Esempio n. 1
0
int main(int argc, char *argv[])
{
    FILE **fps;
    struct timespec start, end;
    double cpu_time1, cpu_time2;

    int threadnum = 10;
    /*
    	printf("Specify number of worker threads: ");
    	scanf("%d", &threadnum);
    */
    /* check file opening */
    int k;
    fps = (FILE **)malloc(threadnum * sizeof(FILE *));
    for(k = 0; k < threadnum; k++) {
        fps[k] = fopen(DICT_FILE, "r");
        if (fps[k] == NULL) {
            printf("cannot open the file\n");
            return -1;
        }
    }

    /* build the entry */
    entry *pHead, *e;
    pHead = (entry *) malloc(sizeof(entry));
    printf("size of entry : %lu bytes\n", sizeof(entry));
    e = pHead;
    e->pNext = NULL;

#if defined(__GNUC__)
    __builtin___clear_cache((char *) pHead, (char *) pHead + sizeof(entry));
#endif


    pthread_t *threads = (pthread_t *)malloc(threadnum * sizeof(pthread_t));
    thread_data **param = (thread_data **)malloc(threadnum * sizeof(thread_data *));

    for(int k=0; k < TABLE_SIZE; k++) {
        if (pthread_mutex_init(&locks[k], NULL) != 0) {
            printf("\n mutex init failed\n");
            return 1;
        }
    }

    clock_gettime(CLOCK_REALTIME, &start);

    int err;
    for(k = 0; k < threadnum; k++) {
        param[k] = pack_param(fps[k], k, threadnum);
        err = pthread_create(&threads[k], NULL, (void *) &thread_work, (void *) param[k]);
        if (err != 0)
            printf("\ncan't create thread :[%s]", strerror(err));
    }

    for(k = 0; k < threadnum; k++) {
        pthread_join(threads[k], NULL);
    }

    clock_gettime(CLOCK_REALTIME, &end);
    cpu_time1 = diff_in_second(start, end);

    /* close file as soon as possible */
    for(k = 0; k < threadnum; k++) {
        fclose(fps[k]);
    }

    for(int k=0; k < TABLE_SIZE; k++) {
        // printf("%d\n", hash_stats[k]);
        pthread_mutex_destroy(&locks[k]);
    }
    e = pHead;

    /* the givn last name to find */
    char input[MAX_LAST_NAME_SIZE] = "zyxel";
    e = pHead;

    assert(findName(input, e) &&
           "Did you implement findName() in " IMPL "?");
    assert(0 == strcmp(findName(input, e)->lastName, "zyxel"));

#if defined(__GNUC__)
    __builtin___clear_cache((char *) pHead, (char *) pHead + sizeof(entry));
#endif
    /* compute the execution time */
    clock_gettime(CLOCK_REALTIME, &start);
    findName(input, e);
    clock_gettime(CLOCK_REALTIME, &end);
    cpu_time2 = diff_in_second(start, end);

    FILE *output;
#if defined(OPT)
    output = fopen("opt.txt", "a");
#else
    output = fopen("orig.txt", "a");
#endif
    fprintf(output, "append() findName() %lf %lf\n", cpu_time1, cpu_time2);
    fclose(output);

    printf("execution time of append() : %lf sec\n", cpu_time1);
    printf("execution time of findName() : %lf sec\n", cpu_time2);

    if (pHead->pNext) free(pHead->pNext);
    free(pHead);

    return 0;
}
Esempio n. 2
0
int do_host_autok(int id)
{
    int i, j;
    int param_count;
    int vol_count;
    //std::list<unsigned int> undo_vol_list;
    struct autok_predata predata;
    unsigned int *param_list;
    unsigned int *vol_list;
    struct autok_predata full_data;
    std::list<struct res_data*> res_list;
    std::list<struct res_data*>::iterator it_res;
    struct res_data *p_res;
    char devnode[BUF_LEN]=""; 
    char resnode[BUF_LEN]="";
    char data_node[BUF_LEN]="";
    int need_to_recover = 0;
    param_count = get_param_count();
    
    printf("Param_count:%d\n", param_count);

    if(get_nvram_param_count(id)!=param_count){
        system("rm -rf /data/autok_*");
        system("rm -rf /data/nvram/APCFG/APRDCL/SDIO");
        close_nvram();
        init_autok_nvram();
        need_to_recover = 1;
    }
    //duplicate nvram data partition
    //if(!is_nvram_mode()){
        for(i=0; i<VCORE_NO; i++){
            //char nvram_node[BUF_LEN]="";
            //snprintf(nvram_node, BUF_LEN, "%s/%s_%d_%d", AUTOK_NVRAM_PATH, RESULT_FILE_PREFIX, id, g_autok_vcore[i]);
            snprintf(data_node, BUF_LEN, "%s/%s_%d_%d", AUTOK_RES_PATH, RESULT_FILE_PREFIX, id, g_autok_vcore[i]);
            // Check environment
            // 1. nvram data partition should exist
            // 2. autok parameter in data partion should not exist
            // 3. param_count should be the same 
            if(is_nvram_data_exist(id, g_autok_vcore[i])>0 && is_file_valid(data_node)<=0){
                //data_copy(nvram_node, data_node);
                int data_length;
                char *data_buf;
                read_from_nvram(id, g_autok_vcore[i], (unsigned char**)&data_buf, &data_length);
                if(write_to_file(data_node, data_buf, data_length)<0){
                    free(data_buf);
                    return -1;
                }
                free(data_buf);
                printf("duplicata from [%s] to [%s]\n", AUTOK_NVRAM_PATH, data_node);
            }
        }
    //}
    
    
    //check autok folder
    for(i=0; i<VCORE_NO; i++){
        // [FIXME] Normal mode & factory mode should store to different path
        snprintf(resnode, BUF_LEN, "%s/%s_%d_%d", AUTOK_RES_PATH, RESULT_FILE_PREFIX, id, g_autok_vcore[i]);
        printf("1-0 done\n");
        //if(!is_nvram_mode()){
            //std::string res_str(resnode);
            p_res = (struct res_data*)malloc(sizeof(struct res_data));
            p_res->id = id;
            p_res->voltage = g_autok_vcore[i];
            strcpy(p_res->filepath, resnode);
            res_list.push_back(p_res);
        //} 
        /*else {
            snprintf(resnode, BUF_LEN, "%s/%s_%d_%d", AUTOK_RES_PATH, RESULT_FILE_PREFIX, id, g_autok_vcore[i]);
            write_file_to_nvram(resnode, id);
            
        }*/
        struct timespec tstart={0,0}, tend={0,0};
        printf("1-1 done\n");
        if(is_file_valid(resnode)<=0){
            //undo_vol_list.push_back(g_autok_vcore[i]);
            set_stage1_voltage(id, g_autok_vcore[i]);
            set_stage1_done(id, 0);
            printf("[%s] set done to 0\n", resnode);
            // prepare zero data to drive autok algorithm 
            param_list = (unsigned int*)malloc(sizeof(unsigned int)*param_count);
            for(j=0; j<param_count; j++){
                param_list[j] = 0;        
            }
            vol_count = 1;            
            vol_list = (unsigned int*)malloc(sizeof(unsigned int)*vol_count); 
            vol_list[0] = g_autok_vcore[i];                  
            pack_param(&predata, vol_list, vol_count, param_list, param_count);
            clock_gettime(CLOCK_MONOTONIC, &tstart);
            set_stage1_params(id, &predata);
            
            printf("operation col_count[%d] vcore[%d] param_count[%d]\n", vol_count, vol_list[0], param_count);     
            release_predata(&predata);
            printf("release col_count[%d] param_count[%d]\n", vol_count, param_count); 
            // Wait for autok stage1 for a specific voltage done
            // [FIXME] can switch to uevent?
            while(1){
                if(get_stage1_done(id))
                    break;
                usleep(10*1000); 
            }
            clock_gettime(CLOCK_MONOTONIC, &tend);
            printf("autok once %.5f seconds\n",((double)tend.tv_sec + 1.0e-9*tend.tv_nsec) - ((double)tstart.tv_sec + 1.0e-9*tstart.tv_nsec));
            set_debug(0);
            snprintf(devnode, BUF_LEN, "%s/%d/%s", STAGE1_DEVNODE, id, "PARAMS");
            if(!is_nvram_mode()){
                printf("[NON_NV]From dev[%s] to res[%s]\n", devnode, resnode);
                from_dev_to_data(devnode, resnode);
                // For recover different version param_count
                if(need_to_recover){
                    write_dev_to_nvram(devnode, id);
                }
            } else {
                printf("[NV]From dev[%s] to nvram\n", devnode);
                from_dev_to_data(devnode, resnode);
                write_dev_to_nvram(devnode, id);
            }
        }
        printf("1-2 done\n");
    }
    
    // Set stage2 data to apply autok parameter
    //if(!is_nvram_mode()){
        // Merge Phase
        full_data.vol_count = VCORE_NO;
        full_data.param_count = param_count;
        full_data.vol_list = (unsigned int*)malloc(sizeof(unsigned int)*VCORE_NO);
        full_data.ai_data = (U_AUTOK_INTERFACE_DATA**)malloc(sizeof(U_AUTOK_INTERFACE_DATA*)*VCORE_NO);
        i = 0;
        for(it_res=res_list.begin(); it_res!=res_list.end(); ++it_res){
            full_data.ai_data[i] = (U_AUTOK_INTERFACE_DATA*)malloc(sizeof(U_AUTOK_INTERFACE_DATA)*param_count);
            struct res_data *p_temp_res = *it_res;
            predata = get_param((char*)p_temp_res->filepath);
            full_data.vol_list[i] = p_temp_res->voltage;
            memcpy(full_data.ai_data[i], predata.ai_data[0], sizeof(U_AUTOK_INTERFACE_DATA)*param_count);
            release_predata(&predata);
            free(p_temp_res);
            i++;
        }
        printf("1-3 done\n");
        set_stage2(id, &full_data);
        release_predata(&full_data);
        printf("1-4 done\n");
    /*}else{
        set_ready(id);
    }*/
    return 0;
}