, BlockXReduce will be called
* @typename
* @typename
* T: data type of in
* NX: the cols of in
* NY: the rows of in
......
......@@ -15,18 +15,14 @@
#include <unsupported/Eigen/SpecialFunctions>
#include "paddle/fluid/operators/elementwise/elementwise_op_impl.cu.h"
#include "paddle/fluid/operators/lgamma_op.h"
#include "paddle/fluid/operators/math/complex_functors.h"
namespace paddle {
namespace operators {
template <typename T, typename Enable = void>
struct CudaLgammaFunctor;
template <typename T>
struct CudaLgammaFunctor<T, math::NoComplex<T, math::Real<T>>> {
__device__ __forceinline__ T operator()(const T* args) const {
return Eigen::numext::lgamma(args[0]);
struct CudaLgammaFunctor {
__device__ __forceinline__ T operator()(const T& x) const {
return Eigen::numext::lgamma(x);
}
};
......@@ -37,15 +33,14 @@ class LgammaKernel<platform::CUDADeviceContext, T>
void Compute(const framework::ExecutionContext& context) const override {
const Tensor* x = context.Input<Tensor>("X");
Tensor* out = context.Output<Tensor>("Out");
out->mutable_data<math::Real<T>>(context.GetPlace());
out->mutable_data<T>(context.GetPlace());
auto& dev_ctx = context.device_context<platform::CUDADeviceContext>();
std::vector<const framework::Tensor*> ins = {x};
std::vector<framework::Tensor*> outs = {out};
auto functor = CudaLgammaFunctor<T>();
LaunchSameDimsElementwiseCudaKernel<ElementwiseType::kUnary, T,
math::Real<T>>(dev_ctx, ins, &outs,
functor);
LaunchSameDimsElementwiseCudaKernel<ElementwiseType::kUnary, T, T>(
dev_ctx, ins, &outs, functor);
}
};
......
......@@ -129,17 +129,10 @@ class MatrixRankGPUKernel : public framework::OpKernel<T> {
compare_result.mutable_data<int64_t>(detail::NewAxisDim(dim_out, k),
context.GetPlace());
int axis = -1;
if (eigenvalue_tensor.dims().size() >= tol_tensor.dims().size()) {
ElementwiseComputeEx<GreaterThanFunctor<T>, platform::CUDADeviceContext,
T, int64_t>(context, &eigenvalue_tensor, &tol_tensor,
axis, GreaterThanFunctor<T>(),
&compare_result);
} else {
ElementwiseComputeEx<LessThanFunctor<T>, platform::CUDADeviceContext, T,
ElementwiseComputeEx<GreaterThanFunctor<T>, platform::CUDADeviceContext, T,
int64_t>(context, &eigenvalue_tensor, &tol_tensor,
axis, LessThanFunctor<T>(),
axis, GreaterThanFunctor<T>(),
&compare_result);
}
auto dito_int =
math::DeviceIndependenceTensorOperations<platform::CUDADeviceContext,
int64_t>(context);
......
......@@ -13,6 +13,7 @@
// limitations under the License.
#pragma once
#include <Eigen/src/Core/util/Constants.h>
#include <Eigen/Dense>
#include <Eigen/SVD>
......@@ -296,6 +297,14 @@ struct DeviceIndependenceTensorOperations {
framework::Tensor ret;
std::vector<int> out_shape = GetBroadcastShape({&x, &y});
ret.Resize(framework::make_ddim(out_shape));
if (platform::is_gpu_place(context.GetPlace())) {
#if defined(__NVCC__) || defined(__HIPCC__)
// For GPU, there is no need to define XxxInverseFunctor and call
// ElementwiseComputeEx in two branches.
ElementwiseComputeEx<SubFunctor<T>, DeviceContext, T>(
context, &x, &y, -1, SubFunctor<T>(), &ret);
#endif
} else {
if (x.dims().size() >= y.dims().size()) {
ElementwiseComputeEx<SubFunctor<T>, DeviceContext, T>(
context, &x, &y, -1, SubFunctor<T>(), &ret);
......@@ -305,6 +314,7 @@ struct DeviceIndependenceTensorOperations {
// need reverse will xrank < yrank
context, &x, &y, -1, InverseSubFunctor<T>(), &ret);
}
}
return ret;
}
const framework::Tensor Unsqueeze(const framework::Tensor& x, int axis = 0) {
......
/* Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
Licensed under the Apache License, Version 2.1 (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-2.1
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. */
#pragma once
#include <tuple>
namespace paddle {
namespace platform {
// Declare a template class with a single template parameter.
template <typename>
struct FunctionTraits;
// A forwarding trait allowing functors (objects which have an operator())
// to be used with this traits class.
template <typename T>
struct FunctionTraits : public FunctionTraits<decltype(&T::operator())> {};
// A partial specialization of FunctionTraits for pointers to member functions
// and has const/non-const class member functions.
template <typename ClassType, typename ReturnType, typename... Args>
struct FunctionTraits<ReturnType (ClassType::*)(Args...) const>
: public FunctionTraits<ReturnType(Args...)> {};
template <typename ClassType, typename ReturnType, typename... Args>
struct FunctionTraits<ReturnType (ClassType::*)(Args...)>
: public FunctionTraits<ReturnType(Args...)> {};
// An implementation for common function.
template <typename ReturnType, typename... Args>
struct FunctionTraits<ReturnType(Args...)> {
static const size_t arity = sizeof...(Args);
static const bool has_pointer_args =
(arity == 1) &&
(std::is_pointer<
typename std::tuple_element<0, std::tuple<Args...>>::type>::value);
};
} // namespace platform
} // namespace paddle
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