//

// File:       fft_setup.cpp

//

// Version:    <1.0>

//

// Disclaimer: IMPORTANT:  This Apple software is supplied to you by Apple Inc. ("Apple")

//             in consideration of your agreement to the following terms, and your use,

//             installation, modification or redistribution of this Apple software

//             constitutes acceptance of these terms.  If you do not agree with these

//             terms, please do not use, install, modify or redistribute this Apple

//             software.

//

//             In consideration of your agreement to abide by the following terms, and

//             subject to these terms, Apple grants you a personal, non - exclusive

//             license, under Apple's copyrights in this original Apple software ( the

//             "Apple Software" ), to use, reproduce, modify and redistribute the Apple

//             Software, with or without modifications, in source and / or binary forms;

//             provided that if you redistribute the Apple Software in its entirety and

//             without modifications, you must retain this notice and the following text

//             and disclaimers in all such redistributions of the Apple Software. Neither

//             the name, trademarks, service marks or logos of Apple Inc. may be used to

//             endorse or promote products derived from the Apple Software without specific

//             prior written permission from Apple.  Except as expressly stated in this

//             notice, no other rights or licenses, express or implied, are granted by

//             Apple herein, including but not limited to any patent rights that may be

//             infringed by your derivative works or by other works in which the Apple

//             Software may be incorporated.

//

//             The Apple Software is provided by Apple on an "AS IS" basis.  APPLE MAKES NO

//             WARRANTIES, EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION THE IMPLIED

//             WARRANTIES OF NON - INFRINGEMENT, MERCHANTABILITY AND FITNESS FOR A

//             PARTICULAR PURPOSE, REGARDING THE APPLE SOFTWARE OR ITS USE AND OPERATION

//             ALONE OR IN COMBINATION WITH YOUR PRODUCTS.

//

//             IN NO EVENT SHALL APPLE BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL OR

//             CONSEQUENTIAL DAMAGES ( INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF

//             SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS

//             INTERRUPTION ) ARISING IN ANY WAY OUT OF THE USE, REPRODUCTION, MODIFICATION

//             AND / OR DISTRIBUTION OF THE APPLE SOFTWARE, HOWEVER CAUSED AND WHETHER

//             UNDER THEORY OF CONTRACT, TORT ( INCLUDING NEGLIGENCE ), STRICT LIABILITY OR

//             OTHERWISE, EVEN IF APPLE HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

//

// Copyright ( C ) 2008 Apple Inc. All Rights Reserved.

//

////////////////////////////////////////////////////////////////////////////////////////////////////

#include "fft_internal.h"

#include "fft_base_kernels.h"

#include <stdlib.h>

#include <string.h>

#include <sys/types.h>

#include <sys/stat.h>

#include <iostream>

#include <string>

#include <sstream>

using namespace std;

extern void getKernelWorkDimensions(cl_fft_plan *plan, cl_fft_kernel_info *kernelInfo, cl_int *batchSize, size_t *gWorkItems, size_t *lWorkItems);

static void 

getBlockConfigAndKernelString(cl_fft_plan *plan)

{

    plan->temp_buffer_needed = 0;

    *plan->kernel_string += baseKernels;

    if(plan->format == clFFT_SplitComplexFormat)

        *plan->kernel_string += twistKernelPlannar;

    else

        *plan->kernel_string += twistKernelInterleaved;

    switch(plan->dim) 

    {

        case clFFT_1D:

            FFT1D(plan, cl_fft_kernel_x);

            break;

        case clFFT_2D:

            FFT1D(plan, cl_fft_kernel_x); 

            FFT1D(plan, cl_fft_kernel_y);  

            break;

        case clFFT_3D:

            FFT1D(plan, cl_fft_kernel_x); 

            FFT1D(plan, cl_fft_kernel_y); 

            FFT1D(plan, cl_fft_kernel_z); 

            break;

        default:

            return;

    }

    plan->temp_buffer_needed = 0;

    cl_fft_kernel_info *kInfo = plan->kernel_info;

    while(kInfo)

    {

        plan->temp_buffer_needed |= !kInfo->in_place_possible;

        kInfo = kInfo->next;

    }

}

static void

deleteKernelInfo(cl_fft_kernel_info *kInfo)

{

    if(kInfo)

    {

        if(kInfo->kernel_name)

            free(kInfo->kernel_name);

        if(kInfo->kernel)

            clReleaseKernel(kInfo->kernel);

        free(kInfo);

    }   

}

static void

destroy_plan(cl_fft_plan *Plan)

{

    cl_fft_kernel_info *kernel_info = Plan->kernel_info;

    while(kernel_info)

    {

        cl_fft_kernel_info *tmp = kernel_info->next;

        deleteKernelInfo(kernel_info);

        kernel_info = tmp;

    }

    Plan->kernel_info = NULL;

    if(Plan->kernel_string)

    {

        delete Plan->kernel_string;

        Plan->kernel_string = NULL;

    }           

    if(Plan->twist_kernel)

    {

        clReleaseKernel(Plan->twist_kernel);

        Plan->twist_kernel = NULL;

    }

    if(Plan->program)

    {

        clReleaseProgram(Plan->program);

        Plan->program = NULL;

    }

    if(Plan->tempmemobj) 

    {

        clReleaseMemObject(Plan->tempmemobj);

        Plan->tempmemobj = NULL;

    }

    if(Plan->tempmemobj_real)

    {

        clReleaseMemObject(Plan->tempmemobj_real);

        Plan->tempmemobj_real = NULL;

    }

    if(Plan->tempmemobj_imag)

    {

        clReleaseMemObject(Plan->tempmemobj_imag);

        Plan->tempmemobj_imag = NULL;

    }

}

static int

createKernelList(cl_fft_plan *plan) 

{

    cl_program program = plan->program;

    cl_fft_kernel_info *kernel_info = plan->kernel_info;

    cl_int err;

    while(kernel_info)

    {

        kernel_info->kernel = clCreateKernel(program, kernel_info->kernel_name, &err);

        if(!kernel_info->kernel || err != CL_SUCCESS)

            return err;

        kernel_info = kernel_info->next;        

    }

    if(plan->format == clFFT_SplitComplexFormat)

        plan->twist_kernel = clCreateKernel(program, "clFFT_1DTwistSplit", &err);

    else

        plan->twist_kernel = clCreateKernel(program, "clFFT_1DTwistInterleaved", &err);

    if(!plan->twist_kernel || err)

        return err;

    return CL_SUCCESS;

}

int getMaxKernelWorkGroupSize(cl_fft_plan *plan, unsigned int *max_wg_size, unsigned int num_devices, cl_device_id *devices)

{   

    int reg_needed = 0;

    *max_wg_size = INT_MAX;

    int err;

    size_t wg_size;

    unsigned int i;

    for(i = 0; i < num_devices; i++)

    {

        cl_fft_kernel_info *kInfo = plan->kernel_info;

        while(kInfo)

        {

            err = clGetKernelWorkGroupInfo(kInfo->kernel, devices[i], CL_KERNEL_WORK_GROUP_SIZE, sizeof(size_t), &wg_size, NULL);

            if(err != CL_SUCCESS)

                return -1;

            if(wg_size < kInfo->num_workitems_per_workgroup)

                reg_needed |= 1;

            if(*max_wg_size > wg_size)

                *max_wg_size = wg_size;

            kInfo = kInfo->next;

        }

    }

    return reg_needed;

}   

#define ERR_MACRO(err) { \

                         if( err != CL_SUCCESS) \

                         { \

                           if(error_code) \

                               *error_code = err; \

                           clFFT_DestroyPlan((clFFT_Plan) plan); \

                           return (clFFT_Plan) NULL; \

                         } \

                       }

clFFT_Plan

clFFT_CreatePlan(cl_context context, clFFT_Dim3 n, clFFT_Dimension dim, clFFT_DataFormat dataFormat, cl_int *error_code )

{

    int i;

    cl_int err;

    int isPow2 = 1;

    cl_fft_plan *plan = NULL;

    ostringstream kString;

    int num_devices;

    int gpu_found = 0;

    cl_device_id devices[16];

    size_t ret_size;

    cl_device_type device_type;

    if(!context)

        ERR_MACRO(CL_INVALID_VALUE);

    isPow2 |= n.x && !( (n.x - 1) & n.x );

    isPow2 |= n.y && !( (n.y - 1) & n.y );

    isPow2 |= n.z && !( (n.z - 1) & n.z );

    if(!isPow2)

        ERR_MACRO(CL_INVALID_VALUE);

    if( (dim == clFFT_1D && (n.y != 1 || n.z != 1)) || (dim == clFFT_2D && n.z != 1) )

        ERR_MACRO(CL_INVALID_VALUE);

    plan = (cl_fft_plan *) malloc(sizeof(cl_fft_plan));

    if(!plan)

        ERR_MACRO(CL_OUT_OF_RESOURCES);

    plan->context = context;

    clRetainContext(context);

    plan->n = n;

    plan->dim = dim;

    plan->format = dataFormat;

    plan->kernel_info = 0;

    plan->num_kernels = 0;

    plan->twist_kernel = 0;

    plan->program = 0;

    plan->temp_buffer_needed = 0;

    plan->last_batch_size = 0;

    plan->tempmemobj = 0;

    plan->tempmemobj_real = 0;

    plan->tempmemobj_imag = 0;

    plan->max_localmem_fft_size = 2048;

    plan->max_work_item_per_workgroup = 256;

    plan->max_radix = 16;

    plan->min_mem_coalesce_width = 16;

    plan->num_local_mem_banks = 16; 

patch_kernel_source:

    plan->kernel_string = new string("");

    if(!plan->kernel_string)

        ERR_MACRO(CL_OUT_OF_RESOURCES);

    getBlockConfigAndKernelString(plan);

    const char *source_str = plan->kernel_string->c_str();

    plan->program = clCreateProgramWithSource(context, 1, (const char**) &source_str, NULL, &err);

    ERR_MACRO(err);

    err = clGetContextInfo(context, CL_CONTEXT_DEVICES, sizeof(devices), devices, &ret_size);

    ERR_MACRO(err);

    num_devices = ret_size / sizeof(cl_device_id);

    for(i = 0; i < num_devices; i++)

    {

        err = clGetDeviceInfo(devices[i], CL_DEVICE_TYPE, sizeof(device_type), &device_type, NULL);

        ERR_MACRO(err);

        if(device_type == CL_DEVICE_TYPE_GPU)

        {   

            gpu_found = 1;

            err = clBuildProgram(plan->program, 1, &devices[i], "-cl-mad-enable", NULL, NULL);

            if (err != CL_SUCCESS)

            {

                char *build_log;                

                char devicename[200];

                size_t log_size;

                err = clGetProgramBuildInfo(plan->program, devices[i], CL_PROGRAM_BUILD_LOG, 0, NULL, &log_size);

                ERR_MACRO(err);

                build_log = (char *) malloc(log_size + 1);

                err = clGetProgramBuildInfo(plan->program, devices[i], CL_PROGRAM_BUILD_LOG, log_size, build_log, NULL);

                ERR_MACRO(err);

                err = clGetDeviceInfo(devices[i], CL_DEVICE_NAME, sizeof(devicename), devicename, NULL);

                ERR_MACRO(err);

                fprintf(stdout, "FFT program build log on device %s\n", devicename);

                fprintf(stdout, "%s\n", build_log);

                free(build_log);

                ERR_MACRO(err);

            }   

        }   

    }

    if(!gpu_found)

        ERR_MACRO(CL_INVALID_CONTEXT);

    err = createKernelList(plan); 

    ERR_MACRO(err);

    // we created program and kernels based on "some max work group size (default 256)" ... this work group size

    // may be larger than what kernel may execute with ... if thats the case we need to regenerate the kernel source 

    // setting this as limit i.e max group size and rebuild. 

    unsigned int max_kernel_wg_size; 

    int patching_req = getMaxKernelWorkGroupSize(plan, &max_kernel_wg_size, num_devices, devices);

    if(patching_req == -1)

    {

        ERR_MACRO(err);

    }

    if(patching_req)

    {

        destroy_plan(plan);

        plan->max_work_item_per_workgroup = max_kernel_wg_size;

        goto patch_kernel_source;

    }

    cl_fft_kernel_info *kInfo = plan->kernel_info;

    while(kInfo)

    {

        plan->num_kernels++;

        kInfo = kInfo->next;

    }

    if(error_code)

        *error_code = CL_SUCCESS;

    return (clFFT_Plan) plan;

}

void         

clFFT_DestroyPlan(clFFT_Plan plan)

{

    cl_fft_plan *Plan = (cl_fft_plan *) plan;

    if(Plan) 

    {   

        destroy_plan(Plan); 

        clReleaseContext(Plan->context);

        free(Plan);

    }       

}

void clFFT_DumpPlan( clFFT_Plan Plan, FILE *file)

{

    size_t gDim, lDim;

    FILE *out;

    if(!file)

        out = stdout;

    else 

        out = file;

    cl_fft_plan *plan = (cl_fft_plan *) Plan;

    cl_fft_kernel_info *kInfo = plan->kernel_info;

    while(kInfo)

    {

        cl_int s = 1;

        getKernelWorkDimensions(plan, kInfo, &s, &gDim, &lDim);

        fprintf(out, "Run kernel %s with global dim = {%zd*BatchSize}, local dim={%zd}\n", kInfo->kernel_name, gDim, lDim);

        kInfo = kInfo->next;

    }

    fprintf(out, "%s\n", plan->kernel_string->c_str());

}