2.1. Hardware objects

Hardware objects are self-contained pieces of software code which link graphical bricks (§2.2) to the underlying instrumentation control software. Their purpose is to provide a way for an application's graphical widgets to interact with an instrument (e.g. sample changer) or motor (e.g. monochromator rotation axis). It is common for one hardware object to interact with more than one piece of underlying control software in order to implement a workflow which uses multiple hardware components or procedures. The BlissFramework provides the methods for creating hardware objects which are configured using eXtensible Markup Language (XML) files loaded through a server. Only one instance of a hardware object runs for a given piece of instrumentation and this instance is available to handle requests made by other hardware objects or bricks. A hardware object provides a Python application programming interface (API) and handles asynchronous communication between other hardware objects or bricks by emitting signals.

2.2. Bricks

Bricks are the individual graphical objects used to make up the GUI seen by a user. They are normally connected to hardware objects in order to allow the display of information and motor control. There are no restricted relationships: one hardware object can have multiple bricks as graphical views (each brick with a different purpose) or a single brick can interact with several hardware objects. Bricks are made configurable by defining properties which are set using the application builder (§2.3). The connection of a brick to a hardware object is configured via a series of properties. This mechanism makes it easy to change the application's configuration after deployment. Bricks also communicate with each other using mechanisms defined in the brick's code file and set with the application builder. This approach was chosen to encourage the creation of small function-specific bricks rather than large multi-functional monolithic bricks that are much harder to maintain and develop. The developer then creates a data flow by connecting these smaller bricks together.

2.3. Application builder

The application builder is a graphical editor developed to create a beamline control GUI and can be launched in `run' or `design' modes. In the former, the application is executed as defined in its configuration file. If launched in design mode, extra windows are displayed that allow the GUI to be modified: bricks can be added or removed, their connections modified and some characteristics of the appearance changed. Linking the run and design modes in this fashion allows for the rapid development and testing of new functionality and GUI layouts.

2.4. Hardware repository server

Underlying all the components of the BlissFramework is the Hardware Repository Server which contains all the configuration information necessary for a hardware object to operate a physical device. By creating a shared configuration pool, multiple BlissFramework applications, for example an instance of MxCuBE running in the experiment control cabin and a stripped-down version running in the experimental hutch, can interact with identical hardware objects as both access the same hardware repository. Communication with a hardware repository server is via sockets over which a filename argument (corresponding to the XML configuration of a hardware object) is sent and the contents of that file returned.

3.1. The Hutch tab

The Hutch tab (Fig. 2) provides access to the functionality necessary for preparing an experiment. The motors that are most commonly used in establishing the experimental configuration have dedicated bricks, with their status being indicated through the use of a colour-coded scheme: green for normal, yellow for moving, red for alarm, and grey for disabled.

A number of higher-level beamline control operations are also provided by bricks in the Hutch tab. `Quick realign' triggers the alignment of optics and/or experimental hutch components and ensures that the X-ray beam delivered to the sample is optimized for intensity at the current working energy. The particular sequence of events instigated is specific to the beamline where the instance of MxCuBE is running. When required, and once a scintillator crystal has been placed at the sample position, `Centre beam' uses a peak-finding algorithm built into the video server to locate the centre of the X-ray beam and move the experimental table and slits such that sample position and beam intersect.

To view and align samples the Hutch tab displays a video feed showing the sample position. Two different methods of sample alignment are available: 3-click and automatic. In the 3-click option the sample is rotated in φ by 3 × 90°, the crystal centre identified via a mouse click after each 90° rotation and the motor movements required to place the sample in the X-ray beam calculated and implemented. Fully automatic crystal centring is achieved using image-processing algorithms in C3D (Lavault et al., 2006). After both 3-click and auto-centring, a manual approval or rejection of the result is available. Upon acceptance, four snapshot images are taken, each separated by 90° in φ. These images are transferred to an archive and made accessible via the ISPyB database (Beteva et al., 2006).

Other general features available via Hutch tab bricks include: changing the size and intensity of the X-ray beam incident on the sample (the `slit' and `transmission' bricks), automatic annealing of the sample currently mounted (Giraud et al., 2009), opening and closing of beamline shutters (for beam visualization on scintillator crystals) and in/out positioning of the beamstop (fine alignment of the beamstop is available in `Expert' mode). The motor positions of the add-on mini-kappa goniometer head (McCarthy et al., 2009) are also monitored and controlled using the Hutch tab. For diffractometers (i.e. MD2; Cusack et al., 1998) where the size of the X-ray beam incident on the sample can be modified using apertures, these can also be inserted and removed via a brick in this tab.

3.2. The Collect tab

The Collect tab (Fig. 3a) is perhaps the most important aspect of the MxCuBE GUI as both sample selection and data collection are performed from within this interface. Here, simple features ease beamline use. On tunable beamlines the operating energy can be specified either in energy (keV) or wavelength (Å) according to the experimenter's preference. The diffraction geometry can be defined by either sample-to-detector distance, by a desired diffraction resolution (calculated using the minimum dimension of the detector) or automatically generated from the diffraction properties of the sample (DNA tab, §3.4).

Figure 3 (a) The Collect tab of the MxCuBE GUI. The sample area in the top portion of the GUI shows information contained in the ISPyB LIMS (sample name, protein acronym, barcode, space group, unit-cell dimensions etc.) for the samples contained in the SC3 sample changer. (b) The sample-changer brick embedded in the Collect tab. The two-dimensional barcodes of the SPINE standard pins contained in the SC3 are read by clicking `scan selected baskets'. The sample currently mounted is flagged in both the sample changer brick and in the sample area (shown in bold green). In this figure MAD/SAD data collection (see text) is not activated.

Other data collection parameters (φ_start, Δφ, exposure time, number of images) can be entered into the tab manually or by running DNA (§3.4). Before a data collection can start, these values are validated by a SPEC macro to ensure consistency with instrument capabilities. In the case of invalid collection parameters a dialogue box explaining the conflict, and preventing data collection, appears. If the collection parameters are valid, a confirmation dialogue box pops up, previewing the filenames of the oscillation images to be collected and highlighting the names of files that already exist.

For MAD or SAD experiments, X-ray energies for the collection of peak (), inflection point () and remote data sets are received from the `Energy Scan' tab (see §3.3) after an absorption-edge scan is carried out. The number, energy and order of datasets to be collected are then confirmed in the Collect tab. Datasets are collected in the order defined and diffraction images are stored in sub-directories named, by default, according to the corresponding dataset energy. These sub-directory names are also user-configurable. A further option allowing inverse-beam data collection is available; this is done by checking the appropriate box and specifying the angular range of the wedges to be collected at φ and φ + 180°.

An important feature is the concept of queued data collection. Here, instead of initiating data collection directly, the parameters are stored for future use. This allows both for the implementation of multi-sweep data collection strategies and for complete datasets to be built up from multiple partial datasets collected at different positions within a crystal. For the latter option, various positions in the crystal are defined using the 3-click centring option (§3.1). After each centring operation, data collection parameters are entered into the queue. On launching the data collection, each partial data set is collected, in its turn, from the position in the crystal previously defined and stored by MxCuBE.

The option of `helical' data collection (Flot et al., 2010), particularly powerful when crystals are much larger than the incident X-ray beam size, is activated and controlled via a series of SPEC commands. Start and end positions are chosen by clicking on points on the crystal in the viewing brick in the Hutch tab and data collection is then initiated as normal. During a helical data collection the crystal is automatically translated between the two pre-defined points so as to gradually move a fresh part of the crystal into the X-ray beam. The time that each point spends in the X-ray beam is calculated automatically as a function of the distance between the two user-defined positions and the total rotation angle required during the data collection. The amount of data collected from each point is therefore constant. With helical data collection the X-ray dose received by the crystal is evenly distributed over the whole of the crystal segment chosen, rather than focused on one particular position; therefore longer exposure times per image are possible before radiation damage occurs. When helical data collection is activated, an information/warning message is displayed to users before data collection starts.

A basic `Image' tab in MxCuBE (not described here) allows the display and inspection of individual diffraction images. However, this functionality is currently almost invariably carried out by launching the much more feature-rich ADXV image-viewing software (Area Detector Systems Corporation; Szebenyi et al., 1997; https://www.scripps.edu/~arvai/adxv.html ) on the beamline control computer. Such is the speed of data collection on modern synchrotron-based MX resources that, even using ADXV, detailed inspection of diffraction images is performed, in the majority of cases, only pre- and post-data-collection. This being the case, emphasis in MxCuBE has turned to the provision of tools (see §3.4, the DNA tab) that allow the rapid determination of crystal diffraction characteristics, the calculation and execution of data collection strategies and the on-line integration and analysis of the resulting intensity data, the latter producing a better idea of diffraction data quality than any visual inspection of diffraction images, no matter what software is used.

The Collect tab is also used to control the SC3 sample changers (Cipriani et al., 2006) installed on the ESRF's MX beamlines (Fig. 3b). In addition to loading/unloading operations, features are incorporated for the scanning and display of the barcodes of samples currently in the sample changer. These barcodes form an integral part of the SPINE standard (Cipriani et al., 2006) to which sample holders must conform if the SC3 is being used. Barcodes are displayed, along with sample information and sample changer position, in the sample area of both the Collect and DNA tabs. Mounting/unmounting of samples can be initiated either by clicking on a particular sample in the sample list, choosing sample changer position in the boxes provided or by clicking on a sample changer position in the matrix that is also provided in the tab. Icons in the matrix display the status of all sample changer positions, which are: sample present and barcode read or supplied via ISPyB (barcode icon); sample present but barcode not read or not supplied (filled white circle); no sample present (empty circle); unknown (question mark). When a sample is loaded a pin icon appears at the relevant position in the matrix and the relevant sample is highlighted in the sample list.

3.3. Energy scans and X-ray fluorescence spectra

Absorption-edge or XANES (X-ray absorption near-edge structure) scans are performed in the Energy Scan tab (Fig. 4); the user can choose which edge to scan (for L edges the L_III edge only is available) by selecting the desired element from the periodic table displayed (only elements for which an absorption edge is accessible are highlighted). All raw data, plot and results files produced are stored under the chosen directory and with a common filename prefix, which is also entered in this tab.

Figure 4 Absorption-edge scans in MxCuBE. (a) A scan is launched by clicking on an element in the periodic table in the `Energy scans' tab. (b) Following a scan, the spectrum is analysed using CHOOCH (Evans & Pettifer, 2001), plots of f′ and f′′ against photon energy displayed and energies for the collection of peak, inflection point and remote wavelengths suggested. (c) Accepting the suggestions for the energies at which data are to be collected activates MAD/SAD data collection in the Collect tab. Here, the number and order of collection of datasets can be defined.

Scans are performed according to principles established empirically (Arzt et al., 2005). The resulting spectrum is analysed using CHOOCH (Evans & Pettifer, 2001) and plots of f′ and f′′ against energy are displayed. Energies for the collection of inflection point, peak and remote data sets are also presented (the latter is by default taken as 50 eV above the energy of the peak of the absorption edge). Accepting one or more of these energies activates the multi-wavelength data collection mode in the Collect tab (§3.2). At the end of the XANES scan procedure, the raw data file and the CHOOCH-transformed spectrum are archived and referenced in the ISPyB database.

The collection and analysis of X-ray fluorescence (XRF) spectra is available via the `XRF Spectrum' tab (Leonard et al., 2009; Fig. 5). To perform the analysis a directory, filename prefix and measurement time are selected before clicking on the `Start spectrum' button. The resulting fluorescence spectrum is displayed along with an analysis of the elements contributing to the spectrum. At the end of the procedure, both the XRF spectrum and an html report (summarizing the elements for which emission lines are identified) are archived and made available in ISPyB.

Figure 5 Analysis of X-ray-induced fluorescence (XRF) spectra in MxCuBE. (a) The spectrum from a crystal (see Fig. 2) of a selenomethionyl derivative of the feruloyl esterase module of xylanase 10B from Clostridium thermocellum (Tarbouriech et al., 2005). The displayed spectrum is truncated so that peaks owing to Compton and Rayleigh scattering by the sample of the incident X-ray beam are not shown. Clicking on a peak in the spectrum allows identification of elements via a pop-up window. (b) The XRF spectrum from a crystal of thermolysin from Bacillus thermoproteolyticus (Mueller-Dieckmann et al., 2007) showing the presence of chloride (Kα emission line, ∼2.6 keV), potassium (Kα, Kβ emission lines, ∼3.7 keV and ∼4.0 keV, respectively) and zinc (Kα, Kβ emission lines, ∼8.6 keV and ∼9.6 keV, respectively). The peak at ∼12.2 keV is due to Compton scattering by the sample of the incident X-ray beam. The Kα emission line of sulfur (∼2.3 keV) is also visible in this spectrum.

3.4. The DNA tab

The DNA system for automated sample evaluation and data collection (Leslie et al., 2002) is a key part of the options offered to users of the ESRF MX beamlines. As DNA has its own GUI we have implemented two methods of interaction with MxCuBE. The first of these is via the DNA GUI (Leslie et al., 2002). In the second, the DNA server is controlled directly from MxCuBE.

When using the DNA GUI the determination of sample changer contents (i.e. barcode scanning) and the subsequent extraction of sample information from ISPyB can be initiated from either the DNA GUI itself or from MxCuBE (§3.2). This information is then displayed in both the MxCuBE and the DNA GUIs. Two modes of operation are then possible. In a so-called `single shot' mode individual samples are loaded and centred using MxCuBE (see above). Sample evaluation, including calculation of a data collection strategy, is then performed as described previously (Leslie et al., 2002) and, if desired, data automatically collected. The on-line integration of diffraction images and analysis of the resulting intensity data, using MOSFLM (Leslie, 1992) and SCALA (Evans, 2006), respectively, is also available. In this mode MxCuBE acts as a slave to DNA. Data collection is controlled from the DNA application and MxCuBE acts as a server, communicating with DNA using XML-encoded messages through http. The data collection pipeline (DCP) mode of DNA allows multiple samples to be selected for evaluation and strategy calculation (Beteva et al., 2006). In both single-shot and DCP modes the results of the DNA characterization are stored in ISPyB.

The use of multiple control interfaces causes confusion to infrequent users. Therefore, an interface to the DNA Expert System was developed and integrated into MxCuBE. This interface has its own tab (Fig. 6) and allows use of DNA in single-shot mode only. It is possible to execute a single action (i.e. taking reference images, indexing reference images, calculating a strategy, collecting/integrating/analysing a data set) or to chain several actions together. A sub-tab allows access to the html output provided by DNA including the results of auto-indexing, test image integration and data collection strategy calculation using BEST (Bourenkov & Popov, 2006). These results are also stored in, and accessible via, ISPyB.

Figure 6 The DNA tab of the MxCuBE GUI. As in the Collect tab (Fig. 3) the sample area in the top part of the GUI shows information contained in the ISPyB LIMS (sample name, protein acronym, barcode, space group, unit-cell dimensions etc.) for the samples contained in the SC3 sample changer. Checkboxes are used to choose which tasks are to be carried out. Following successful characterization, unit-cell parameters and crystal point group are shown in the `current results' brick. The data collection strategy calculated using BEST is displayed both in this brick and in the task area of the tab. Individual or a sequential series of tasks are carried out by clicking on `DNA execute steps'.

3.5. MxCuBE features for remote access

As is the case at the SSRL MX facilities (González et al., 2005) and as described elsewhere (Gabadinho et al., 2008), the NoMachine NX software (https://www.nomachine.com/ ) was chosen to support remote access at the ESRF's MX beamlines. This allows remote users to connect to a ESRF firewall computer from where they can connect and log in to the relevant beamline control computer and start MxCuBE and other beamline applications. These applications are displayed on the user's local workstation from where the remote user can, when given permission, control the beamline.

A major concern when developing remote access was the requirement that users at the beamline and users elsewhere must be aware of each other and be able to communicate with each other. This implies several instances of MxCuBE running at the same time and that all instances are connected. Supporting multiple MxCuBE applications running concurrently was achieved by opening a server in the beamline instance of MxCuBE (the master instance) to which all other instances (slave instances) connect via a simple socket protocol (Fig. 1). Only one instance of the GUI can control the instrumentation at any one time. In the master instance of MxCuBE an account (with extra privileges) was created for beamline scientists and operators. This allows beamline staff to survey all operations carried out by remote slave instances of MxCuBE or, should the need arise, re-take control of the beamline without the explicit authorization of the remote user currently in control.

At the start of a remote-access experiment the beamline is controlled by ESRF staff logged in to MxCuBE via the operator account. During this phase of the experimental session, remote users can connect to the beamline control computer and start a slave instance of MxCuBE which, at first, has access only to a very limited subset of operations such as logging in. Once logged in, the only actions initially enabled are the sending and receiving of messages to other MxCuBE instances via the `Chat' tab and the ability to request control of the beamline via the remote-control brick (Fig. 2). Remote users can only start their experiments when the beamline scientist, or operator, explicitly cedes control.

Slave instances of MxCuBE cannot directly take control from any other instance of the beamline GUI. However, they can view all other instances of MxCuBE running on a particular beamline and cede control to another slave instance of the GUI if this is requested. As the current state of MxCuBE on a particular beamline is mirrored across different instances logged into the same account, collaborative work has become popular. Geographically diverse researchers (i.e. different users in the same ESRF Block Allocation Group) can share beam time by passing control between MxCuBE instances. Although only one instance can physically control the beamline, others can monitor the experiment, give suggestions over the message feature, or request control of the beamline in order to perform experiments themselves. This mirroring of GUI instances is also useful for beamline staff during technical support, as they can log in to MxCuBE using the operator account to diagnose and resolve problems.

If during an experiment a remote user loses, for whatever reason, connection to MxCuBE, control reverts back to the beamline's server-instance. In such cases, users must reconnect to MxCuBE and ask for control of the beamline. To avoid delays when beamline staff are not present (i.e. overnight) it is possible to set a timeout such that control passes to the requestor if not explicitly denied within 30 s. At the end of the experimental session, control users can return control to the beamline operator or scientist simply by logging out of MxCuBE.