#include #include #include #include #include #include "uca.h" #include "uca-grabber.h" struct fg_apc_data { Fg_Struct *fg; dma_mem *mem; uint32_t timeout; /* End-user related callback variables */ uca_cam_grab_callback callback; void *meta_data; void *user; }; struct uca_sisofg_map_t { enum uca_grabber_constants uca_prop; int fg_id; bool interpret_data; /**< is data a constant or a value? */ }; static struct uca_sisofg_map_t uca_to_fg[] = { /* properties */ { UCA_PROP_WIDTH, FG_WIDTH, false }, { UCA_PROP_HEIGHT, FG_HEIGHT, false }, { UCA_PROP_X_OFFSET, FG_XOFFSET, false }, { UCA_PROP_Y_OFFSET, FG_YOFFSET, false }, { UCA_PROP_EXPOSURE, FG_EXPOSURE, false }, { UCA_PROP_GRAB_TIMEOUT, FG_TIMEOUT, false }, { UCA_GRABBER_TRIGGER_MODE, FG_TRIGGERMODE, true}, { UCA_GRABBER_FORMAT, FG_FORMAT, true}, { UCA_GRABBER_CAMERALINK_TYPE, FG_CAMERA_LINK_CAMTYP, true }, /* values */ { UCA_FORMAT_GRAY8, FG_GRAY, false }, { UCA_FORMAT_GRAY16, FG_GRAY16, false }, { UCA_CL_8BIT_FULL_8, FG_CL_8BIT_FULL_8, false }, { UCA_CL_8BIT_FULL_10, FG_CL_8BIT_FULL_10, false }, { UCA_TRIGGER_FREERUN, FREE_RUN, false }, { UCA_GRABBER_INVALID, 0, false } }; #define GET_FG(grabber) (((struct fg_apc_data *) grabber->user)->fg) #define GET_MEM(grabber) (((struct fg_apc_data *) grabber->user)->mem) uint32_t uca_me4_destroy(struct uca_grabber *grabber) { if (grabber != NULL) { Fg_FreeMemEx(GET_FG(grabber), GET_MEM(grabber)); Fg_FreeGrabber(GET_FG(grabber)); } return UCA_NO_ERROR; } static struct uca_sisofg_map_t *uca_me4_find_property(enum uca_grabber_constants property) { int i = 0; /* Find a valid frame grabber id for the property */ while (uca_to_fg[i].uca_prop != UCA_GRABBER_INVALID) { if (uca_to_fg[i].uca_prop == property) return &uca_to_fg[i]; i++; } return NULL; } uint32_t uca_me4_set_property(struct uca_grabber *grabber, int32_t property, void *data) { /* Handle all properties not related specifically to the me4 */ union uca_value *v = (union uca_value *) data; switch (property) { case UCA_PROP_GRAB_TIMEOUT: ((struct fg_apc_data *) grabber->user)->timeout = v->u32; break; case UCA_PROP_GRAB_SYNCHRONOUS: grabber->synchronous = v->u32 != 0; return UCA_NO_ERROR; default: break; } /* Try to find a matching me4 property */ uint32_t err = UCA_ERR_GRABBER | UCA_ERR_PROP; struct uca_sisofg_map_t *fg_prop = uca_me4_find_property(property); if (fg_prop == NULL) return err | UCA_ERR_INVALID; if (fg_prop->interpret_data) { /* Data is not a value but a SiSo specific constant that we need to * translate to Silicon Software speak. Therefore, we try to find it in * the map. */ struct uca_sisofg_map_t *constant = uca_me4_find_property(*((uint32_t *) data)); if (constant != NULL) return Fg_setParameter(GET_FG(grabber), fg_prop->fg_id, &constant->fg_id, PORT_A) == FG_OK ? \ UCA_NO_ERROR : err | UCA_ERR_INVALID; return err | UCA_ERR_INVALID; } else return Fg_setParameter(GET_FG(grabber), fg_prop->fg_id, data, PORT_A) == FG_OK ? \ UCA_NO_ERROR : err | UCA_ERR_INVALID; } uint32_t uca_me4_get_property(struct uca_grabber *grabber, int32_t property, void *data) { switch (property) { case UCA_PROP_GRAB_SYNCHRONOUS: *((uint32_t *) data) = grabber->synchronous ? 1 : 0; return UCA_NO_ERROR; default: break; } uint32_t err = UCA_ERR_GRABBER | UCA_ERR_PROP; struct uca_sisofg_map_t *fg_prop = uca_me4_find_property(property); if (fg_prop == NULL) return err | UCA_ERR_INVALID; /* FIXME: translate data back to UCA_ normalized constants */ return Fg_getParameter(GET_FG(grabber), fg_prop->fg_id, data, PORT_A) == FG_OK ? \ UCA_NO_ERROR : err | UCA_ERR_INVALID; } uint32_t uca_me4_alloc(struct uca_grabber *grabber, uint32_t pixel_size, uint32_t n_buffers) { dma_mem *mem = GET_MEM(grabber); /* If buffers are already allocated, we are freeing every buffer and start * again. */ if (mem != NULL) Fg_FreeMemEx(GET_FG(grabber), mem); uint32_t width, height; uca_me4_get_property(grabber, UCA_PROP_WIDTH, &width); uca_me4_get_property(grabber, UCA_PROP_HEIGHT, &height); mem = Fg_AllocMemEx(GET_FG(grabber), n_buffers*width*height*pixel_size, n_buffers); if (mem != NULL) { ((struct fg_apc_data *) grabber->user)->mem = mem; return UCA_NO_ERROR; } return UCA_ERR_GRABBER | UCA_ERR_NO_MEMORY; } uint32_t uca_me4_acquire(struct uca_grabber *grabber, int32_t n_frames) { if (GET_MEM(grabber) == NULL) return UCA_ERR_GRABBER | UCA_ERR_NO_MEMORY; n_frames = n_frames < 0 ? GRAB_INFINITE : n_frames; if (Fg_AcquireEx(GET_FG(grabber), 0, n_frames, ACQ_STANDARD, GET_MEM(grabber)) == FG_OK) return UCA_NO_ERROR; return UCA_ERR_GRABBER | UCA_ERR_ACQUIRE; } uint32_t uca_me4_stop_acquire(struct uca_grabber *grabber) { if (GET_MEM(grabber) != NULL) if (Fg_stopAcquireEx(GET_FG(grabber), 0, GET_MEM(grabber), STOP_SYNC) != FG_OK) return UCA_ERR_GRABBER | UCA_ERR_ACQUIRE; return UCA_NO_ERROR; } uint32_t uca_me4_grab(struct uca_grabber *grabber, void **buffer, uint64_t *frame_number) { static frameindex_t last_frame = 0; struct fg_apc_data *me4 = (struct fg_apc_data *) grabber->user; if (grabber->synchronous) last_frame = Fg_getLastPicNumberBlockingEx(me4->fg, last_frame+1, PORT_A, me4->timeout, me4->mem); else last_frame = Fg_getLastPicNumberEx(me4->fg, PORT_A, me4->mem); if (last_frame <= 0) return UCA_ERR_GRABBER | UCA_ERR_FRAME_TRANSFER; *frame_number = (uint64_t) last_frame; *buffer = Fg_getImagePtrEx(me4->fg, last_frame, PORT_A, me4->mem); return UCA_NO_ERROR; } static int uca_me4_callback(frameindex_t frame, struct fg_apc_data *apc) { apc->callback(frame, Fg_getImagePtrEx(apc->fg, frame, PORT_A, apc->mem), apc->meta_data, apc->user); return 0; } uint32_t uca_me4_register_callback(struct uca_grabber *grabber, uca_cam_grab_callback callback, void *meta_data, void *user) { if (grabber->callback == NULL) { grabber->callback = callback; struct fg_apc_data *apc_data = (struct fg_apc_data *) grabber->user; apc_data->callback = callback; apc_data->meta_data = meta_data; apc_data->user = user; struct FgApcControl ctrl; ctrl.version = 0; ctrl.data = (struct fg_apc_data *) grabber->user; ctrl.func = &uca_me4_callback; ctrl.flags = FG_APC_DEFAULTS; ctrl.timeout = 1; if (Fg_registerApcHandler(GET_FG(grabber), PORT_A, &ctrl, FG_APC_CONTROL_BASIC) != FG_OK) return UCA_ERR_GRABBER | UCA_ERR_CALLBACK; } else return UCA_ERR_GRABBER | UCA_ERR_CALLBACK; return UCA_NO_ERROR; } uint32_t uca_me4_init(struct uca_grabber **grabber) { Fg_Struct *fg = Fg_Init("libFullAreaGray8.so", 0); if (fg == NULL) return UCA_ERR_GRABBER | UCA_ERR_NOT_FOUND; struct uca_grabber *uca = (struct uca_grabber *) malloc(sizeof(struct uca_grabber)); memset(uca, 0, sizeof(struct uca_grabber)); struct fg_apc_data *me4 = (struct fg_apc_data *) malloc(sizeof(struct fg_apc_data)); memset(me4, 0, sizeof(struct fg_apc_data)); me4->fg = fg; Fg_getParameter(fg, FG_TIMEOUT, &me4->timeout, PORT_A); uca->user = me4; uca->destroy = &uca_me4_destroy; uca->set_property = &uca_me4_set_property; uca->get_property = &uca_me4_get_property; uca->alloc = &uca_me4_alloc; uca->acquire = &uca_me4_acquire; uca->stop_acquire = &uca_me4_stop_acquire; uca->grab = &uca_me4_grab; uca->register_callback = &uca_me4_register_callback; *grabber = uca; return UCA_NO_ERROR; }