2012-12-12 下载ndk编译出so和可执行文件,放到android 真机运行,包含源码。

一、下载ndk链接NDK 下载  |  Android NDK  |  Android Developers

二、解压ndk后得到下面的文件,里面包含ndk-build.cmd,这个是用来编译的。

2012-12-12 下载ndk编译出so和可执行文件,放到android 真机运行,包含源码。_第1张图片

三、Android.mk和C源码。完整源码下载路径https://download.csdn.net/download/qq_37858386/88622702

3.1 Android.mk

LOCAL_PATH := $(call my-dir)
include $(CLEAR_VARS)
LOCAL_MODULE    := libgiada
LOCAL_SRC_FILES := giada.c
LOCAL_LDLIBS += -llog 
LOCAL_LDLIBS +=-lm
LOCAL_HEADER_LIBRARIES := jni_headers
include $(BUILD_SHARED_LIBRARY)


include $(CLEAR_VARS)
LOCAL_MODULE    := test
LOCAL_SRC_FILES := test.c
LOCAL_LDLIBS += -llog 
LOCAL_LDLIBS +=-lm
LOCAL_HEADER_LIBRARIES := jni_headers
include $(BUILD_EXECUTABLE)

3.2 Application.mk

APP_ABI :=  armeabi-v7a arm64-v8a

3.3 test.c

/* DO NOT EDIT THIS FILE - it is machine generated */


#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 

void main()
{
	printf("Hello world\n");
}

3.4 giada.c

/* DO NOT EDIT THIS FILE - it is machine generated */


#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 
#include 

#include "giada.h"


#define CAMERA_INFO_STRUCT_CONTAIN_BYTES_LEN  0

struct image_meta
{
	char     fourcc[4];
	// crop info
	uint16_t left;
	uint16_t top;
	uint16_t width;
	uint16_t height;
	uint8_t  subsample;
	uint8_t  dummy;
	uint16_t dc;
	uint32_t exposure_us;	// 0~65535 ms
	uint16_t voltage_mv;	// 0~65535 mv
	uint16_t prehold_ms;	// ms
}__attribute__((packed));

struct cmd_header 
{
	uint16_t cmd;
	uint16_t ack;
	struct image_meta meta;
}__attribute__((packed));

struct sync_header
{
	uint8_t cmd;
	uint8_t ack;
    uint16_t len;
}__attribute__((packed));

struct file_content_header
{
    uint32_t magic;
    uint32_t len;
    int64_t  size;
    int64_t  off;
    char     path[256];
    uint8_t  content[0];
}__attribute__((packed));

#define CONTENT_LEN 0x10000
struct file_content
{
    uint32_t magic;
    uint32_t len;
    int64_t  size;
    int64_t  off;
    char     path[256];
    uint8_t  content[CONTENT_LEN];
}__attribute__((packed));

struct image_content_header
{
	uint32_t magic;
	uint8_t  type;	// PREVIEW, CAPTURE, & CONTINUOUS
    uint8_t  compress:1;
    uint8_t  dummy:7;
	uint16_t serial;	// continuous shoot
	uint32_t len;
    uint32_t  size;	// total size
    //int64_t  off;
    struct   image_meta meta;
    char     path[128];
    char     name[128];
}__attribute__((packed));

struct enum_header
{
	uint8_t  magic;
	uint8_t  cmd;
	uint8_t  ack;
	uint8_t serial;
	uint16_t len;
}__attribute__((packed));

struct thermal
{
    uint32_t soc;
    uint32_t near_sensor;
    uint32_t sensor;
};
struct camera_config
{
	char CamPartNum[16];
	char FPIPartNum[16];
	char SensorPartNum[16];
	uint16_t FPIMaxVoltage;
	uint16_t FPIMaxPreviewVoltage;;
	uint16_t FPIVoltageStep;
	uint16_t FPIStepSleep;
	uint16_t FPIMaxPrehold;
	uint16_t MaxExposure;
	uint16_t MaxWidth;
	uint16_t MaxHeight;
    uint16_t Transpose;
    uint16_t dummy;
    char     reserved[128];
}__attribute__((packed));

struct camera_info
{
    uint16_t width;
    uint16_t height;
    uint8_t  channel;
    uint8_t  bits_per_channel;
    uint8_t  bytes_per_channel;
    uint8_t  hw_version;
    uint16_t version;
    uint16_t cache_count;
    struct camera_config config;
    struct thermal thermal;
}__attribute__((packed));

struct capture_time
{
        int      frame_advanced;
        uint32_t set_expo_time;
        uint32_t set_volt_time;
        uint32_t volt_hold_time;
        uint32_t first_frame_time;
        uint32_t second_frame_time;
        uint64_t trig_start_time;
        uint64_t trig_timestamp;
        uint64_t frame_timestamp;
        uint64_t real_timestamp;
}__attribute__((packed));

struct voltage_step
{
    uint16_t step_mv;
    uint16_t sleep_ms;
}__attribute__((packed));

#define VERSIONS_LEN  255
struct camera_desc
{
    uint32_t ip;
    uint32_t client_ip;
    uint8_t  mac[6];
    char     ifname[18];
    char	 cam_name[32];
    struct   camera_config config;
    char     versions[VERSIONS_LEN];
    char     hw_version;
}__attribute__((packed));

struct session_header
{
    uint16_t id;
    uint16_t ack;
    uint32_t len;
}__attribute__((packed));

#define TAG "NETCAP-JNI"
#define LOGD(...) __android_log_print(ANDROID_LOG_DEBUG, TAG, __VA_ARGS__)
#define LOGI(...) __android_log_print(ANDROID_LOG_INFO, TAG, __VA_ARGS__)
#define LOGW(...) __android_log_print(ANDROID_LOG_WARN, TAG, __VA_ARGS__)
#define LOGE(...) __android_log_print(ANDROID_LOG_ERROR, TAG, __VA_ARGS__)
#define LOGF(...) __android_log_print(ANDROID_LOG_FATAL, TAG, __VA_ARGS__)


uint16_t  *des_image_ushort_buf;
uint8_t   *des_image_uchar_buf;

int32_t ItemCount;
struct continuous_shoot_element
{
        int voltage_mv;
        int prehold_ms;
        int exposure_us;
};
struct continuous_shoot_element *continuousItems;

uint16_t convert_u10_to_u8(uint8_t *dst, uint16_t *src, int w, int h)
{
    int i;
    uint64_t dc=0;
    uint16_t ret;

    for( i=0; i>2);
        dc += src[i];
    }
    ret = dc/(w*h);
    return ret;
}

void decompress_u16_u10_64_C(uint16_t *dest, uint8_t *src, int w, int h)
{
	int i, j, n;
	uint8_t  *src_upper = src + w*h;
	uint16_t tmp;

    uint16_t temp;
	for( i=0; i> (2*n)) & 0x3);
				dest[i + j + n*16] = src[i + j + n*16] | (tmp << 8);
			}
		}
		src_upper += 16;
	}
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1continuous_1data
  (JNIEnv *env, jobject obj,jbyteArray j_item_data,jbyteArray j_count_data,jint count,
                      jintArray j_voltage_mv,jintArray j_prehold_ms,jintArray j_exposure_us)
{
     int i = 0;
     ItemCount = count ;
     struct continuous_shoot_element m_continuousItems[ItemCount];

     uint32_t *voltage_buf = (*env)->GetIntArrayElements(env,j_voltage_mv,NULL);
     uint32_t *prehold_buf = (*env)->GetIntArrayElements(env,j_prehold_ms,NULL);
     uint32_t *exposure_buf = (*env)->GetIntArrayElements(env,j_exposure_us,NULL);

    #if 1
       for(i = 0;i < ItemCount; i++){

            m_continuousItems[i].voltage_mv  = voltage_buf[i];
            m_continuousItems[i].prehold_ms  = prehold_buf[i];
            m_continuousItems[i].exposure_us = exposure_buf[i];
            LOGI("[%s] m_continuousItems[%d].voltage_mv=%d,m_continuousItems[i].prehold_ms=%d,m_continuousItems[i].exposure_us=%d;\n",__func__,
                                       i,m_continuousItems[i].voltage_mv,m_continuousItems[i].prehold_ms,m_continuousItems[i].exposure_us);
       }
   	   LOGI("[%s] sizeof(ItemCount)=%d,ItemCount=%d;sizeof(struct continuous_shoot_element)=%d.\n",__func__,
   	                      sizeof(ItemCount),ItemCount,sizeof(struct continuous_shoot_element));

    #endif
    (*env)->SetByteArrayRegion(env, j_count_data, 0, sizeof(ItemCount), &ItemCount);
    (*env)->SetByteArrayRegion(env, j_item_data, 0, (sizeof(struct continuous_shoot_element)) * ItemCount, m_continuousItems);
    (*env)->ReleaseIntArrayElements(env,j_voltage_mv, voltage_buf, 0);
    (*env)->ReleaseIntArrayElements(env,j_prehold_ms, prehold_buf, 0);
    (*env)->ReleaseIntArrayElements(env,j_exposure_us, exposure_buf, 0);
    return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1rename_1content_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jbyteArray j_new_name)
{
    struct file_content m_file_content;
    jbyte   *byte_new_name = (*env)-> GetByteArrayElements(env,j_new_name, NULL);
    int     len_byte_new_name = (*env)-> GetArrayLength(env,j_new_name);
    memset(&m_file_content,0,sizeof(m_file_content));
    m_file_content.off = 0;
    m_file_content.size = len_byte_new_name;
    m_file_content.magic = 0xbeaffeed;
    strcpy(m_file_content.path, "camera-name");
    m_file_content.len = len_byte_new_name;

    #if 1
	   LOGI("[%s] sizeof(m_file_content)=%d,sizeof(struct file_content_header)=%d;len_byte_new_name=%d,new_name:%s;\n",__func__,sizeof(m_file_content),sizeof(struct file_content_header),len_byte_new_name,byte_new_name);
    #endif
    (*env)->GetByteArrayRegion(env,j_new_name, 0, m_file_content.len, m_file_content.content);
    (*env)->SetByteArrayRegion(env, byte_data, 0, sizeof(struct file_content_header) + m_file_content.len, &m_file_content);
    (*env)->ReleaseByteArrayElements(env,j_new_name, byte_new_name, 0);
	return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1sync_1header_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jint cmd,jint ack,jint len)
{
    struct sync_header m_sync_header;
    memset(&m_sync_header,0,sizeof(m_sync_header));
    m_sync_header.cmd = cmd;
    m_sync_header.ack = ack;
    m_sync_header.len = len;
    (*env)->SetByteArrayRegion(env, byte_data, 0, sizeof(m_sync_header), &m_sync_header);
    #if 1
	LOGI("[%s] sizeof(m_sync_header)=%d ,cmd=%d , ack=%d, len=%d;\n",__func__,sizeof(m_sync_header), cmd , ack, len);
    #endif
	return 0;
}


JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1camera_1desc
  (JNIEnv *env, jobject obj,jbyteArray src_data,jbyteArray cam_name,jbyteArray ip)
{
      struct camera_desc m_camera_desc;
  	  uint8_t *src_buf = (*env)->GetByteArrayElements(env,src_data,NULL);
      memset(&m_camera_desc,0,sizeof(m_camera_desc));
      memcpy(&m_camera_desc,src_buf + 6, sizeof(m_camera_desc));
      (*env)->SetByteArrayRegion(env, cam_name, 0, sizeof(m_camera_desc.cam_name), &m_camera_desc.cam_name);
      (*env)->SetByteArrayRegion(env, ip, 0, sizeof(m_camera_desc.ip), &m_camera_desc.ip);
      #if 0
  	  LOGI("[%s] sizeof(camera_desc)=%d,m_camera_desc.cam_name=%s,m_camera_desc.ip=0x%x,client_ip=0x%x\n",__func__,
  	                            sizeof(m_camera_desc),m_camera_desc.cam_name,m_camera_desc.ip,m_camera_desc.client_ip);
  	  LOGI("[%s] sizeof(m_camera_desc.cam_name)=%d,versions=%s,hw_version=%d\n",__func__,sizeof(m_camera_desc.cam_name),m_camera_desc.versions,m_camera_desc.hw_version);
      #endif
      (*env)->ReleaseByteArrayElements(env,src_data,src_buf,0);
  	  return 0;
}
JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1voltage_1step_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jint step_mv,jint sleep_ms)
{
    struct voltage_step m_voltage_step;
    m_voltage_step.step_mv = step_mv;
    m_voltage_step.sleep_ms = sleep_ms;
    (*env)->SetByteArrayRegion(env, byte_data, 0, sizeof(m_voltage_step), &m_voltage_step);
	LOGI("[%s] sizeof(voltage_step)=%d\n",__func__, sizeof(m_voltage_step));
	return 0;
}


JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1session_1header
  (JNIEnv *env, jobject obj,jbyteArray j_src_data,jintArray j_member_data)
{
    int id;
    int ack;
    int len;
    struct session_header m_session_header;
    uint8_t *src_data_buf = (*env)->GetByteArrayElements(env,j_src_data,NULL);

    memcpy(&m_session_header,src_data_buf, sizeof(m_session_header));
    id  = m_session_header.id;
    ack  = m_session_header.ack;
    len  = m_session_header.len;
    (*env)->SetIntArrayRegion(env, j_member_data, 0, 1, &id);
    (*env)->SetIntArrayRegion(env, j_member_data, 1, 1, &ack);
    (*env)->SetIntArrayRegion(env, j_member_data, 2, 1, &len);
#if 0
    LOGI("[%s] sizeof(struct session_header)=%d\n;id=%d,ack=%d,len=%d \n",__func__,
                sizeof(struct session_header),m_session_header.id,m_session_header.ack,m_session_header.len);
#endif
    (*env)->ReleaseByteArrayElements(env,j_src_data,src_data_buf,0);
	return sizeof(struct session_header);
}
JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcapturetimeandthermal_1data
  (JNIEnv *env, jobject obj,jbyteArray src_data,jintArray soc,jintArray near_sensor,jintArray sensor)
{
    struct thermal  m_thermal;
    struct capture_time m_capture_time;
    uint8_t *src_buf = (*env)->GetByteArrayElements(env,src_data,NULL);
    memset(&m_capture_time,0,sizeof(m_capture_time));
    memset(&m_thermal,0,sizeof(m_thermal));
    memcpy(&m_capture_time,src_buf, sizeof(m_capture_time));
    memcpy(&m_thermal,src_buf + sizeof(m_capture_time), sizeof(m_thermal));
    (*env)->SetIntArrayRegion(env, soc, 0, 1, &m_thermal.soc);
    (*env)->SetIntArrayRegion(env, near_sensor, 0, 1, &m_thermal.near_sensor);
    (*env)->SetIntArrayRegion(env, sensor, 0, 1, &m_thermal.sensor);
    #if 0
	LOGI("[%s] sizeof(m_capture_time)=%d ,sizeof(m_thermal)=%d,soc=%d,near_sensor=%d,sensor=%d\n",__func__,
	                 sizeof(m_capture_time),sizeof(m_thermal),m_thermal.soc,m_thermal.near_sensor,m_thermal.sensor);
    #endif
    (*env)->ReleaseByteArrayElements(env,src_data,src_buf,0);
	return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcommand_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jint cmd,jint left,jint top,jint width,jint height,
                                          jint prehold_ms,jint voltage_mv,jint exposure_us,jint ack,jshort subsample)
{
    struct cmd_header m_cmd_header;
    struct image_content_header  m_image_content_header;
    memset(&m_cmd_header,0,sizeof(m_cmd_header));
    m_cmd_header.cmd = cmd;
    m_cmd_header.meta.left = left;
    m_cmd_header.meta.top  = top;
    m_cmd_header.meta.width = width;
    m_cmd_header.meta.height = height;
    m_cmd_header.meta.prehold_ms = prehold_ms;
    m_cmd_header.meta.voltage_mv = voltage_mv;
    m_cmd_header.meta.exposure_us = exposure_us;
    m_cmd_header.ack = ack;
    m_cmd_header.meta.subsample = (uint8_t) subsample;

    (*env)->SetByteArrayRegion(env, byte_data, 0, sizeof(m_cmd_header), &m_cmd_header);
    #if 0
	LOGI("[%s] sizeof(m_cmd_header)=%d ,sizeof(m_image_content_header)=%d ,m_cmd_header.ack=%d,m_cmd_header.meta.subsample=%d;\n",__func__,
	                 sizeof(m_cmd_header),sizeof(m_image_content_header),m_cmd_header.ack, m_cmd_header.meta.subsample);
    #endif
	return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1enumheader_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jint magic,jint cmd,jint ack,jint serial,jint len)
{
    int m_len;
    struct enum_header m_enum_header;
    memset(&m_enum_header,0,sizeof(m_enum_header));
    m_enum_header.magic = magic;
    m_enum_header.cmd = cmd;
    m_enum_header.ack = ack;
    m_enum_header.serial = serial;
    m_enum_header.len  = len;

    (*env)->SetByteArrayRegion(env, byte_data, 0, sizeof(m_enum_header), &m_enum_header);
    m_len = sizeof(m_enum_header);
	//LOGI("[%s] sizeof(m_enum_header)=%d ;\n",__func__,m_len);
	return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcapture_1data
  (JNIEnv *env, jobject obj,jbyteArray des_data,jbyteArray src_data,jint width,jint height)
{
     uint8_t *image_buf = (*env)->GetByteArrayElements(env,src_data,NULL);
#if 0
     if(des_image_uchar_buf == NULL)
        des_image_uchar_buf = (uint8_t *)malloc(width * height);

     if(des_image_ushort_buf == NULL)
       des_image_ushort_buf = (uint16_t *)malloc(width * height);

     decompress_u16_u10_64_C(des_image_ushort_buf, image_buf,width, height);
     convert_u10_to_u8(des_image_uchar_buf, des_image_ushort_buf, width, height);
     (*env)->SetByteArrayRegion(env, des_data, 0, width * height, des_image_uchar_buf);
     LOGI("[%s]  m_width=%d,m_height=%d ",__func__,width,height);
#else
     if(des_image_ushort_buf == NULL)
       des_image_ushort_buf = (uint16_t *)malloc(width * height);

     decompress_u16_u10_64_C(des_image_ushort_buf, image_buf,width, height);
     (*env)->SetByteArrayRegion(env, des_data, 0, width * height * 2, des_image_ushort_buf);
     LOGI("[%s]  m_width=%d,m_height=%d ",__func__,width,height);
#endif
     (*env)->ReleaseByteArrayElements(env,src_data,image_buf,0);
     return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1bayer10_1to_1rgb888
     (JNIEnv *env, jobject obj,jbyteArray rgb_des,jintArray j_bayer_src,jint w,jint h,jint type)
{
    int i, j;
    uint16_t r, g, b;
    uint64_t dc=0;
    uint16_t ret;
    uint32_t *bayer = (*env)->GetIntArrayElements(env,j_bayer_src,NULL);
    uint8_t  *rgb   = (uint8_t *) malloc(w * h * 3);
    int ta,tb,tc,td;
    for(i=0;i>= 2;
            b >>= 2;
            r >>= 2;
            rgb[i*w*3 + j*3 + 2]=(uint8_t)(b);
            rgb[(i+1)*w*3 + j*3 + 2]=(uint8_t)(b);
            rgb[i*w*3 + (j+1)*3 + 2]=(uint8_t)(b);
            rgb[(i+1)*w*3 + (j+1)*3 + 2]=(uint8_t)(b);

            rgb[i*w*3 + j*3 + 1]=(uint8_t)(g);
            rgb[(i+1)*w*3 + j*3 + 1]=(uint8_t)(g);
            rgb[i*w*3 + (j+1)*3 + 1]=(uint8_t)(g);
            rgb[(i+1)*w*3 + (j+1)*3 + 1]=(uint8_t)(g);

            rgb[i*w*3 + j*3]=(uint8_t)(r);
            rgb[(i+1)*w*3 + j*3]=(uint8_t)(r);
            rgb[i*w*3 + (j+1)*3]=(uint8_t)(r);
            rgb[(i+1)*w*3 + (j+1)*3]=(uint8_t)(r);

            ta=i*w*3 + j*3 + 2;
            tb=(i+1)*w*3 + j*3 + 2;
            tc=i*w*3 + (j+1)*3 + 2;
            td=(i+1)*w*3 + (j+1)*3 + 2;
        }
    }
     ret = dc/(w*h);
     (*env)->SetByteArrayRegion(env, rgb_des, 0, w * h * 3, rgb);
     (*env)->ReleaseIntArrayElements(env,j_bayer_src,bayer,0);
    return ret;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1member_1contain_1bytes_1length
                      (JNIEnv *env, jobject obj, jint item)
{
    jint len = 0;
    switch( item )
    {
        case CAMERA_INFO_STRUCT_CONTAIN_BYTES_LEN:
             len = sizeof(struct camera_info);
        break;

        default :

        break;
    }
    #if 1
     LOGI("[%s]item = %d,len=%d;\n",__func__,item,len);
    #endif
    return len;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1camera_1info
  (JNIEnv *env, jobject obj,jbyteArray des_data,jbyteArray src_data,jshortArray width,jshortArray height,
          jbyteArray bits_per_channel,jbyteArray channel,jshortArray cache_count,jshortArray version,jshortArray max_value,
          jbyteArray j_sensorpartnum ,jbyteArray j_campartnum,jshortArray j_transpose)
{
     struct camera_info m_camera_info;
     uint8_t *src_data_buf = (*env)->GetByteArrayElements(env,src_data,NULL);
     memcpy(&m_camera_info,src_data_buf, sizeof(m_camera_info));

    (*env)->SetShortArrayRegion(env, width,  0, 1, &m_camera_info.width);
    (*env)->SetShortArrayRegion(env, height, 0, 1, &m_camera_info.height);
    (*env)->SetShortArrayRegion(env, version, 0, 1, &m_camera_info.version);
    (*env)->SetByteArrayRegion(env, bits_per_channel, 0, 1, &m_camera_info.bits_per_channel);
    (*env)->SetShortArrayRegion(env, cache_count, 0, 1, &m_camera_info.cache_count);
    (*env)->SetByteArrayRegion(env, channel, 0, 1, &m_camera_info.channel);
    (*env)->SetShortArrayRegion(env, max_value, 0, 1, &m_camera_info.config.FPIMaxPreviewVoltage);
    (*env)->SetShortArrayRegion(env, max_value, 1, 1, &m_camera_info.config.FPIMaxVoltage);
    (*env)->SetShortArrayRegion(env, max_value, 2, 1, &m_camera_info.config.MaxExposure);
    (*env)->SetShortArrayRegion(env, max_value, 3, 1, &m_camera_info.config.FPIMaxPrehold);
    (*env)->SetByteArrayRegion(env, j_sensorpartnum, 0, 16, m_camera_info.config.SensorPartNum);
    (*env)->SetByteArrayRegion(env, j_campartnum, 0, 16, m_camera_info.config.CamPartNum);
    (*env)->SetShortArrayRegion(env,j_transpose, 0, 1, &m_camera_info.config.Transpose);

    #if 0
     LOGI("[%s]sizeof(m_camera_info)=%d;width=%d;height=%d;version=%d\n",
    	                          __func__, sizeof(m_camera_info),m_camera_info.width,m_camera_info.height,m_camera_info.version);
     LOGI("[%s]m_camera_info.SensorPartNum=%s\n",
    	                          __func__, m_camera_info.config.SensorPartNum);
	 LOGI("[%s]FPIMaxPreviewVoltage=%d;FPIMaxVoltage=%d;MaxExposure=%d;FPIMaxPrehold=%d\n",
	                          __func__, m_camera_info.config.FPIMaxPreviewVoltage,m_camera_info.config.FPIMaxVoltage,
	                          m_camera_info.config.MaxExposure,m_camera_info.config.FPIMaxPrehold);
    #endif
     (*env)->ReleaseByteArrayElements(env,src_data,src_data_buf,0);
     return 0;
}

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1image_1content_1header_1data
  (JNIEnv *env, jobject obj,jbyteArray byte_data,jshortArray width,jshortArray height,jintArray size,jintArray serial,jshortArray subsample,jbyteArray type)
{
    struct image_content_header  m_image_content_header;
    unsigned char * pBuffer = (*env)->GetByteArrayElements(env,byte_data,NULL);
    uint16_t m_subsample ;
    uint32_t m_serial ;
	memcpy(&m_image_content_header,pBuffer, sizeof(m_image_content_header));
#if 0
    LOGI("[%s] strlenp Buffer=%d ",__func__,strlen(pBuffer));
	LOGI("[%s]sizeof(m_image_content_header)=%d,type=%d,width=%d,height=%d,size=%d,m_image_content_header.meta.serial=%d,m_image_content_header.subsample=%d,m_image_content_header.compress=%d \n",
	                          __func__, sizeof(m_image_content_header),m_image_content_header.type,
	                          m_image_content_header.meta.width,m_image_content_header.meta.height,
	                          m_image_content_header.size,m_image_content_header.serial,m_image_content_header.meta.subsample,
	                          m_image_content_header.compress);
#endif
    m_subsample = m_image_content_header.meta.subsample;
    m_serial = m_image_content_header.serial;
    (*env)->SetShortArrayRegion(env, width,  0, 1, &m_image_content_header.meta.width);
    (*env)->SetShortArrayRegion(env, height, 0, 1, &(m_image_content_header.meta.height));
    (*env)->SetIntArrayRegion(env, serial, 0, 1, &m_serial);
    (*env)->SetShortArrayRegion(env, subsample, 0, 1, &m_subsample);
    (*env)->SetIntArrayRegion(env, size, 0, 1, &(m_image_content_header.size));
    (*env)->SetByteArrayRegion(env, type, 0, 1, &(m_image_content_header.type));
    (*env)->ReleaseByteArrayElements(env,byte_data,pBuffer,0);
    /*
    jbyte* array= (*env)->GetByteArrayElements(env,jarray,&isCopy);
    (*env)->ReleaseByteArrayElements(env,jarray,array,0);
    */
	return 0;
}
#ifdef __cplusplus
}
#endif

3.5 giada.h

/* DO NOT EDIT THIS FILE - it is machine generated */
#include 
/* Header for class _Included_android_netcap_api */

#ifndef _Included_android_netcap_api
#define _Included_android_netcap_api
#ifdef __cplusplus
extern "C" {
#endif
const  int RGGB=0;
const  int BGGR=1;
const  int GRBG=2;
const  int GBRG=3;

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1rename_1content_1data
  (JNIEnv *, jobject ,jbyteArray ,jbyteArray );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1camera_1desc
  (JNIEnv *, jobject ,jbyteArray ,jbyteArray ,jbyteArray );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1voltage_1step_1data
  (JNIEnv *, jobject ,jbyteArray ,jint step_mv,jint );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcapturetimeandthermal_1data
  (JNIEnv *, jobject ,jbyteArray ,jintArray ,jintArray ,jintArray );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcommand_1data
	(JNIEnv *, jobject,jbyteArray, jint ,jint,jint, jint, jint, jint, jint, jint,jint,jshort);

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1enumheader_1data
  (JNIEnv *env, jobject ,jbyteArray ,jint ,jint ,jint ack,jint ,jint );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1image_1content_1header_1data
    (JNIEnv *, jobject,jbyteArray,jshortArray,jshortArray,jintArray ,jshortArray,jshortArray,jbyteArray type);

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1getcapture_1data
  (JNIEnv *, jobject ,jbyteArray ,jbyteArray ,jint ,jint );

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1camera_1info
  (JNIEnv *, jobject ,jbyteArray ,jbyteArray ,jshortArray ,jshortArray ,
                jbyteArray ,jbyteArray ,jshortArray ,jshortArray ,jshortArray ,jbyteArray,jbyteArray,jshortArray);
JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1member_1contain_1bytes_1length
  (JNIEnv *, jobject , jint );
JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1bayer10_1to_1rgb888
  (JNIEnv *, jobject ,jbyteArray,jintArray,jint,jint ,jint);

JNIEXPORT jint JNICALL Java_com_hypernano_netcap_Netcap_native_1get_1session_1header
  (JNIEnv *, jobject ,jbyteArray ,jintArray );
#ifdef __cplusplus
}
#endif
#endif

四、使用ndk-build.cmd编译C源码成so和可执行文件。

2012-12-12 下载ndk编译出so和可执行文件,放到android 真机运行,包含源码。_第2张图片

五、push到android 真机去运行

六、参考文章:

在Clion开发工具上使用NDK编译可以在安卓上执行的程序_clion ndk-CSDN博客

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