#include #include #include #include "uca.h" #include "uca-cam.h" #include "uca-grabber.h" #include "pco.h" #define GET_PCO(uca) ((struct pco_edge_t *)(uca->user)) #define set_void(p, type, value) { *((type *) p) = (type) value; } static uint32_t uca_pco_set_exposure(struct uca_camera_t *cam, uint32_t *exposure) { uint32_t e, d; if (pco_get_delay_exposure(GET_PCO(cam), &d, &e) != PCO_NOERROR) return UCA_ERR_PROP_GENERAL; if (pco_set_delay_exposure(GET_PCO(cam), d, *exposure) != PCO_NOERROR) return UCA_ERR_PROP_GENERAL; return UCA_NO_ERROR; } static uint32_t uca_pco_set_delay(struct uca_camera_t *cam, uint32_t *delay) { uint32_t e, d; if (pco_get_delay_exposure(GET_PCO(cam), &d, &e) != PCO_NOERROR) return UCA_ERR_PROP_GENERAL; if (pco_set_delay_exposure(GET_PCO(cam), *delay, e) != PCO_NOERROR) return UCA_ERR_PROP_GENERAL; return UCA_NO_ERROR; } static uint32_t uca_pco_destroy(struct uca_camera_t *cam) { pco_set_rec_state(GET_PCO(cam), 0); pco_destroy(GET_PCO(cam)); return UCA_NO_ERROR; } static uint32_t uca_pco_set_property(struct uca_camera_t *cam, enum uca_property_ids property, void *data) { struct uca_grabber_t *grabber = cam->grabber; switch (property) { case UCA_PROP_WIDTH: if (grabber->set_property(grabber, UCA_GRABBER_WIDTH, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_VALUE_OUT_OF_RANGE; cam->frame_width = *((uint32_t *) data); break; case UCA_PROP_HEIGHT: if (grabber->set_property(grabber, UCA_GRABBER_HEIGHT, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_VALUE_OUT_OF_RANGE; cam->frame_height = *((uint32_t *) data); break; case UCA_PROP_X_OFFSET: if (grabber->set_property(grabber, UCA_GRABBER_OFFSET_X, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_VALUE_OUT_OF_RANGE; break; case UCA_PROP_Y_OFFSET: if (grabber->set_property(grabber, UCA_GRABBER_OFFSET_Y, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_VALUE_OUT_OF_RANGE; break; case UCA_PROP_EXPOSURE: return uca_pco_set_exposure(cam, (uint32_t *) data); case UCA_PROP_DELAY: return uca_pco_set_delay(cam, (uint32_t *) data); case UCA_PROP_TIMESTAMP_MODE: return pco_set_timestamp_mode(GET_PCO(cam), *((uint16_t *) data)); default: return UCA_ERR_PROP_INVALID; } return UCA_NO_ERROR; } static uint32_t uca_pco_get_property(struct uca_camera_t *cam, enum uca_property_ids property, void *data, size_t num) { struct pco_edge_t *pco = GET_PCO(cam); struct uca_grabber_t *grabber = cam->grabber; switch (property) { case UCA_PROP_NAME: { /* FIXME: how to ensure, that buffer is large enough? */ SC2_Camera_Name_Response name; /* FIXME: This is _not_ a mistake. For some reason (which I * still have to figure out), it is sometimes not possible to * read the camera name... unless the same call precedes that * one.*/ pco_read_property(pco, GET_CAMERA_NAME, &name, sizeof(name)); pco_read_property(pco, GET_CAMERA_NAME, &name, sizeof(name)); strncpy((char *) data, name.szName, num); } break; case UCA_PROP_TEMPERATURE_SENSOR: { SC2_Temperature_Response temperature; if (pco_read_property(pco, GET_TEMPERATURE, &temperature, sizeof(temperature)) == PCO_NOERROR) set_void(data, uint32_t, temperature.sCCDtemp / 10); } break; case UCA_PROP_TEMPERATURE_CAMERA: { SC2_Temperature_Response temperature; if (pco_read_property(pco, GET_TEMPERATURE, &temperature, sizeof(temperature)) == PCO_NOERROR) set_void(data, uint32_t, temperature.sCamtemp); } break; case UCA_PROP_WIDTH: set_void(data, uint32_t, cam->frame_width); break; case UCA_PROP_WIDTH_MIN: set_void(data, uint32_t, 1); break; case UCA_PROP_WIDTH_MAX: set_void(data, uint32_t, pco->description.wMaxHorzResStdDESC); break; case UCA_PROP_HEIGHT: set_void(data, uint32_t, cam->frame_height); break; case UCA_PROP_HEIGHT_MIN: set_void(data, uint32_t, 1); break; case UCA_PROP_HEIGHT_MAX: set_void(data, uint32_t, pco->description.wMaxVertResStdDESC); break; case UCA_PROP_X_OFFSET: if (grabber->get_property(grabber, UCA_GRABBER_OFFSET_X, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_GENERAL; break; case UCA_PROP_Y_OFFSET: if (grabber->get_property(grabber, UCA_GRABBER_OFFSET_Y, (uint32_t *) data) != UCA_NO_ERROR) return UCA_ERR_PROP_GENERAL; break; case UCA_PROP_DELAY: { uint32_t exposure; if (pco_get_delay_exposure(pco, (uint32_t *) data, &exposure) != PCO_NOERROR) return UCA_ERR_PROP_INVALID; } break; case UCA_PROP_DELAY_MIN: set_void(data, uint32_t, pco->description.dwMinDelayDESC); break; case UCA_PROP_DELAY_MAX: set_void(data, uint32_t, pco->description.dwMaxDelayDESC); break; case UCA_PROP_EXPOSURE: { uint32_t delay; if (pco_get_delay_exposure(pco, &delay, (uint32_t *) data) != PCO_NOERROR) return UCA_ERR_PROP_INVALID; } break; case UCA_PROP_EXPOSURE_MIN: set_void(data, uint32_t, pco->description.dwMinExposureDESC); break; case UCA_PROP_EXPOSURE_MAX: set_void(data, uint32_t, pco->description.dwMaxExposureDESC); break; case UCA_PROP_BITDEPTH: set_void(data, uint32_t, 16); break; default: return UCA_ERR_PROP_INVALID; } return UCA_NO_ERROR; } uint32_t uca_pco_start_recording(struct uca_camera_t *cam) { struct pco_edge_t *pco = GET_PCO(cam); if (pco_arm_camera(pco) != PCO_NOERROR) return UCA_ERR_CAM_ARM; if (pco_set_rec_state(pco, 1) != PCO_NOERROR) return UCA_ERR_CAM_RECORD; return cam->grabber->acquire(cam->grabber, -1); } uint32_t uca_pco_stop_recording(struct uca_camera_t *cam) { if (pco_set_rec_state(GET_PCO(cam), 0) != PCO_NOERROR) return UCA_ERR_PROP_GENERAL; return UCA_NO_ERROR; } uint32_t uca_pco_grab(struct uca_camera_t *cam, char *buffer) { uint16_t *frame; uint32_t err = cam->grabber->grab(cam->grabber, (void **) &frame, &cam->current_frame); if (err != UCA_NO_ERROR) return err; /* FIXME: choose according to data format */ //pco_reorder_image_5x16((uint16_t *) buffer, frame, cam->frame_width, cam->frame_height); memcpy(buffer, frame, cam->frame_width*cam->frame_height*2); return UCA_NO_ERROR; } uint32_t uca_pco_init(struct uca_camera_t **cam, struct uca_grabber_t *grabber) { if (grabber == NULL) return UCA_ERR_CAM_NOT_FOUND; struct pco_edge_t *pco = pco_init(); if (pco == NULL) { return UCA_ERR_CAM_NOT_FOUND; } if ((pco->serial_ref == NULL) || !pco_is_active(pco)) { pco_destroy(pco); return UCA_ERR_CAM_NOT_FOUND; } struct uca_camera_t *uca = (struct uca_camera_t *) malloc(sizeof(struct uca_camera_t)); uca->user = pco; uca->grabber = grabber; uca->grabber->asynchronous = true; /* Camera found, set function pointers... */ uca->destroy = &uca_pco_destroy; uca->set_property = &uca_pco_set_property; uca->get_property = &uca_pco_get_property; uca->start_recording = &uca_pco_start_recording; uca->stop_recording = &uca_pco_stop_recording; uca->grab = &uca_pco_grab; /* Prepare camera for recording */ pco_set_scan_mode(pco, PCO_SCANMODE_SLOW); pco_set_rec_state(pco, 0); pco_set_timestamp_mode(pco, 2); pco_set_timebase(pco, 1, 1); pco_arm_camera(pco); /* Prepare frame grabber for recording */ int val = UCA_CL_8BIT_FULL_10; grabber->set_property(grabber, UCA_GRABBER_CAMERALINK_TYPE, &val); val = UCA_FORMAT_GRAY8; grabber->set_property(grabber, UCA_GRABBER_FORMAT, &val); val = UCA_TRIGGER_FREERUN; grabber->set_property(grabber, UCA_GRABBER_TRIGGER_MODE, &val); uint32_t width, height; pco_get_actual_size(pco, &width, &height); uca->frame_width = width; uca->frame_height = height; /* Yes, we really have to take an image twice as large because we set the * CameraLink interface to 8-bit 10 Taps, but are actually using 5x16 bits. */ width *= 2; grabber->set_property(grabber, UCA_GRABBER_WIDTH, &width); grabber->set_property(grabber, UCA_GRABBER_HEIGHT, &height); uca->state = UCA_CAM_CONFIGURABLE; *cam = uca; return UCA_NO_ERROR; }