libvision/kernel/vpu/ExynosVpuKernelBitwiseUnary.cpp

/*
 * Copyright (C) 2015, Samsung Electronics Co. LTD
 *
 * Licensed under the Apache License, Version 2.0 (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-2.0
 *
 * 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.
 */

#define LOG_TAG "ExynosVpuKernelBitwiseUnary"
#include <cutils/log.h>

#include "ExynosVpuKernelBitwiseUnary.h"

#include "vpu_kernel_util.h"

#include "td-binary-not.h"

namespace android {

using namespace std;

static vx_uint16 td_binary_bitwisenot[] =
    TASK_test_binary_not_from_VDE_DS;

vx_status
ExynosVpuKernelBitwiseUnary::inputValidator(vx_node node, vx_uint32 index)
{
    vx_status status = VX_ERROR_INVALID_PARAMETERS;

    if (index == 0) {
        vx_image input = 0;
        vx_parameter param = vxGetParameterByIndex(node, index);

        vxQueryParameter(param, VX_PARAMETER_ATTRIBUTE_REF, &input, sizeof(input));
        if (input) {
            vx_df_image format = 0;
            vxQueryImage(input, VX_IMAGE_ATTRIBUTE_FORMAT, &format, sizeof(format));
            if (format == VX_DF_IMAGE_U8)
                status = VX_SUCCESS;
            vxReleaseImage(&input);
        }
        vxReleaseParameter(&param);
    }

    return status;
}

vx_status
ExynosVpuKernelBitwiseUnary::outputValidator(vx_node node, vx_uint32 index, vx_meta_format meta)
{
    vx_status status = VX_ERROR_INVALID_PARAMETERS;

    if (index == 1) {
        vx_parameter param = vxGetParameterByIndex(node, 0);
        if (param) {
            vx_image inimage = 0;
            vxQueryParameter(param, VX_PARAMETER_ATTRIBUTE_REF, &inimage, sizeof(inimage));
            if (inimage) {
                vx_uint32 width = 0, height = 0;
                vxQueryImage(inimage, VX_IMAGE_ATTRIBUTE_WIDTH, &width, sizeof(width));
                vxQueryImage(inimage, VX_IMAGE_ATTRIBUTE_HEIGHT, &height, sizeof(height));

                vx_df_image format = VX_DF_IMAGE_U8;
                vxSetMetaFormatAttribute(meta, VX_IMAGE_ATTRIBUTE_FORMAT, &format, sizeof(format));
                vxSetMetaFormatAttribute(meta, VX_IMAGE_ATTRIBUTE_WIDTH, &width, sizeof(width));
                vxSetMetaFormatAttribute(meta, VX_IMAGE_ATTRIBUTE_HEIGHT, &height, sizeof(height));

                status = VX_SUCCESS;
                vxReleaseImage(&inimage);
            }
            vxReleaseParameter(&param);
        }
    }

    return status;
}

ExynosVpuKernelBitwiseUnary::ExynosVpuKernelBitwiseUnary(vx_char *name, vx_uint32 param_num)
                                       : ExynosVpuKernel(name, param_num)
{

}

ExynosVpuKernelBitwiseUnary::~ExynosVpuKernelBitwiseUnary(void)
{

}

vx_status
ExynosVpuKernelBitwiseUnary::setupBaseVxInfo(const vx_reference parameters[])
{
    vx_status status = VX_FAILURE;

    vx_image input = (vx_image)parameters[0];

    status = vxGetValidAncestorRegionImage(input, &m_valid_rect);
    if (status != VX_SUCCESS) {
        VXLOGE("getting valid region fails, err:%d", status);
    }

    return status;
}

vx_status
ExynosVpuKernelBitwiseUnary::updateTaskParamFromVX(vx_node node, const vx_reference *parameters)
{
    vx_status status = VX_SUCCESS;

     if (!node)
        VXLOGE("invalid node, %p, %p", node, parameters);

    /* update vpu param from vx param */
    /* do nothing */

EXIT:
    return status;
}

vx_status
ExynosVpuKernelBitwiseUnary::initVxIo(const vx_reference *parameters)
{
    vx_status status = VX_SUCCESS;

    ExynosVpuTaskIfWrapper *task_wr_0 = m_task_wr_list[0];

    /* connect vx param to io */
    vx_param_info_t param_info;
    memset(&param_info, 0x0, sizeof(param_info));

    param_info.image.plane = 0;
    status = task_wr_0->setIoVxParam(VS4L_DIRECTION_IN, 0, 0, param_info);
    if (status != VX_SUCCESS) {
        VXLOGE("assigning param fails, %p", parameters);
        goto EXIT;
    }

    param_info.image.plane = 0;
    status = task_wr_0->setIoVxParam(VS4L_DIRECTION_OT, 0, 1, param_info);
    if (status != VX_SUCCESS) {
        VXLOGE("assigning param fails, %p", parameters);
        goto EXIT;
    }

EXIT:
    return status;
}

ExynosVpuKernelBitwiseNot::ExynosVpuKernelBitwiseNot(vx_char *name, vx_uint32 param_num)
                                       : ExynosVpuKernelBitwiseUnary(name, param_num)
{
    strcpy(m_task_name, "not");
}

vx_status
ExynosVpuKernelBitwiseNot::initTask(vx_node node, const vx_reference *parameters)
{
    vx_status status;

#if 1
    status = initTaskFromBinary();
    if (status != VX_SUCCESS) {
        VXLOGE("init task from binary fails, %p, %p", node, parameters);
        goto EXIT;
    }
#else
    status = initTaskFromApi();
    if (status != VX_SUCCESS) {
        VXLOGE("init task from api fails, %p, %p", node, parameters);
        goto EXIT;
    }
#endif

EXIT:
    return status;
}

vx_status
ExynosVpuKernelBitwiseNot::initTaskFromBinary(void)
{
    vx_status status = VX_SUCCESS;
    ExynosVpuTaskIf *task_if_0;

    task_if_0 = initTask0FromBinary();
    if (task_if_0 == NULL) {
        VXLOGE("task0 isn't created");
        status = VX_FAILURE;
        goto EXIT;
    }

EXIT:
    return status;
}

ExynosVpuTaskIf*
ExynosVpuKernelBitwiseNot::initTask0FromBinary(void)
{
    vx_status status = VX_SUCCESS;
    int ret = NO_ERROR;

    ExynosVpuTaskIfWrapper *task_wr = new ExynosVpuTaskIfWrapper(this, 0);
    status = setTaskIfWrapper(0, task_wr);
    if (status != VX_SUCCESS) {
        VXLOGE("adding taskif wrapper fails");
        return NULL;
    }

    ExynosVpuTaskIf *task_if = task_wr->getTaskIf();
    ret = task_if->importTaskStr((struct vpul_task*)td_binary_bitwisenot);
    if (ret != NO_ERROR) {
        VXLOGE("creating task descriptor fails, ret:%d", ret);
        status = VX_FAILURE;
    }

    /* connect pu to io */
    task_if->setIoPu(VS4L_DIRECTION_IN, 0, (uint32_t)0);
    task_if->setIoPu(VS4L_DIRECTION_OT, 0, (uint32_t)2);

    if (status == VX_SUCCESS)
        return task_if;
    else
        return NULL;
}

vx_status
ExynosVpuKernelBitwiseNot::initTaskFromApi(void)
{
    vx_status status = VX_SUCCESS;
    ExynosVpuTaskIf *task_if_0;

    task_if_0 = initTask0FromApi();
    if (task_if_0 == NULL) {
        VXLOGE("task0 isn't created");
        status = VX_FAILURE;
        goto EXIT;
    }

    status = createStrFromObjectOfTask();
    if (status != VX_SUCCESS) {
        VXLOGE("creating task str fails");
        goto EXIT;
    }

EXIT:
    return status;
}

ExynosVpuTaskIf*
ExynosVpuKernelBitwiseNot::initTask0FromApi(void)
{
    vx_status status = VX_SUCCESS;

    ExynosVpuPuFactory pu_factory;

    ExynosVpuTaskIfWrapper *task_wr = new ExynosVpuTaskIfWrapper(this, 0);
    status = setTaskIfWrapper(0, task_wr);
    if (status != VX_SUCCESS) {
        VXLOGE("adding taskif wrapper fails");
        return NULL;
    }

    ExynosVpuTaskIf *task_if = task_wr->getTaskIf();
    ExynosVpuTask *task = new ExynosVpuTask(task_if);
    struct vpul_task *task_param = task->getTaskInfo();
    task_param->priority = m_priority;

    ExynosVpuVertex *start_vertex = new ExynosVpuVertex(task, VPUL_VERTEXT_START);
    ExynosVpuProcess *salb_process = new ExynosVpuProcess(task);
    ExynosVpuVertex *end_vertex = new ExynosVpuVertex(task, VPUL_VERTEXT_END);

    ExynosVpuVertex::connect(start_vertex, salb_process);
    ExynosVpuVertex::connect(salb_process, end_vertex);

    ExynosVpuIoSizeInout *iosize = new ExynosVpuIoSizeInout(salb_process);

    /* define subchain */
    ExynosVpuSubchainHw *salb_subchain = new ExynosVpuSubchainHw(salb_process);

    /* define pu */
    ExynosVpuPu *in = pu_factory.createPu(salb_subchain, VPU_PU_DMAIN0);
    in->setSize(iosize, iosize);
    ExynosVpuPu *salb = pu_factory.createPu(salb_subchain, VPU_PU_SALB0);
    salb->setSize(iosize, iosize);
    ExynosVpuPu *out = pu_factory.createPu(salb_subchain, VPU_PU_DMAOT0);
    out->setSize(iosize, iosize);

    ExynosVpuPu::connect(in, 0, salb, 0);
    ExynosVpuPu::connect(salb, 0, out, 0);

    struct vpul_pu_dma *in_param = (struct vpul_pu_dma*)in->getParameter();
    struct vpul_pu_salb *salb_param = (struct vpul_pu_salb*)salb->getParameter();
    struct vpul_pu_dma *out_param = (struct vpul_pu_dma*)out->getParameter();

    salb_param->input_enable = 1;
    salb_param->operation_code = 7;
    salb_param->salbregs_custom_trunc_bittage = 1;

    /* connect pu to io */
    ExynosVpuIoExternalMem *io_external_mem;
    ExynosVpuMemmapExternal *memmap;
    ExynosVpuIoFixedMapRoi *fixed_roi;
    ExynosVpuIoTypesDesc *iotyps;

    io_external_mem = new ExynosVpuIoExternalMem(task);
    memmap = new ExynosVpuMemmapExternal(task, io_external_mem);
    fixed_roi = new ExynosVpuIoFixedMapRoi(salb_process, memmap);
    iotyps = new ExynosVpuIoTypesDesc(salb_process, fixed_roi);
    in->setIoTypesDesc(iotyps);

    io_external_mem = new ExynosVpuIoExternalMem(task);
    memmap = new ExynosVpuMemmapExternal(task, io_external_mem);
    fixed_roi = new ExynosVpuIoFixedMapRoi(salb_process, memmap);
    iotyps = new ExynosVpuIoTypesDesc(salb_process, fixed_roi);
    out->setIoTypesDesc(iotyps);

    status_t ret = NO_ERROR;
    ret |= task_if->setIoPu(VS4L_DIRECTION_IN, 0, in);
    ret |= task_if->setIoPu(VS4L_DIRECTION_OT, 0, out);
    if (ret != NO_ERROR) {
        VXLOGE("connectting pu to io fails");
        status = VX_FAILURE;
        goto EXIT;
    }

EXIT:
    if (status == VX_SUCCESS)
        return task_if;
    else
        return NULL;
}

}; /* namespace android */