cavis/libnd4j/include/graph/RandomGenerator.h

/*******************************************************************************
 * Copyright (c) 2015-2018 Skymind, Inc.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Apache License, Version 2.0 which is available at
 * https://www.apache.org/licenses/LICENSE-2.0.
 *
 * 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.
 *
 * SPDX-License-Identifier: Apache-2.0
 ******************************************************************************/

//
//  @author raver119@protonmail.com
//

#ifndef LIBND4J_GRAPH_RNG_H
#define LIBND4J_GRAPH_RNG_H

#include <types/u64.h>
#include <pointercast.h>
#include <op_boilerplate.h>
#include <dll.h>
#include <chrono>
#include <array/DataTypeUtils.h>
#include <helpers/logger.h>
#include <stdexcept>

#ifdef __CUDACC__
#include <cuda.h>
#include <cuda_runtime.h>
#endif

namespace nd4j {
    namespace graph {
#ifdef __CUDACC__
        class ND4J_EXPORT CudaManagedRandomGenerator {
        private:

        protected:
            void *devHolder;

        public:
            void *operator new(size_t len) {
                void *ptr;
                auto res = cudaHostAlloc(&ptr, len, cudaHostAllocDefault);
                if (res != 0)
                    throw std::runtime_error("CudaManagedRandomGenerator: failed to allocate memory");

                return ptr;
             }

            void operator delete(void *ptr) {
                cudaFreeHost(ptr);
            }
        };

        class ND4J_EXPORT RandomGenerator : public CudaManagedRandomGenerator {
#else
        class ND4J_EXPORT RandomGenerator {
#endif
        private:
#ifndef __CUDACC__
            void *placeHolder;
#endif
            // GRAPH-LEVEL STATE
            u64 _rootState;

            // NODE-LEVEL STATE
            u64 _nodeState;

            /**
             * Utility method, returns number of milliseconds since 1970
             * Leave this static if possible to avoid problems in constructor
             */
            static FORCEINLINE Nd4jLong currentMilliseconds();


            FORCEINLINE _CUDA_HD uint32_t xoroshiro32(Nd4jLong index);
            FORCEINLINE _CUDA_HD uint64_t xoroshiro64(Nd4jLong index);

            /**
             * This method returns integer value between 0 and MAX_UINT
             */
            //uint32_t relativeUInt32(Nd4jLong index);

        public:
            FORCEINLINE RandomGenerator(Nd4jLong rootSeed = 0, Nd4jLong nodeSeed = 0);

            /**
             * This method allows to change graph-level state in runtime.
             * PLEASE NOTE: this method will change state of node as well.
             */
            FORCEINLINE _CUDA_H void setStates(Nd4jLong rootSeed, Nd4jLong nodeState = 0);

            
            /**
             * This method returns T value between from and to
             */
            template <typename T>
            FORCEINLINE _CUDA_HD T relativeT(Nd4jLong index, T from, T to);

            /**
             * This method returns T value between 0 and MAX_T
             */
            template <typename T>
            FORCEINLINE _CUDA_HD T relativeT(Nd4jLong index);

            /**
             * These two methods are made for JVM
             * @param index
             * @return
             */
            FORCEINLINE _CUDA_HD int relativeInt(Nd4jLong index);
            FORCEINLINE _CUDA_HD Nd4jLong relativeLong(Nd4jLong index);

            FORCEINLINE _CUDA_HD void rewindH(Nd4jLong steps);

            /**
             * These methods set up only node states, with non-changed root ones
             */
            FORCEINLINE _CUDA_H void setSeed(int seed) {
                _nodeState._ulong = static_cast<uint64_t>(seed);
            }

            FORCEINLINE _CUDA_H void setSeed(uint64_t seed) {
                _nodeState._ulong = seed;
            }

            FORCEINLINE _CUDA_HD Nd4jLong rootState() {
                return _rootState._long;
            }

            FORCEINLINE _CUDA_HD Nd4jLong nodeState() {
                return _nodeState._long;
            }
        };


        FORCEINLINE RandomGenerator::RandomGenerator(Nd4jLong rootSeed, Nd4jLong nodeSeed) {
            // this seed is used graph-level state
            if (rootSeed == 0)
                rootSeed = currentMilliseconds();

            // graph-level state is just first seed
            _rootState._long = rootSeed;

            // used to build second, node state
            _nodeState._long = (nodeSeed != 0 ? nodeSeed: 1298567341LL);
        }

        FORCEINLINE void RandomGenerator::setStates(Nd4jLong rootSeed, Nd4jLong nodeSeed) {
            // this seed is used graph-level state
            if (rootSeed == 0)
                rootSeed = currentMilliseconds();

            // graph-level state is just first seed
            _rootState._long = rootSeed;

            // used to build second, node state
            _nodeState._long = (nodeSeed != 0 ? nodeSeed: 1298567341LL);
        }

        FORCEINLINE Nd4jLong RandomGenerator::currentMilliseconds() {
            auto s = std::chrono::system_clock::now().time_since_epoch();
            auto v = std::chrono::duration_cast<std::chrono::milliseconds>(s).count();
            return v;
        }

        template <>
        _CUDA_HD FORCEINLINE uint64_t RandomGenerator::relativeT<uint64_t>(Nd4jLong index) {
            return this->xoroshiro64(index);
        }

        template <>
        _CUDA_HD FORCEINLINE uint32_t RandomGenerator::relativeT<uint32_t>(Nd4jLong index) {            
            return this->xoroshiro32(index);
        }

        template <>
        _CUDA_HD FORCEINLINE int RandomGenerator::relativeT<int>(Nd4jLong index) {
            auto x = this->relativeT<uint32_t>(index);
            auto r = static_cast<int>(x % DataTypeUtils::max<int>());
            return r;
        }

        template <>
        _CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeT<Nd4jLong>(Nd4jLong index) {
            auto x = this->relativeT<uint64_t>(index);
            auto r = static_cast<Nd4jLong>(x % DataTypeUtils::max<Nd4jLong>());
            return r;
        }

        template <typename T>
        _CUDA_HD FORCEINLINE T RandomGenerator::relativeT(Nd4jLong index, T from, T to) {            
            auto t = this->relativeT<T>(index);
            auto z = from + T(t * (to - from));
            return z;
        }

        template <>
        _CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeT(Nd4jLong index, Nd4jLong from, Nd4jLong to) {
            auto t = this->relativeT<double>(index);
            auto z = from + Nd4jLong(t * (to - from));
            return z;
        }

        template <>
        _CUDA_HD FORCEINLINE int RandomGenerator::relativeT(Nd4jLong index, int from, int to) {
            auto t = this->relativeT<float>(index);
            auto z = from + float(t * (to - from));
            return z;
        }

        template <typename T>
        _CUDA_HD FORCEINLINE T RandomGenerator::relativeT(Nd4jLong index) {
            // This is default implementation for floating point types
#ifdef __DOUBLE_RNG__            
            auto i = static_cast<double>(this->relativeT<uint64_t>(index));
            auto r = i / static_cast<double>(DataTypeUtils::max<uint64_t>());
            return static_cast<T>(r);
#else            
            auto i = static_cast<float>(this->relativeT<uint32_t>(index));            
            auto r = i / static_cast<float>(DataTypeUtils::max<uint32_t>());
            return static_cast<T>(r);
#endif
        }


        _CUDA_HD FORCEINLINE int RandomGenerator::relativeInt(Nd4jLong index) {
            return relativeT<int>(index);
        }

        _CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeLong(Nd4jLong index) {
            return relativeT<Nd4jLong>(index);
        }

        //////
        static FORCEINLINE _CUDA_HD uint32_t rotl(const uint32_t x, int k) {
            return (x << k) | (x >> (32 - k));
        }

        static FORCEINLINE _CUDA_HD  uint64_t rotl(const uint64_t x, int k) {
            return (x << k) | (x >> (64 - k));
        }

        _CUDA_HD FORCEINLINE uint32_t RandomGenerator::xoroshiro32(Nd4jLong index) {

            auto s0 = _rootState._ulong;            
            auto s1 = _nodeState._ulong;

            // xor by idx
            s0 |= ((index + 2) * (s1 + 24243287));            
            s1 ^= ((index + 2) * (s0 + 723829));
            
            unsigned long val = 0;
            val = s1 ^ s0;
            int* pHalf = reinterpret_cast<int*>(&val);

            return rotl(*pHalf * 0x9E3779BB, 5) * 5;
        }

        _CUDA_HD FORCEINLINE uint64_t RandomGenerator::xoroshiro64(Nd4jLong index) {
            auto s0 = _rootState._ulong;
            auto s1 = _nodeState._ulong;

            // xor by idx
            s0 |= ((index + 2) * (s1 + 24243287));
            s1 ^= ((index + 2) * (s0 + 723829));

            // since we're not modifying state - do rotl step right here
            s1 ^= s0;
            s0 = rotl(s0, 55) ^ s1 ^ (s1 << 14);
            s1 = rotl(s1, 36);

            return s0 + s1;
        }

        _CUDA_HD FORCEINLINE void RandomGenerator::rewindH(Nd4jLong steps) {
            auto s0 = _nodeState._du32._v0;
            auto s1 = _nodeState._du32._v1;

            s1 ^= s0;
            _nodeState._du32._v0 = rotl(s0, 26) ^ s1 ^ (s1 << 9); // a, b
            _nodeState._du32._v1 = rotl(s1, 13); // c

            _nodeState._long ^= (steps ^ 0xdeadbeef);
        }
    }
}

#endif
Eclipse Migration Initial Commit 2019-06-06 14:21:15 +02:00			`/*******************************************************************************`
			`* Copyright (c) 2015-2018 Skymind, Inc.`
			`*`
			`* This program and the accompanying materials are made available under the`
			`* terms of the Apache License, Version 2.0 which is available at`
			`* https://www.apache.org/licenses/LICENSE-2.0.`
			`*`
			`* 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.`
			`*`
			`* SPDX-License-Identifier: Apache-2.0`
			`******************************************************************************/`

			`//`
			`// @author raver119@protonmail.com`
			`//`

			`#ifndef LIBND4J_GRAPH_RNG_H`
			`#define LIBND4J_GRAPH_RNG_H`

			`#include <types/u64.h>`
			`#include <pointercast.h>`
			`#include <op_boilerplate.h>`
			`#include <dll.h>`
			`#include <chrono>`
			`#include <array/DataTypeUtils.h>`
			`#include <helpers/logger.h>`
alloc check for RNG (#179) * missing alloc validation in RandomGenerator for CUDA Signed-off-by: raver119 <raver119@gmail.com> * set error message if rng alloc failed Signed-off-by: raver119 <raver119@gmail.com> * check for error code during RNG creation in java Signed-off-by: raver119 <raver119@gmail.com> 2020-01-23 07:51:02 +01:00			`#include <stdexcept>`
Eclipse Migration Initial Commit 2019-06-06 14:21:15 +02:00
			`#ifdef __CUDACC__`
			`#include <cuda.h>`
			`#include <cuda_runtime.h>`
			`#endif`

			`namespace nd4j {`
			`namespace graph {`
			`#ifdef __CUDACC__`
			`class ND4J_EXPORT CudaManagedRandomGenerator {`
			`private:`

			`protected:`
			`void *devHolder;`

			`public:`
			`void *operator new(size_t len) {`
			`void *ptr;`
alloc check for RNG (#179) * missing alloc validation in RandomGenerator for CUDA Signed-off-by: raver119 <raver119@gmail.com> * set error message if rng alloc failed Signed-off-by: raver119 <raver119@gmail.com> * check for error code during RNG creation in java Signed-off-by: raver119 <raver119@gmail.com> 2020-01-23 07:51:02 +01:00			`auto res = cudaHostAlloc(&ptr, len, cudaHostAllocDefault);`
			`if (res != 0)`
			`throw std::runtime_error("CudaManagedRandomGenerator: failed to allocate memory");`

Eclipse Migration Initial Commit 2019-06-06 14:21:15 +02:00			`return ptr;`
			`}`

			`void operator delete(void *ptr) {`
			`cudaFreeHost(ptr);`
			`}`
			`};`

			`class ND4J_EXPORT RandomGenerator : public CudaManagedRandomGenerator {`
			`#else`
			`class ND4J_EXPORT RandomGenerator {`
			`#endif`
			`private:`
			`#ifndef __CUDACC__`
			`void *placeHolder;`
			`#endif`
			`// GRAPH-LEVEL STATE`
			`u64 _rootState;`

			`// NODE-LEVEL STATE`
			`u64 _nodeState;`

			`/**`
			`* Utility method, returns number of milliseconds since 1970`
			`* Leave this static if possible to avoid problems in constructor`
			`*/`
			`static FORCEINLINE Nd4jLong currentMilliseconds();`


			`FORCEINLINE _CUDA_HD uint32_t xoroshiro32(Nd4jLong index);`
			`FORCEINLINE _CUDA_HD uint64_t xoroshiro64(Nd4jLong index);`

			`/**`
			`* This method returns integer value between 0 and MAX_UINT`
			`*/`
			`//uint32_t relativeUInt32(Nd4jLong index);`

			`public:`
			`FORCEINLINE RandomGenerator(Nd4jLong rootSeed = 0, Nd4jLong nodeSeed = 0);`

			`/**`
			`* This method allows to change graph-level state in runtime.`
			`* PLEASE NOTE: this method will change state of node as well.`
			`*/`
			`FORCEINLINE _CUDA_H void setStates(Nd4jLong rootSeed, Nd4jLong nodeState = 0);`



			`/**`
			`* This method returns T value between from and to`
			`*/`
			`template <typename T>`
			`FORCEINLINE _CUDA_HD T relativeT(Nd4jLong index, T from, T to);`

			`/**`
			`* This method returns T value between 0 and MAX_T`
			`*/`
			`template <typename T>`
			`FORCEINLINE _CUDA_HD T relativeT(Nd4jLong index);`

			`/**`
			`* These two methods are made for JVM`
			`* @param index`
			`* @return`
			`*/`
			`FORCEINLINE _CUDA_HD int relativeInt(Nd4jLong index);`
			`FORCEINLINE _CUDA_HD Nd4jLong relativeLong(Nd4jLong index);`

			`FORCEINLINE _CUDA_HD void rewindH(Nd4jLong steps);`

			`/**`
			`* These methods set up only node states, with non-changed root ones`
			`*/`
			`FORCEINLINE _CUDA_H void setSeed(int seed) {`
			`_nodeState._ulong = static_cast<uint64_t>(seed);`
			`}`

			`FORCEINLINE _CUDA_H void setSeed(uint64_t seed) {`
			`_nodeState._ulong = seed;`
			`}`

			`FORCEINLINE _CUDA_HD Nd4jLong rootState() {`
			`return _rootState._long;`
			`}`

			`FORCEINLINE _CUDA_HD Nd4jLong nodeState() {`
			`return _nodeState._long;`
			`}`
			`};`


			`FORCEINLINE RandomGenerator::RandomGenerator(Nd4jLong rootSeed, Nd4jLong nodeSeed) {`
			`// this seed is used graph-level state`
			`if (rootSeed == 0)`
			`rootSeed = currentMilliseconds();`

			`// graph-level state is just first seed`
			`_rootState._long = rootSeed;`

			`// used to build second, node state`
			`_nodeState._long = (nodeSeed != 0 ? nodeSeed: 1298567341LL);`
			`}`

			`FORCEINLINE void RandomGenerator::setStates(Nd4jLong rootSeed, Nd4jLong nodeSeed) {`
			`// this seed is used graph-level state`
			`if (rootSeed == 0)`
			`rootSeed = currentMilliseconds();`

			`// graph-level state is just first seed`
			`_rootState._long = rootSeed;`

			`// used to build second, node state`
			`_nodeState._long = (nodeSeed != 0 ? nodeSeed: 1298567341LL);`
			`}`

			`FORCEINLINE Nd4jLong RandomGenerator::currentMilliseconds() {`
			`auto s = std::chrono::system_clock::now().time_since_epoch();`
			`auto v = std::chrono::duration_cast<std::chrono::milliseconds>(s).count();`
			`return v;`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE uint64_t RandomGenerator::relativeT<uint64_t>(Nd4jLong index) {`
			`return this->xoroshiro64(index);`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE uint32_t RandomGenerator::relativeT<uint32_t>(Nd4jLong index) {`
			`return this->xoroshiro32(index);`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE int RandomGenerator::relativeT<int>(Nd4jLong index) {`
			`auto x = this->relativeT<uint32_t>(index);`
			`auto r = static_cast<int>(x % DataTypeUtils::max<int>());`
			`return r;`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeT<Nd4jLong>(Nd4jLong index) {`
			`auto x = this->relativeT<uint64_t>(index);`
			`auto r = static_cast<Nd4jLong>(x % DataTypeUtils::max<Nd4jLong>());`
			`return r;`
			`}`

			`template <typename T>`
			`_CUDA_HD FORCEINLINE T RandomGenerator::relativeT(Nd4jLong index, T from, T to) {`
Shugeo random uniform int (#30) * Corrected randomuniform declaration. * Refactored uniform distribution for both cuda and cpu platforms. * Refactored uniform distribution and tests. * Fixed type usage with indices. * Refactored uniform distribution implementation and tests to full conform with TF implementation. * Refactored gamma function to use type util method. * Copyright changes and fixes with ConstantHelper. * Added error checking on allocate cuda device memory and operations. 2019-11-06 11:49:27 +01:00			`auto t = this->relativeT<T>(index);`
			`auto z = from + T(t * (to - from));`
			`return z;`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeT(Nd4jLong index, Nd4jLong from, Nd4jLong to) {`
			`auto t = this->relativeT<double>(index);`
			`auto z = from + Nd4jLong(t * (to - from));`
			`return z;`
			`}`

			`template <>`
			`_CUDA_HD FORCEINLINE int RandomGenerator::relativeT(Nd4jLong index, int from, int to) {`
			`auto t = this->relativeT<float>(index);`
			`auto z = from + float(t * (to - from));`
Eclipse Migration Initial Commit 2019-06-06 14:21:15 +02:00			`return z;`
			`}`

			`template <typename T>`
			`_CUDA_HD FORCEINLINE T RandomGenerator::relativeT(Nd4jLong index) {`
			`// This is default implementation for floating point types`
			`#ifdef __DOUBLE_RNG__`
			`auto i = static_cast<double>(this->relativeT<uint64_t>(index));`
			`auto r = i / static_cast<double>(DataTypeUtils::max<uint64_t>());`
			`return static_cast<T>(r);`
			`#else`
			`auto i = static_cast<float>(this->relativeT<uint32_t>(index));`
			`auto r = i / static_cast<float>(DataTypeUtils::max<uint32_t>());`
			`return static_cast<T>(r);`
			`#endif`
			`}`


			`_CUDA_HD FORCEINLINE int RandomGenerator::relativeInt(Nd4jLong index) {`
			`return relativeT<int>(index);`
			`}`

			`_CUDA_HD FORCEINLINE Nd4jLong RandomGenerator::relativeLong(Nd4jLong index) {`
			`return relativeT<Nd4jLong>(index);`
			`}`

			`//////`
			`static FORCEINLINE _CUDA_HD uint32_t rotl(const uint32_t x, int k) {`
			`return (x << k) \| (x >> (32 - k));`
			`}`

			`static FORCEINLINE _CUDA_HD uint64_t rotl(const uint64_t x, int k) {`
			`return (x << k) \| (x >> (64 - k));`
			`}`

			`_CUDA_HD FORCEINLINE uint32_t RandomGenerator::xoroshiro32(Nd4jLong index) {`

			`auto s0 = _rootState._ulong;`
			`auto s1 = _nodeState._ulong;`

			`// xor by idx`
			`s0 \|= ((index + 2) * (s1 + 24243287));`
			`s1 ^= ((index + 2) * (s0 + 723829));`

			`unsigned long val = 0;`
			`val = s1 ^ s0;`
			`int* pHalf = reinterpret_cast<int*>(&val);`

			`return rotl(pHalf 0x9E3779BB, 5) * 5;`
			`}`

			`_CUDA_HD FORCEINLINE uint64_t RandomGenerator::xoroshiro64(Nd4jLong index) {`
			`auto s0 = _rootState._ulong;`
			`auto s1 = _nodeState._ulong;`

			`// xor by idx`
			`s0 \|= ((index + 2) * (s1 + 24243287));`
			`s1 ^= ((index + 2) * (s0 + 723829));`

			`// since we're not modifying state - do rotl step right here`
			`s1 ^= s0;`
			`s0 = rotl(s0, 55) ^ s1 ^ (s1 << 14);`
			`s1 = rotl(s1, 36);`

			`return s0 + s1;`
			`}`

			`_CUDA_HD FORCEINLINE void RandomGenerator::rewindH(Nd4jLong steps) {`
			`auto s0 = _nodeState._du32._v0;`
			`auto s1 = _nodeState._du32._v1;`

			`s1 ^= s0;`
			`_nodeState._du32._v0 = rotl(s0, 26) ^ s1 ^ (s1 << 9); // a, b`
			`_nodeState._du32._v1 = rotl(s1, 13); // c`

			`_nodeState._long ^= (steps ^ 0xdeadbeef);`
			`}`
			`}`
			`}`

			`#endif`