static void pipe_right(t_node *tree, int *pipe_fd, t_data *data) { char *line; off_t offset; close(pipe_fd[1]); if (data->tmp_pipeout == -1) get_tmpfd(&data->tmp_pipeout, "/.temp_pipeout"); else { remove_tmp("/.temp_pipeout"); get_tmpfd(&data->tmp_pipeout, "/.temp_pipeout"); } while (get_next_line(pipe_fd[0], &line) > 0) { ft_putendl_fd(line, data->tmp_pipeout); ft_strdel(&line); } offset = lseek(data->tmp_pipeout, 0, SEEK_CUR); lseek(data->tmp_pipeout, 0, SEEK_SET); update_offset(&data, offset); read_tree(tree->right); remove_tmp("/.temp_pipeout"); if (g_pid.built == 0 || WEXITSTATUS(g_pid.id) != 0) exit(EXIT_FAILURE); else exit(EXIT_SUCCESS); }
int appf_runtime_init(void) { int ret,i; unsigned va, pa; struct appf_main_table* pmaintable = (struct appf_main_table*)reloc_addr((unsigned)&main_table); struct appf_cluster* pcluster; update_offset(); /* TODO: read U bit */ is_smp = FALSE; pa = reloc_addr((unsigned)&main_table); va = (unsigned)&main_table; if (pa == va) { __V(flat_mapped) = TRUE; } /* if (__V(flat_mapped) == 0 && use_smc == 0) { ret = 0; ret = appf_setup_translation_tables(); if (ret < 0) { return ret; } }*/ return appf_platform_runtime_init(); }
///need to create memory for this ui object too void ui_element::tick() { correct_bounds(*this); int r_id = hologram_manager::get_real_id(ref_id); hologram_manager::acquire(r_id); clEnqueueAcquireGLObjects(cl::cqueue, 1, &g_ui, 0, NULL, NULL); //cl::cqueue.finish(); cl_uint global[2] = {(cl_uint)w, (cl_uint)h}; cl_uint local[2] = {16, 8}; cl_float2 offset = {finish.x - w/2.0f, finish.y - h/2.0f}; compute::buffer coords = compute::buffer(cl::context, sizeof(cl_float2), CL_MEM_COPY_HOST_PTR, &offset); compute::buffer g_id = compute::buffer(cl::context, sizeof(cl_uint), CL_MEM_COPY_HOST_PTR, &id); arg_list id_arg_list; id_arg_list.push_back(&hologram_manager::g_tex_mem_base[r_id]); id_arg_list.push_back(&hologram_manager::g_tex_mem[r_id]); id_arg_list.push_back(&g_ui); id_arg_list.push_back(&coords); id_arg_list.push_back(&hologram_manager::g_id_bufs[r_id]); id_arg_list.push_back(&g_id); run_kernel_with_list(cl::blit_with_id, global, local, 2, id_arg_list, true); clEnqueueReleaseGLObjects(cl::cqueue, 1, &g_ui, 0, NULL, NULL); hologram_manager::release(r_id); update_offset(); //time.stop(); }
int Random::myrandom(int burst) { int randval = Random::randvals[offset] % burst; update_offset(); return randval; }
int appf_boottime_init(void) { /* Set up stack pointers per CPU, per cluster */ /* Discover devices, set up tables */ update_offset(); appf_platform_boottime_init(); *((unsigned*)reloc_addr((unsigned)&appf_runtime_call_flat_mapped)) = (unsigned)appf_runtime_call; *((unsigned*)reloc_addr((unsigned)&appf_device_memory_flat_mapped)) = reloc_addr((unsigned)appf_device_memory); appf_setup_translation_tables(); return 0; }
static gboolean knob_button_release_event(CcItem * knob, CcView * view, GdkEventButton* ev) { gdouble* offset = g_object_get_data(G_OBJECT(knob), "CccDemoKnobOffset"); if(knob == knobs[0] || knob == knobs[2]) { cc_circle_set_anchor(CC_CIRCLE(knob), ev->x + offset[0], ev->y + offset[1]); update_box(); } else { update_offset(ev->x, ev->y); } g_object_set_data(G_OBJECT(knob), "CccDemoKnobOffset", NULL); cc_view_ungrab_item(view, CC_ITEM(knob), ev->time); return TRUE; }
static gboolean knob_motion_notify_event(CcItem * knob, CcView * view, GdkEventMotion* ev) { gdouble* offset = g_object_get_data(G_OBJECT(knob), "CccDemoKnobOffset"); if(G_LIKELY(offset)) { if(knob == knobs[0] || knob == knobs[2]) { cc_circle_set_anchor(CC_CIRCLE(knob), ev->x + offset[0], ev->y + offset[1]); update_box(); } else { update_offset(ev->x, ev->y); } return TRUE; } return FALSE; }