/*
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The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL THE
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*/

/* HIT_START
 * BUILD: %t %s ../../test_common.cpp
 * TEST: %t
 * HIT_END
 */

// Test pointer tracking logic: allocate memory and retrieve stats with hipPointerGetAttributes

#include "hip/hip_runtime.h"
#include "test_common.h"
#include <vector>

size_t Nbytes = 0;

//=================================================================================================
// Utility Functions:
//=================================================================================================

bool operator==(const hipPointerAttribute_t& lhs, const hipPointerAttribute_t& rhs) {
    return ((lhs.hostPointer == rhs.hostPointer) && (lhs.devicePointer == rhs.devicePointer) &&
            (lhs.memoryType == rhs.memoryType) && (lhs.device == rhs.device) &&
            (lhs.allocationFlags == rhs.allocationFlags));
};


bool operator!=(const hipPointerAttribute_t& lhs, const hipPointerAttribute_t& rhs) {
    return !(lhs == rhs);
}


const char* memoryTypeToString(hipMemoryType memoryType) {
    switch (memoryType) {
        case hipMemoryTypeHost:
            return "[Host]";
        case hipMemoryTypeDevice:
            return "[Device]";
        default:
            return "[Unknown]";
    };
}


void resetAttribs(hipPointerAttribute_t* attribs) {
    attribs->hostPointer = (void*)(-1);
    attribs->devicePointer = (void*)(-1);
    attribs->memoryType = hipMemoryTypeHost;
    attribs->device = -2;
    attribs->isManaged = -1;
    attribs->allocationFlags = 0xffff;
};


void printAttribs(const hipPointerAttribute_t* attribs) {
    printf(
        "hostPointer:%p devicePointer:%p  memoryType:%s deviceId:%d isManaged:%d "
        "allocationFlags:%u\n",
        attribs->hostPointer, attribs->devicePointer, memoryTypeToString(attribs->memoryType),
        attribs->device, attribs->isManaged, attribs->allocationFlags);
};


inline int zrand(int max) { return rand() % max; }


//=================================================================================================
// Functions to run tests
//=================================================================================================
//--
// Run through a couple simple cases to test lookups and host pointer arithmetic:
void testSimple() {
    printf("\n");
    printf("===========================================================================\n");
    printf("Simple Tests\n");
    printf("===========================================================================\n");

    char* A_d;
    char* A_Pinned_h;
    char* A_OSAlloc_h;
    hipError_t e;

    HIPCHECK(hipMalloc(&A_d, Nbytes));
    HIPCHECK(hipHostMalloc((void**)&A_Pinned_h, Nbytes, hipHostMallocDefault));
    A_OSAlloc_h = (char*)malloc(Nbytes);

    size_t free, total;
    HIPCHECK(hipMemGetInfo(&free, &total));
    printf("hipMemGetInfo: free=%zu (%4.2f) Nbytes=%lu total=%zu (%4.2f)\n", free,
           (float)(free / 1024.0 / 1024.0), Nbytes, total, (float)(total / 1024.0 / 1024.0));
    HIPASSERT(free + Nbytes <= total);


    hipPointerAttribute_t attribs;
    hipPointerAttribute_t attribs2;

    // Device memory
    printf("\nDevice memory (hipMalloc)\n");
    HIPCHECK(hipPointerGetAttributes(&attribs, A_d));

    // Check pointer arithmetic cases:
    resetAttribs(&attribs2);
    HIPCHECK(hipPointerGetAttributes(&attribs2, A_d + 100));
    HIPASSERT((char*)attribs.devicePointer + 100 == (char*)attribs2.devicePointer);

    // Corner case at end of array:
    resetAttribs(&attribs2);
    HIPCHECK(hipPointerGetAttributes(&attribs2, A_d + Nbytes - 1));
    HIPASSERT((char*)attribs.devicePointer + Nbytes - 1 == (char*)attribs2.devicePointer);

    // Pointer just beyond array - must be invalid or at least a different pointer
    resetAttribs(&attribs2);
    e = hipPointerGetAttributes(&attribs2, A_d + Nbytes + 1);
    if (e != hipErrorInvalidValue) {
        // We might have strayed into another pointer area.
        HIPASSERT((char*)attribs.devicePointer != (char*)attribs2.devicePointer);
    }


    resetAttribs(&attribs2);
    e = hipPointerGetAttributes(&attribs2, A_d + Nbytes);
    if (e != hipErrorInvalidValue) {
        HIPASSERT(attribs.devicePointer != attribs2.devicePointer);
    }

    hipFree(A_d);
    e = hipPointerGetAttributes(&attribs, A_d);
    HIPASSERT(e == hipErrorInvalidValue);  // Just freed the pointer, this should return an error.


    // Device-visible host memory
    printf("\nDevice-visible host memory (hipHostMalloc)\n");
    HIPCHECK(hipPointerGetAttributes(&attribs, A_Pinned_h));

    resetAttribs(&attribs2);
    HIPCHECK(hipPointerGetAttributes(&attribs2, A_Pinned_h + Nbytes / 2));
    HIPASSERT((char*)attribs.hostPointer + Nbytes / 2 == (char*)attribs2.hostPointer);


    hipHostFree(A_Pinned_h);
    e = hipPointerGetAttributes(&attribs, A_Pinned_h);
    HIPASSERT(e == hipErrorInvalidValue);  // Just freed the pointer, this should return an error.

    // OS memory
    printf("\nOS-allocated memory (malloc)\n");
    e = hipPointerGetAttributes(&attribs, A_OSAlloc_h);
    HIPASSERT(e == hipErrorInvalidValue);  // Just freed the pointer, this should return an error.
}

// Store the hipPointer attrib and some extra info so can later compare the looked-up info against
// the reference expectation
struct SuperPointerAttribute {
    void* _pointer;
    size_t _sizeBytes;
    hipPointerAttribute_t _attrib;
};


//---
// Support function to check result against a reference:
void checkPointer(SuperPointerAttribute& ref, int major, int minor, void* pointer) {
    hipPointerAttribute_t attribs;
    resetAttribs(&attribs);

    hipError_t e = hipPointerGetAttributes(&attribs, pointer);
    if ((e != hipSuccess) || (attribs != ref._attrib)) {
        HIPCHECK(e);
        HIPASSERT(attribs != ref._attrib);
    } else {
        if (p_verbose & 0x1) {
            printf("#%4d.%d GOOD:%p getattr ::  ", major, minor, pointer);
            printAttribs(&attribs);
        }
    }
}


//---
// Test that allocates memory across all devices withing the specified size range
// (minSize...maxSize). Then does lookups to make sure the info reported by the tracker matches
// expecations Then deallocates it all.
//
// Multiple threads can call this function and in fact we do this in the testMultiThreaded_1 test.
void clusterAllocs(int numAllocs, size_t minSize, size_t maxSize) {
    printf("  clusterAllocs numAllocs=%d size=%lu..%lu\n", numAllocs, minSize, maxSize);
    std::vector<SuperPointerAttribute> reference(numAllocs);

    HIPASSERT(minSize > 0);
    HIPASSERT(maxSize >= minSize);

    int numDevices;
    HIPCHECK(hipGetDeviceCount(&numDevices));

    //---
    // Populate with device and host allocations.
    size_t totalDeviceAllocated[numDevices];
    for (int i = 0; i < numDevices; i++) {
        totalDeviceAllocated[i] = 0;
    }
    for (int i = 0; i < numAllocs; i++) {
        bool isDevice = rand() & 0x1;
        reference[i]._sizeBytes = zrand(maxSize - minSize) + minSize;

        reference[i]._attrib.device = zrand(numDevices);
        HIPCHECK(hipSetDevice(reference[i]._attrib.device));
        reference[i]._attrib.isManaged = 0;

        void* ptr;
        if (isDevice) {
            totalDeviceAllocated[reference[i]._attrib.device] += reference[i]._sizeBytes;
            HIPCHECK(hipMalloc((void**)&ptr, reference[i]._sizeBytes));
            reference[i]._attrib.memoryType = hipMemoryTypeDevice;
            reference[i]._attrib.devicePointer = ptr;
            reference[i]._attrib.hostPointer = NULL;
            reference[i]._attrib.allocationFlags = 0;  // TODO-randomize these.
        } else {
            HIPCHECK(hipHostMalloc((void**)&ptr, reference[i]._sizeBytes, hipHostMallocDefault));
            reference[i]._attrib.memoryType = hipMemoryTypeHost;
            reference[i]._attrib.devicePointer = ptr;
            reference[i]._attrib.hostPointer = ptr;
            reference[i]._attrib.allocationFlags = 0;  // TODO-randomize these.
        }
        reference[i]._pointer = ptr;
    }

    for (int i = 0; i < numDevices; i++) {
        size_t free, total;
        HIPCHECK(hipSetDevice(i));
        HIPCHECK(hipMemGetInfo(&free, &total));
        printf(
            "  device#%d: hipMemGetInfo: free=%zu (%4.2fMB) totalDevice=%lu (%4.2fMB) total=%zu "
            "(%4.2fMB)\n",
            i, free, (float)(free / 1024.0 / 1024.0), totalDeviceAllocated[i],
            (float)(totalDeviceAllocated[i]) / 1024.0 / 1024.0, total,
            (float)(total / 1024.0 / 1024.0));
        HIPASSERT(free + totalDeviceAllocated[i] <= total);
    }

    // Now look up each pointer we inserted and verify we can find it:
    for (int i = 0; i < numAllocs; i++) {
        SuperPointerAttribute& ref = reference[i];
        checkPointer(ref, i, 0, ref._pointer);
        checkPointer(ref, i, 1, (char*)ref._pointer + ref._sizeBytes / 2);
        if (ref._sizeBytes > 1) {
            checkPointer(ref, i, 2, (char*)ref._pointer + ref._sizeBytes - 1);
        }

        if (ref._attrib.memoryType == hipMemoryTypeDevice) {
            hipFree(ref._pointer);
        } else {
            hipHostFree(ref._pointer);
        }
    }
}

//---
// Multi-threaded test with many simul allocs.
// IN : serialize will force the test to run in serial fashion.
void testMultiThreaded_1(bool serialize = false) {
    printf("\n===========================================================================\n");
    printf("MultiThreaded_1\n");
    if (serialize) printf("[SERIALIZE]\n");
    printf("===========================================================================\n");
    std::thread t1(clusterAllocs, 1000, 101, 1000);
    if (serialize) t1.join();

    std::thread t2(clusterAllocs, 1000, 11, 100);
    if (serialize) t2.join();

    std::thread t3(clusterAllocs, 1000, 5, 10);
    if (serialize) t3.join();

    std::thread t4(clusterAllocs, 1000, 1, 4);
    if (serialize) t4.join();

    if (!serialize) {
        t1.join();
        t2.join();
        t3.join();
        t4.join();
    }

}

int main(int argc, char* argv[]) {
    N = 1000000;
    HipTest::parseStandardArguments(argc, argv, true);

    Nbytes = N * sizeof(char);

    printf("N=%zu (%6.2f MB) device=%d\n", N, Nbytes / (1024.0 * 1024.0), p_gpuDevice);

    if (p_tests & 0x01) {
        printf("info: set device to %d\n", p_gpuDevice);
        HIPCHECK(hipSetDevice(p_gpuDevice));
        testSimple();
    }

    if (p_tests & 0x02) {
        srand(0x100);
        printf("\n===========================================================================\n");
        clusterAllocs(100, 1024 * 1, 1024 * 1024);
    }

    if (p_tests & 0x04) {
        srand(0x200);
        printf("\n===========================================================================\n");
        clusterAllocs(1000, 1, 10);  //  Many tiny allocations;
    }

    if (p_tests & 0x08) {
        srand(0x300);
        testMultiThreaded_1(true);
        testMultiThreaded_1(false);
    }

    printf("\n");
    passed();
}