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fuchsia / third_party / github.com / intel / libva-utils / refs/heads/upstream/v2.18-branch / . / videoprocess / vpphdr_tm.cpp
blob: 5007ac0a7f0a6a13498a64460eb5436fea1c08f2 [file] [log] [blame] [edit]
/*
* Copyright (c) 2009-2022, Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* 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 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR
* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
* OTHER DEALINGS IN THE SOFTWARE.
*/
/*
* Video process test case based on LibVA.
* This test covers high dynamic range tone mapping feature.
* Usage: ./vpphdr_tm process_hdr_tm.cfg
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <time.h>
#include <assert.h>
#include <va/va.h>
#include <va/va_vpp.h>
#include "va_display.h"
#ifndef VA_FOURCC_I420
#define VA_FOURCC_I420 0x30323449
#endif
#define MAX_LEN 1024
#define CHECK_VASTATUS(va_status,func) \
if (va_status != VA_STATUS_SUCCESS) { \
printf("%s:%s (%d) failed,exit\n", __func__, func, __LINE__); \
exit(1); \
}
static VADisplay va_dpy = NULL;
static VAContextID context_id = 0;
static VAConfigID config_id = 0;
static VASurfaceID g_in_surface_id = VA_INVALID_ID;
static VASurfaceID g_out_surface_id = VA_INVALID_ID;
static FILE* g_config_file_fd = NULL;
static FILE* g_src_file_fd = NULL;
static FILE* g_dst_file_fd = NULL;
static char g_config_file_name[MAX_LEN];
static char g_src_file_name[MAX_LEN];
static char g_dst_file_name[MAX_LEN];
static uint32_t g_in_pic_width = 1920;
static uint32_t g_in_pic_height = 1080;
static uint32_t g_out_pic_width = 1920;
static uint32_t g_out_pic_height = 1080;
static uint32_t g_in_fourcc = VA_FOURCC('N', 'V', '1', '2');
static uint32_t g_in_format = VA_FOURCC_P010;
static uint32_t g_out_fourcc = VA_FOURCC('N', 'V', '1', '2');
static uint32_t g_out_format = VA_RT_FORMAT_YUV420;
static uint32_t g_src_file_fourcc = VA_FOURCC('I', '4', '2', '0');
static uint32_t g_dst_file_fourcc = VA_FOURCC('Y', 'V', '1', '2');
static uint32_t g_frame_count = 1;
// The maximum display luminace is 1000 nits by default.
static uint32_t g_in_max_display_luminance = 10000000;
static uint32_t g_in_min_display_luminance = 100;
static uint32_t g_in_max_content_luminance = 4000;
static uint32_t g_in_pic_average_luminance = 1000;
// The maximum display luminace is 1000 nits by default.
static uint32_t g_out_max_display_luminance = 10000000;
static uint32_t g_out_min_display_luminance = 100;
static uint32_t g_out_max_content_luminance = 4000;
static uint32_t g_out_pic_average_luminance = 1000;
static uint32_t g_in_colour_primaries = 9;
static uint32_t g_in_transfer_characteristic = 16;
static uint32_t g_out_colour_primaries = 9;
static uint32_t g_out_transfer_characteristic = 16;
static uint32_t g_tm_type =1;
static int8_t
read_value_string(FILE *fp, const char* field_name, char* value)
{
char strLine[MAX_LEN];
char* field = NULL;
char* str = NULL;
uint16_t i;
if (!fp || !field_name || !value) {
printf("Invalid fuction parameters\n");
return -1;
}
rewind(fp);
while (!feof(fp)) {
if (!fgets(strLine, MAX_LEN, fp))
continue;
for (i = 0; i < MAX_LEN && strLine[i]; i++)
if (strLine[i] != ' ') break;
if (i == MAX_LEN || strLine[i] == '#' || strLine[i] == '\n')
continue;
field = strtok(&strLine[i], ":");
if (strncmp(field, field_name, strlen(field_name)))
continue;
if (!(str = strtok(NULL, ":")))
continue;
/* skip blank space in string */
while (*str == ' ')
str++;
*(str + strlen(str)-1) = '\0';
strcpy(value, str);
return 0;
}
return -1;
}
static int8_t
read_value_uint32(FILE* fp, const char* field_name, uint32_t* value)
{
char str[MAX_LEN];
if (read_value_string(fp, field_name, str)) {
printf("Failed to find integer field: %s", field_name);
return -1;
}
*value = (uint32_t)atoi(str);
return 0;
}
static int8_t
read_value_float(FILE *fp, const char* field_name, float* value)
{
char str[MAX_LEN];
if (read_value_string(fp, field_name, str)) {
printf("Failed to find float field: %s \n",field_name);
return -1;
}
*value = atof(str);
return 0;
}
static VAStatus
create_surface(VASurfaceID * p_surface_id,
uint32_t width, uint32_t height,
uint32_t fourCC, uint32_t format)
{
VAStatus va_status;
VASurfaceAttrib surface_attrib;
surface_attrib.type = VASurfaceAttribPixelFormat;
surface_attrib.flags = VA_SURFACE_ATTRIB_SETTABLE;
surface_attrib.value.type = VAGenericValueTypeInteger;
surface_attrib.value.value.i = fourCC;
va_status = vaCreateSurfaces(va_dpy,
format,
width ,
height,
p_surface_id,
1,
&surface_attrib,
1);
printf("create_surface: p_surface_id %d, width %d, height %d, fourCC 0x%x, format 0x%x\n",
*p_surface_id, width, height, fourCC, format);
return va_status;
}
static VAStatus
hdrtm_filter_init(VABufferID *filter_param_buf_id, uint32_t tm_type)
{
VAStatus va_status = VA_STATUS_SUCCESS;
VAProcFilterParameterBufferHDRToneMapping hdrtm_param;
VAHdrMetaDataHDR10 in_hdr10_metadata = {};
// The input is HDR content
in_hdr10_metadata.max_display_mastering_luminance = g_in_max_display_luminance;
in_hdr10_metadata.min_display_mastering_luminance = g_in_min_display_luminance;
in_hdr10_metadata.max_content_light_level = g_in_max_content_luminance;
in_hdr10_metadata.max_pic_average_light_level = g_in_pic_average_luminance;
in_hdr10_metadata.display_primaries_x[0] = 8500;
in_hdr10_metadata.display_primaries_y[0] = 39850;
in_hdr10_metadata.display_primaries_x[1] = 35400;
in_hdr10_metadata.display_primaries_y[1] = 14600;
in_hdr10_metadata.display_primaries_x[2] = 6550;
in_hdr10_metadata.display_primaries_y[2] = 2300;
in_hdr10_metadata.white_point_x = 15635;
in_hdr10_metadata.white_point_y = 16450;
hdrtm_param.type = VAProcFilterHighDynamicRangeToneMapping;
hdrtm_param.data.metadata_type = VAProcHighDynamicRangeMetadataHDR10;
hdrtm_param.data.metadata= &in_hdr10_metadata;
hdrtm_param.data.metadata_size = sizeof(VAHdrMetaDataHDR10);
va_status = vaCreateBuffer(va_dpy, context_id, VAProcFilterParameterBufferType, sizeof(hdrtm_param), 1, (void *)&hdrtm_param, filter_param_buf_id);
return va_status;
}
static VAStatus
hdrtm_metadata_init(VAHdrMetaData &out_metadata, uint32_t tm_type, VAHdrMetaDataHDR10 &out_hdr10_metadata)
{
VAStatus va_status = VA_STATUS_SUCCESS;
out_hdr10_metadata.max_display_mastering_luminance = g_out_max_display_luminance;
out_hdr10_metadata.min_display_mastering_luminance = g_out_min_display_luminance;
out_hdr10_metadata.max_content_light_level = g_out_max_content_luminance;
out_hdr10_metadata.max_pic_average_light_level = g_out_pic_average_luminance;
printf("hdrtm_metadata_init g_out_max_display_luminance %d, g_out_min_display_luminance %d\n", g_out_max_display_luminance, g_out_min_display_luminance);
printf("hdrtm_metadata_init g_out_max_content_luminance %d, g_out_pic_average_luminance %d\n", g_out_max_content_luminance, g_out_pic_average_luminance);
// HDR display or SDR display
switch (tm_type)
{
case VA_TONE_MAPPING_HDR_TO_HDR:
out_hdr10_metadata.display_primaries_x[0] = 8500;
out_hdr10_metadata.display_primaries_y[0] = 39850;
out_hdr10_metadata.display_primaries_x[1] = 35400;
out_hdr10_metadata.display_primaries_y[1] = 14600;
out_hdr10_metadata.display_primaries_x[2] = 6550;
out_hdr10_metadata.display_primaries_y[2] = 2300;
out_hdr10_metadata.white_point_x = 15635;
out_hdr10_metadata.white_point_y = 16450;
break;
case VA_TONE_MAPPING_HDR_TO_SDR:
out_hdr10_metadata.display_primaries_x[0] = 15000;
out_hdr10_metadata.display_primaries_y[0] = 30000;
out_hdr10_metadata.display_primaries_x[1] = 32000;
out_hdr10_metadata.display_primaries_y[1] = 16500;
out_hdr10_metadata.display_primaries_x[2] = 7500;
out_hdr10_metadata.display_primaries_y[2] = 3000;
out_hdr10_metadata.white_point_x = 15635;
out_hdr10_metadata.white_point_y = 16450;
break;
default:
break;
}
out_metadata.metadata_type = VAProcHighDynamicRangeMetadataHDR10;
out_metadata.metadata = &out_hdr10_metadata;
out_metadata.metadata_size = sizeof(VAHdrMetaDataHDR10);
return va_status;
}
static VAStatus
video_frame_process(VASurfaceID in_surface_id,
VASurfaceID out_surface_id)
{
VAStatus va_status;
VAProcPipelineParameterBuffer pipeline_param = {};
VARectangle surface_region = {}, output_region = {};
VABufferID pipeline_param_buf_id = VA_INVALID_ID;
VABufferID filter_param_buf_id = VA_INVALID_ID;
VAHdrMetaData out_metadata = {};
/*Query Filter's Caps: The return value will be HDR10 and H2S, H2H, H2E. */
VAProcFilterCapHighDynamicRange hdrtm_caps[VAProcHighDynamicRangeMetadataTypeCount];
uint32_t num_hdrtm_caps = VAProcHighDynamicRangeMetadataTypeCount;
memset(&hdrtm_caps, 0, sizeof(VAProcFilterCapHighDynamicRange)*num_hdrtm_caps);
va_status = vaQueryVideoProcFilterCaps(va_dpy, context_id,
VAProcFilterHighDynamicRangeToneMapping,
(void *)hdrtm_caps, &num_hdrtm_caps);
CHECK_VASTATUS(va_status,"vaQueryVideoProcFilterCaps");
printf("vaQueryVideoProcFilterCaps num_hdrtm_caps %d\n", num_hdrtm_caps);
for (int i = 0; i < num_hdrtm_caps; ++i) {
printf("vaQueryVideoProcFilterCaps hdrtm_caps[%d]: metadata type %d, flag %d\n", i, hdrtm_caps[i].metadata_type, hdrtm_caps[i].caps_flag);
}
hdrtm_filter_init(&filter_param_buf_id, g_tm_type);
VAHdrMetaDataHDR10 out_hdr10_metadata = {};
hdrtm_metadata_init(out_metadata, g_tm_type, out_hdr10_metadata);
/* Fill pipeline buffer */
surface_region.x = 0;
surface_region.y = 0;
surface_region.width = g_in_pic_width;
surface_region.height = g_in_pic_height;
output_region.x = 0;
output_region.y = 0;
output_region.width = g_out_pic_width;
output_region.height = g_out_pic_height;
memset(&pipeline_param, 0, sizeof(pipeline_param));
pipeline_param.surface = in_surface_id;
pipeline_param.surface_region = &surface_region;
pipeline_param.output_region = &output_region;
pipeline_param.filter_flags = 0;
pipeline_param.filters = &filter_param_buf_id;
pipeline_param.num_filters = 1;
pipeline_param.surface_color_standard = VAProcColorStandardExplicit;
pipeline_param.input_color_properties.colour_primaries = g_in_colour_primaries;
pipeline_param.input_color_properties.transfer_characteristics = g_in_transfer_characteristic;
pipeline_param.output_color_standard = VAProcColorStandardExplicit;
pipeline_param.output_color_properties.colour_primaries = g_out_colour_primaries;
pipeline_param.output_color_properties.transfer_characteristics = g_out_transfer_characteristic;
pipeline_param.output_hdr_metadata = &out_metadata;
va_status = vaCreateBuffer(va_dpy,
context_id,
VAProcPipelineParameterBufferType,
sizeof(pipeline_param),
1,
&pipeline_param,
&pipeline_param_buf_id);
CHECK_VASTATUS(va_status, "vaCreateBuffer");
va_status = vaBeginPicture(va_dpy,
context_id,
out_surface_id);
CHECK_VASTATUS(va_status, "vaBeginPicture");
va_status = vaRenderPicture(va_dpy,
context_id,
&pipeline_param_buf_id,
1);
CHECK_VASTATUS(va_status, "vaRenderPicture");
va_status = vaEndPicture(va_dpy, context_id);
CHECK_VASTATUS(va_status, "vaEndPicture");
if (filter_param_buf_id != VA_INVALID_ID)
vaDestroyBuffer(va_dpy,filter_param_buf_id);
if (pipeline_param_buf_id != VA_INVALID_ID)
vaDestroyBuffer(va_dpy,pipeline_param_buf_id);
return va_status;
}
static VAStatus
vpp_context_create()
{
VAStatus va_status = VA_STATUS_SUCCESS;
uint32_t i;
int32_t j;
/* VA driver initialization */
va_dpy = va_open_display();
int32_t major_ver, minor_ver;
va_status = vaInitialize(va_dpy, &major_ver, &minor_ver);
assert(va_status == VA_STATUS_SUCCESS);
/* Check whether VPP is supported by driver */
VAEntrypoint entrypoints[5];
int32_t num_entrypoints;
num_entrypoints = vaMaxNumEntrypoints(va_dpy);
va_status = vaQueryConfigEntrypoints(va_dpy,
VAProfileNone,
entrypoints,
&num_entrypoints);
CHECK_VASTATUS(va_status, "vaQueryConfigEntrypoints");
for (j = 0; j < num_entrypoints; j++) {
if (entrypoints[j] == VAEntrypointVideoProc)
break;
}
if (j == num_entrypoints) {
printf("VPP is not supported by driver\n");
assert(0);
}
/* Render target surface format check */
VAConfigAttrib attrib;
attrib.type = VAConfigAttribRTFormat;
va_status = vaGetConfigAttributes(va_dpy,
VAProfileNone,
VAEntrypointVideoProc,
&attrib,
1);
CHECK_VASTATUS(va_status, "vaGetConfigAttributes");
if (!(attrib.value & g_out_format)) {
printf("RT format %d is not supported by VPP !\n",g_out_format);
//assert(0);
}
/* Create surface/config/context for VPP pipeline */
va_status = create_surface(&g_in_surface_id, g_in_pic_width, g_in_pic_height,
g_in_fourcc, g_in_format);
CHECK_VASTATUS(va_status, "vaCreateSurfaces for input");
va_status = create_surface(&g_out_surface_id, g_out_pic_width, g_out_pic_height,
g_out_fourcc, g_out_format);
CHECK_VASTATUS(va_status, "vaCreateSurfaces for output");
va_status = vaCreateConfig(va_dpy,
VAProfileNone,
VAEntrypointVideoProc,
&attrib,
1,
&config_id);
CHECK_VASTATUS(va_status, "vaCreateConfig");
va_status = vaCreateContext(va_dpy,
config_id,
g_out_pic_width,
g_out_pic_height,
VA_PROGRESSIVE,
&g_out_surface_id,
1,
&context_id);
CHECK_VASTATUS(va_status, "vaCreateContext");
uint32_t supported_filter_num = VAProcFilterCount;
VAProcFilterType supported_filter_types[VAProcFilterCount];
va_status = vaQueryVideoProcFilters(va_dpy,
context_id,
supported_filter_types,
&supported_filter_num);
CHECK_VASTATUS(va_status, "vaQueryVideoProcFilters");
for (i = 0; i < supported_filter_num; i++){
if (supported_filter_types[i] == VAProcFilterHighDynamicRangeToneMapping)
break;
}
if (i == supported_filter_num) {
printf("VPP filter type VAProcFilterHighDynamicRangeToneMapping is not supported by driver !\n");
}
return va_status;
}
static void
vpp_context_destroy()
{
/* Release resource */
vaDestroySurfaces(va_dpy, &g_in_surface_id, 1);
vaDestroySurfaces(va_dpy, &g_out_surface_id, 1);
vaDestroyContext(va_dpy, context_id);
vaDestroyConfig(va_dpy, config_id);
vaTerminate(va_dpy);
va_close_display(va_dpy);
}
static int8_t
parse_fourcc_and_format(char *str, uint32_t *fourcc, uint32_t *format)
{
uint32_t tfourcc = VA_FOURCC('N', 'V', '1', '2');
uint32_t tformat = VA_RT_FORMAT_YUV420;
if (!strcmp(str, "YV12")){
tfourcc = VA_FOURCC('Y', 'V', '1', '2');
} else if(!strcmp(str, "I420")){
tfourcc = VA_FOURCC('I', '4', '2', '0');
} else if(!strcmp(str, "NV12")){
tfourcc = VA_FOURCC('N', 'V', '1', '2');
} else if(!strcmp(str, "YUY2") || !strcmp(str, "YUYV")) {
tfourcc = VA_FOURCC('Y', 'U', 'Y', '2');
} else if(!strcmp(str, "UYVY")){
tfourcc = VA_FOURCC('U', 'Y', 'V', 'Y');
} else if (!strcmp(str, "P010")) {
tfourcc = VA_FOURCC('P', '0', '1', '0');
} else if (!strcmp(str, "I010")) {
tfourcc = VA_FOURCC('I', '0', '1', '0');
} else if (!strcmp(str, "RGBA")) {
tformat = VA_RT_FORMAT_RGB32;
tfourcc = VA_FOURCC_RGBA;
printf("parse_fourcc_and_format: RGBA format 0x%8x, fourcc 0x%8x\n", tformat, tfourcc);
} else if (!strcmp(str, "RGBX")) {
tfourcc = VA_FOURCC_RGBX;
} else if (!strcmp(str, "BGRA")) {
tfourcc = VA_FOURCC_BGRA;
} else if (!strcmp(str, "BGRX")) {
tfourcc = VA_FOURCC_BGRX;
} else if (!strcmp(str, "P010")) {
tfourcc = VA_FOURCC_P010;
printf("parse_fourcc_and_format: P010\n");
} else if (!strcmp(str, "A2RGB10")) { //A2R10G10B10
tfourcc = VA_FOURCC_A2R10G10B10;
printf("parse_fourcc_and_format: ARGB10 format 0x%8x, fourcc 0x%8x\n", tformat, tfourcc);
} else{
printf("Not supported format: %s! Currently only support following format: %s\n",
str, "YV12, I420, NV12, YUY2(YUYV), UYVY, I010, RGBA, RGBX, BGRA or BGRX");
assert(0);
}
printf("parse_fourcc_and_format: format 0x%x, fourcc 0x%x\n", tformat, tfourcc);
if (fourcc)
*fourcc = tfourcc;
if (format)
*format = tformat;
return 0;
}
bool read_frame_to_surface(FILE *fp, VASurfaceID surface_id)
{
VAStatus va_status;
VAImage va_image;
int i = 0;
int frame_size = 0, y_size = 0, u_size = 0;
unsigned char *y_src = NULL, *u_src = NULL, *v_src = NULL;
unsigned char *y_dst = NULL, *u_dst = NULL, *v_dst = NULL;
int bytes_per_pixel = 2;
void *out_buf = NULL;
unsigned char *src_buffer = NULL;
if (fp == NULL)
return false;
// This function blocks until all pending operations on the surface have been completed.
va_status = vaSyncSurface(va_dpy, surface_id);
CHECK_VASTATUS(va_status, "vaSyncSurface");
va_status = vaDeriveImage(va_dpy, surface_id, &va_image);
CHECK_VASTATUS(va_status, "vaDeriveImage");
va_status = vaMapBuffer(va_dpy, va_image.buf, &out_buf);
CHECK_VASTATUS(va_status, "vaMapBuffer");
printf("read_frame_to_surface: va_image.width %d, va_image.height %d, va_image.pitches[0]: %d, va_image.pitches[1] %d, va_image.pitches[2] %d\n",
va_image.width, va_image.height, va_image.pitches[0], va_image.pitches[1], va_image.pitches[1]);
switch (va_image.format.fourcc)
{
case VA_FOURCC_P010:
frame_size = va_image.width * va_image.height * bytes_per_pixel * 3 / 2;
y_size = va_image.width * va_image.height * bytes_per_pixel;
u_size = (va_image.width / 2 * bytes_per_pixel) * (va_image.height >> 1);
src_buffer = (unsigned char*)malloc(frame_size);
assert(src_buffer);
fread(src_buffer, 1, frame_size, fp);
y_src = src_buffer;
u_src = src_buffer + y_size; // UV offset for P010
y_dst = (unsigned char*)out_buf + va_image.offsets[0]; // Y plane
u_dst = (unsigned char*)out_buf + va_image.offsets[1]; // U offset for P010
for (i = 0; i < va_image.height; i++) {
memcpy(y_dst, y_src, va_image.width * 2);
y_dst += va_image.pitches[0];
y_src += va_image.width * 2;
}
for (i = 0; i < va_image.height >> 1; i++) {
memcpy(u_dst, u_src, va_image.width * 2);
u_dst += va_image.pitches[1];
u_src += va_image.width * 2;
}
printf("read_frame_to_surface: P010 \n");
break;
case VA_RT_FORMAT_RGB32_10BPP:
case VA_FOURCC_RGBA:
case VA_FOURCC_A2R10G10B10:
case VA_FOURCC_A2B10G10R10:
frame_size = va_image.width * va_image.height * 4;
src_buffer = (unsigned char*)malloc(frame_size);
assert(src_buffer);
fread(src_buffer, 1, frame_size, fp);
y_src = src_buffer;
y_dst = (unsigned char*)out_buf + va_image.offsets[0];
for (i = 0; i < va_image.height; i++) {
memcpy(y_dst, y_src, va_image.width * 4);
y_dst += va_image.pitches[0];
y_src += va_image.width * 4;
}
printf("read_frame_to_surface: RGBA or A2RGB10 \n");
break;
default: // should not come here
printf("VA_STATUS_ERROR_INVALID_IMAGE_FORMAT \n");
va_status = VA_STATUS_ERROR_INVALID_IMAGE_FORMAT;
break;
}
vaUnmapBuffer(va_dpy, va_image.buf);
vaDestroyImage(va_dpy, va_image.image_id);
if (src_buffer)
{
free(src_buffer);
src_buffer = NULL;
}
if (va_status != VA_STATUS_SUCCESS)
return false;
else
return true;
}
bool write_surface_to_frame(FILE *fp, VASurfaceID surface_id)
{
VAStatus va_status;
VAImage va_image;
int i = 0;
int frame_size = 0, y_size = 0, u_size = 0;
unsigned char *y_src = NULL, *u_src = NULL, *v_src = NULL;
unsigned char *y_dst = NULL, *u_dst = NULL, *v_dst = NULL;
int bytes_per_pixel = 2;
void *in_buf = NULL;
unsigned char *dst_buffer = NULL;
if (fp == NULL)
return false;
// This function blocks until all pending operations on the surface have been completed.
va_status = vaSyncSurface(va_dpy, surface_id);
CHECK_VASTATUS(va_status, "vaSyncSurface");
va_status = vaDeriveImage(va_dpy, surface_id, &va_image);
CHECK_VASTATUS(va_status, "vaDeriveImage");
va_status = vaMapBuffer(va_dpy, va_image.buf, &in_buf);
CHECK_VASTATUS(va_status, "vaMapBuffer");
printf("write_surface_to_frame: va_image.width %d, va_image.height %d, va_image.pitches[0]: %d, va_image.pitches[1] %d, va_image.pitches[2] %d\n",
va_image.width, va_image.height, va_image.pitches[0], va_image.pitches[1], va_image.pitches[1]);
switch (va_image.format.fourcc)
{
case VA_FOURCC_P010:
case VA_FOURCC_NV12:
bytes_per_pixel = (va_image.format.fourcc == VA_FOURCC_P010) ? 2 : 1;
frame_size = va_image.width * va_image.height * bytes_per_pixel * 3 / 2;
dst_buffer = (unsigned char*)malloc(frame_size);
assert(dst_buffer);
y_size = va_image.width * va_image.height * bytes_per_pixel;
u_size = (va_image.width / 2 * bytes_per_pixel) * (va_image.height >> 1);
y_dst = dst_buffer;
u_dst = dst_buffer + y_size; // UV offset for P010
y_src = (unsigned char*)in_buf + va_image.offsets[0];
u_src = (unsigned char*)in_buf + va_image.offsets[1]; // U offset for P010
for (i = 0; i < va_image.height; i++) {
memcpy(y_dst, y_src, va_image.width * bytes_per_pixel);
y_dst += va_image.width * bytes_per_pixel;
y_src += va_image.pitches[0];
}
for (i = 0; i < va_image.height >> 1; i++) {
memcpy(u_dst, u_src, va_image.width * bytes_per_pixel);
u_dst += va_image.width * bytes_per_pixel;
u_src += va_image.pitches[1];
}
printf("read_frame_to_surface: P010 \n");
break;
case VA_FOURCC_RGBA:
case VA_FOURCC_ABGR:
case VA_FOURCC_A2B10G10R10:
case VA_FOURCC_A2R10G10B10:
frame_size = va_image.width * va_image.height * 4;
dst_buffer = (unsigned char*)malloc(frame_size);
assert(dst_buffer);
y_dst = dst_buffer;
y_src = (unsigned char*)in_buf + va_image.offsets[0];
for (i = 0; i < va_image.height; i++) {
memcpy(y_dst, y_src, va_image.width * 4);
y_dst += va_image.pitches[0];
y_src += va_image.width * 4;
}
printf("read_frame_to_surface: RGBA and A2R10G10B10 \n");
break;
default: // should not come here
printf("VA_STATUS_ERROR_INVALID_IMAGE_FORMAT %x\n", va_image.format.fourcc);
va_status = VA_STATUS_ERROR_INVALID_IMAGE_FORMAT;
break;
}
assert(dst_buffer);
fwrite(dst_buffer, 1, frame_size, fp);
if (dst_buffer) {
free(dst_buffer);
dst_buffer = NULL;
}
vaUnmapBuffer(va_dpy, va_image.buf);
vaDestroyImage(va_dpy, va_image.image_id);
if (va_status != VA_STATUS_SUCCESS)
return false;
else
return true;
}
static int8_t
parse_basic_parameters()
{
char str[MAX_LEN];
/* Read src frame file information */
read_value_string(g_config_file_fd, "SRC_FILE_NAME", g_src_file_name);
read_value_uint32(g_config_file_fd, "SRC_FRAME_WIDTH", &g_in_pic_width);
read_value_uint32(g_config_file_fd, "SRC_FRAME_HEIGHT", &g_in_pic_height);
read_value_string(g_config_file_fd, "SRC_FRAME_FORMAT", str);
parse_fourcc_and_format(str, &g_in_fourcc, &g_in_format);
printf("Input file: %s, width: %d, height: %d, fourcc 0x%x, format 0x%x\n", g_src_file_name, g_in_pic_width, g_in_pic_height, g_in_fourcc, g_in_format);
/* Read dst frame file information */
read_value_string(g_config_file_fd, "DST_FILE_NAME", g_dst_file_name);
read_value_uint32(g_config_file_fd, "DST_FRAME_WIDTH", &g_out_pic_width);
read_value_uint32(g_config_file_fd, "DST_FRAME_HEIGHT",&g_out_pic_height);
read_value_string(g_config_file_fd, "DST_FRAME_FORMAT", str);
parse_fourcc_and_format(str, &g_out_fourcc, &g_out_format);
printf("Output file: %s, width: %d, height: %d, fourcc 0x%x, format 0x%x\n", g_dst_file_name, g_out_pic_width, g_out_pic_height, g_out_fourcc, g_out_format);
read_value_string(g_config_file_fd, "SRC_FILE_FORMAT", str);
parse_fourcc_and_format(str, &g_src_file_fourcc, NULL);
read_value_string(g_config_file_fd, "DST_FILE_FORMAT", str);
parse_fourcc_and_format(str, &g_dst_file_fourcc, NULL);
read_value_uint32(g_config_file_fd, "FRAME_SUM", &g_frame_count);
read_value_uint32(g_config_file_fd, "SRC_MAX_DISPLAY_MASTERING_LUMINANCE", &g_in_max_display_luminance);
read_value_uint32(g_config_file_fd, "SRC_MIN_DISPLAY_MASTERING_LUMINANCE", &g_in_min_display_luminance);
read_value_uint32(g_config_file_fd, "SRC_MAX_CONTENT_LIGHT_LEVEL", &g_in_max_content_luminance);
read_value_uint32(g_config_file_fd, "SRC_MAX_PICTURE_AVERAGE_LIGHT_LEVEL", &g_in_pic_average_luminance);
read_value_uint32(g_config_file_fd, "DST_MAX_DISPLAY_MASTERING_LUMINANCE", &g_out_max_display_luminance);
read_value_uint32(g_config_file_fd, "DST_MIN_DISPLAY_MASTERING_LUMINANCE", &g_out_min_display_luminance);
read_value_uint32(g_config_file_fd, "DST_MAX_CONTENT_LIGHT_LEVEL", &g_out_max_content_luminance);
read_value_uint32(g_config_file_fd, "DST_MAX_PICTURE_AVERAGE_LIGHT_LEVEL", &g_out_pic_average_luminance);
read_value_uint32(g_config_file_fd, "SRC_FRAME_COLOUR_PRIMARIES", &g_in_colour_primaries);
read_value_uint32(g_config_file_fd, "SRC_FRAME_TRANSFER_CHARACTERISTICS", &g_in_transfer_characteristic);
read_value_uint32(g_config_file_fd, "DST_FRAME_COLOUR_PRIMARIES", &g_out_colour_primaries);
read_value_uint32(g_config_file_fd, "DST_FRAME_TRANSFER_CHARACTERISTICS", &g_out_transfer_characteristic);
read_value_uint32(g_config_file_fd, "TM_TYPE", &g_tm_type);
return 0;
}
static void
print_help()
{
printf("The app is used to test the hdr tm feature.\n");
printf("Cmd Usage: ./process_hdr_tm.cfg process_hdr_tm.cfg.cfg\n");
printf("The configure file process_hdr_tm.cfg is used to configure the para.\n");
printf("You can refer process_hdr_tm.cfg.template for each para meaning and create the configure file.\n");
}
int32_t main(int32_t argc, char *argv[])
{
VAStatus va_status;
uint32_t i;
if (argc != 2 || !strcmp(argv[1], "-h") || !strcmp(argv[1], "--help")){
print_help();
return -1;
}
/* Parse the configure file for video process*/
strncpy(g_config_file_name, argv[1], MAX_LEN);
g_config_file_name[MAX_LEN - 1] = '\0';
if (NULL == (g_config_file_fd = fopen(g_config_file_name, "r"))){
printf("Open configure file %s failed!\n",g_config_file_name);
assert(0);
}
/* Parse basic parameters */
if (parse_basic_parameters()){
printf("Parse parameters in configure file error\n");
assert(0);
}
va_status = vpp_context_create();
if (va_status != VA_STATUS_SUCCESS) {
printf("vpp context create failed \n");
assert(0);
}
/* Video frame fetch, process and store */
if (NULL == (g_src_file_fd = fopen(g_src_file_name, "r"))){
printf("Open SRC_FILE_NAME: %s failed, please specify it in config file: %s !\n",
g_src_file_name, g_config_file_name);
assert(0);
}
if (NULL == (g_dst_file_fd = fopen(g_dst_file_name, "w"))){
printf("Open DST_FILE_NAME: %s failed, please specify it in config file: %s !\n",
g_dst_file_name, g_config_file_name);
assert(0);
}
printf("\nStart to process, ...\n");
struct timespec Pre_time;
struct timespec Cur_time;
unsigned int duration = 0;
clock_gettime(CLOCK_MONOTONIC, &Pre_time);
for (i = 0; i < g_frame_count; i ++){
read_frame_to_surface(g_src_file_fd, g_in_surface_id);
video_frame_process(g_in_surface_id, g_out_surface_id);
write_surface_to_frame(g_dst_file_fd, g_out_surface_id);
}
clock_gettime(CLOCK_MONOTONIC, &Cur_time);
duration = (Cur_time.tv_sec - Pre_time.tv_sec) * 1000;
if (Cur_time.tv_nsec > Pre_time.tv_nsec) {
duration += (Cur_time.tv_nsec - Pre_time.tv_nsec) / 1000000;
} else {
duration += (Cur_time.tv_nsec + 1000000000 - Pre_time.tv_nsec) / 1000000 - 1000;
}
printf("Finish processing, performance: \n" );
printf("%d frames processed in: %d ms, ave time = %d ms\n",g_frame_count, duration, duration/g_frame_count);
if (g_src_file_fd) {
fclose(g_src_file_fd);
g_src_file_fd = NULL;
}
if (g_dst_file_fd) {
fclose(g_dst_file_fd);
g_dst_file_fd = NULL;
}
if (g_config_file_fd) {
fclose(g_config_file_fd);
g_config_file_fd = NULL;
}
vpp_context_destroy();
return 0;
}