def add_file(self, can_remove=True): """Add settings for another file to the list""" group = cps.SettingsGroup() if can_remove: group.append("divider", cps.Divider(line=False)) def get_directory_fn(): return self.directory.get_absolute_path() group.append( "file_name", cps.FilenameText( FILE_TEXT, cps.NONE, metadata=True, get_directory_fn=get_directory_fn, exts=[("TIF - Tagged Image File format (*.tif,*.tiff)", "*.tif;*.tiff"), ("PNG - Portable Network Graphics (*.png)", "*.png"), ("JPG/JPEG file (*.jpg,*.jpeg)", "*.jpg,*.jpeg"), ("BMP - Windows Bitmap (*.bmp)", "*.bmp"), ("Compuserve GIF file (*.gif)", "*.gif"), ("MATLAB image (*.mat)", "*.mat"), ("All files (*.*)", "*.*")], doc=""" The filename can be constructed in one of two ways: <ul> <li>As a fixed filename (e.g., <i>Exp1_D03f00d0.tif</i>). </li> <li>Using the metadata associated with an image set in <b>LoadImages</b> or <b>LoadData</b>. This is especially useful if you want your output given a unique label according to the metadata corresponding to an image group. The name of the metadata to substitute is included in a special tag format embedded in your file specification. %(USING_METADATA_TAGS_REF)s%(USING_METADATA_HELP_REF)s.</li> </ul> <p>Keep in mind that in either case, the image file extension, if any, must be included.""" % globals())) group.append( "image_objects_choice", cps.Choice('Load as images or objects?', IO_ALL, doc=""" This setting determines whether you load an image as image data or as segmentation results (i.e., objects): <ul> <li><i>%(IO_IMAGES)s:</i> The input image will be given a user-specified name by which it will be refered downstream. This is the most common usage for this module.</li> <li><i>%(IO_OBJECTS)s:</i> Use this option if the input image is a label matrix and you want to obtain the objects that it defines. A <i>label matrix</i> is a grayscale or color image in which the connected regions share the same label, and defines how objects are represented in CellProfiler. The labels are integer values greater than or equal to 0. The elements equal to 0 are the background, whereas the elements equal to 1 make up one object, the elements equal to 2 make up a second object, and so on. This option allows you to use the objects without needing to insert an <b>Identify</b> module to extract them first. See <b>IdentifyPrimaryObjects</b> for more details.</li> </ul>""" % globals())) group.append( "image_name", cps.FileImageNameProvider("Name the image that will be loaded", "OrigBlue", doc=''' <i>(Used only if an image is output)</i><br> Enter the name of the image that will be loaded. You can use this name to select the image in downstream modules.''' )) group.append( "rescale", cps.Binary("Rescale intensities?", True, doc=""" <i>(Used only if an image is output)</i><br> This option determines whether image metadata should be used to rescale the image's intensities. Some image formats save the maximum possible intensity value along with the pixel data. For instance, a microscope might acquire images using a 12-bit A/D converter which outputs intensity values between zero and 4095, but stores the values in a field that can take values up to 65535. <p>Select <i>%(YES)s</i> to rescale the image intensity so that saturated values are rescaled to 1.0 by dividing all pixels in the image by the maximum possible intensity value. </p> <p>Select <i>%(NO)s</i> to ignore the image metadata and rescale the image to 0 – 1.0 by dividing by 255 or 65535, depending on the number of bits used to store the image.</p>""" % globals())) group.append( "objects_name", cps.ObjectNameProvider( 'Name this loaded object', "Nuclei", doc="""<i>(Used only if objects are output)</i><br> This is the name for the objects loaded from your image""") ) group.append( "wants_outlines", cps.Binary("Retain outlines of loaded objects?", False, doc=""" <i>(Used only if objects are output)</i><br> Select <i>%(YES)s</i> if you want to save an image of the outlines of the loaded objects.""" % globals())) group.append( "outlines_name", cps.OutlineNameProvider('Name the outlines', 'NucleiOutlines', doc=""" <i>(Used only if objects are output)</i><br> Enter a name that will allow the outlines to be selected later in the pipeline.""" )) if can_remove: group.append( "remove", cps.RemoveSettingButton("", "Remove this image", self.file_settings, group)) self.file_settings.append(group)
def create_settings(self): self.image_name = cps.ImageNameSubscriber( 'Select the input image', 'None', doc='''What did you call the images to be made into a projection?''' ) self.projection_type = cps.Choice('Type of projection', P_ALL, doc=''' What kind of projection would you like to make? The final image can be created by the following methods: <ul><li><i>%(P_AVERAGE)s:</i> Use the average pixel intensity at each pixel position.</li> <li><i>%(P_MAXIMUM)s:</i> Use the maximum pixel value at each pixel position.</li> <li><i>%(P_MINIMUM)s:</i> Use the minimum pixel value at each pixel position.</li> <li><i>%(P_SUM)s:</i> Add the pixel values at each pixel position.</li> <li><i>%(P_VARIANCE)s:</i> Compute the variance at each pixel position. <br> The variance method is described in "Selinummi J, Ruusuvuori P, Podolsky I, Ozinsky A, Gold E, et al. (2009), "Bright Field Microscopy as an Alternative to Whole Cell Fluorescence in Automated Analysis of Macrophage Images", PLoS ONE 4(10): e7497 <a href="http://dx.doi.org/10.1371/journal.pone.0007497">(link)</a>. The method is designed to operate on a z-stack of brightfield images taken at different focus planes. Background pixels will have relatively uniform illumination whereas cytoplasm pixels will have higher variance across the z-stack.</li> <li><i>%(P_POWER)s:</i> Compute the power at a given frequency at each pixel position.<br> The power method is experimental. The method computes the power at a given frequency through the z-stack. It might be used with a phase contrast image where the signal at a given pixel will vary sinusoidally with depth. The frequency is measured in z-stack steps and pixels that vary with the given frequency will have a higher score than other pixels with similar variance, but different frequencies.</li> <li><i>%(P_BRIGHTFIELD)s:</i> Perform the brightfield projection at each pixel position.<br> Artifacts such as dust appear as black spots which are most strongly resolved at their focal plane with gradually increasing signals below. The brightfield method scores these as zero since the dark appears in the early z-stacks. These pixels have a high score for the variance method but have a reduced score when using the brightfield method.</li> <li><i>%(P_MASK)s:</i> Compute a binary image of the pixels that are masked in any of the input images.<br> The mask method operates on any masks that might have been applied to the images in a group. The output is a binary image where the "1" pixels are those that are not masked in all of the images and the "0" pixels are those that are masked in one or more of the images.<br> You can use the output of the mask method to mask or crop all of the images in a group similarly. Use the mask method to combine all of the masks in a group, save the image and then use <b>Crop</b>, <b>MaskImage</b> or <b>MaskObjects</b> in another pipeline to mask all images or objects in the group similarly.</li> </ul> ''' % globals()) self.projection_image_name = cps.ImageNameProvider( 'Name the output image', 'ProjectionBlue', doc='''What do you want to call the projected image?''', provided_attributes={ cps.AGGREGATE_IMAGE_ATTRIBUTE: True, cps.AVAILABLE_ON_LAST_ATTRIBUTE: True }) self.frequency = cps.Float("Frequency", 6.0, minval=1.0, doc=""" <i>(Used only if %(P_POWER)s is selected as the projection method)</i><br> This setting controls the frequency at which the power is measured. A frequency of 2 will respond most strongly to pixels that alternate between dark and light in successive z-stack slices. A frequency of N will respond most strongly to pixels whose brightness cycle every N slices.""" % globals())
def create_settings(self): self.input_image = cps.ImageNameSubscriber("Select an input image", "None", doc=""" What did you call the image to be tiled? Additional images within the cycle can be added later by choosing the <i>Across cycles</i> option.""") self.output_image = cps.ImageNameProvider("Name the output image", "TiledImage", doc=""" What do you want to call the final tiled image?""") self.additional_images = [] self.add_button = cps.DoSomething("", "Add another image", self.add_image) self.tile_method = cps.Choice("Tile within cycles or across cycles?", T_ALL, doc=''' How would you like to tile images? Two options are available:<br> <ul> <li><i>Tile within cycles:</i> If you have loaded more than one image for each cycle using modules upstream in the pipeline, the images can be tiled. For example, you may tile three different channels (OrigRed, OrigBlue, and OrigGreen), and a new tiled image will be created for every image cycle. This option takes the place of the obsolete <b>PlaceAdjacent</b> module. </li> <li><i>Tile across cycles:</i> If you want to tile images from multiple cycles together, select this option. For example, you may tile all the images of the same type (e.g., OrigBlue) across all fields of view in your experiment, which will result in one final tiled image when processing is complete.</li> </ul>''') self.rows = cps.Integer("Number of rows in final tiled image", 8, doc=''' How many rows would you like to have in the tiled image? For example, if you want to show your images in a 96-well format, enter 8. <p><i>Special cases:</i> Let <i>M</i> be the total number of slots for images (i.e, number of rows x number of columns) and <i>N</i> be the number of actual images. <ul> <li>If <i>M</i> > <i>N</i>, blanks will be used for the empty slots.</li> <li>If the <i>M</i> < <i>N</i>, an error will occur since there are not enough image slots. Check "Automatically calculate number of rows?" to avoid this error.</li> </ul></p>''') self.columns = cps.Integer( "Number of columns in final tiled image", 12, doc='''How many columns would you like to have in the tiled image? For example, if you want to show your images in a 96-well format, enter 12. <p><i>Special cases:</i> Let <i>M</i> be the total number of slots for images (i.e, number of rows x number of columns) and <i>N</i> be the number of actual images. <ul> <li>If <i>M</i> > <i>N</i>, blanks will be used for the empty slots.</li> <li>If the <i>M</i> < <i>N</i>, an error will occur since there are not enough image slots. Check "Automatically calculate number of columns?" to avoid this error.</li> </ul></p>''') self.place_first = cps.Choice( "Begin tiling in which corner of the final image?", P_ALL, doc=''' Where do you want the first image to be placed? Begin in the upper left-hand corner for a typical multi-well plate format where the first image is A01.''' ) self.tile_style = cps.Choice( "Begin tiling across a row, or down a column?", S_ALL, doc=''' Are the images arranged in rows or columns? If your images are named A01, A02, etc, enter <i>row</i>".''') self.meander = cps.Binary("Tile in meander mode?", False, doc=''' Meander mode tiles adjacent images in one direction, then the next row/column is tiled in the opposite direction. Some microscopes capture images in this fashion. The default mode is "comb", or "typewriter" mode; in this mode, when one row is completely tiled in one direction, the next row starts near where the first row started and tiles again in the same direction.''') self.wants_automatic_rows = cps.Binary( "Automatically calculate number of rows?", False, doc="""<b>Tile</b> can automatically calculate the number of rows in the grid based on the number of image cycles that will be processed. Check this box to create a grid that has the number of columns that you entered and enough rows to display all of your images. If you check both automatic rows and automatic columns, <b>Tile</b> will create a grid that has roughly the same number of rows and columns.""") self.wants_automatic_columns = cps.Binary( "Automatically calculate number of columns?", False, doc="""<b>Tile</b> can automatically calculate the number of columns in the grid from the number of image cycles that will be processed. Check this box to create a grid that has the number of rows that you entered and enough columns to display all of your images. If you check both automatic rows and automatic columns, <b>Tile</b> will create a grid that has roughly the same number of rows and columns.""")
def create_settings(self): self.orig_image_name = cps.ImageNameSubscriber( "Select the input images", cps.NONE, doc=""" Select the images to display on the web page.""") self.wants_thumbnails = cps.Binary("Use thumbnail images?", False, doc=""" Select <i>%(YES)s</i> to display thumbnail images (small versions of the images) on the web page that link to the full images. <br> Select <i>%(NO)s</i> to display the full image directly on the web page. <p>If you are going to use thumbnails, you will need to load them using the <b>Input</b> modules; you can also run a separate pipeline prior to this one to create thumbnails from your originals using the <b>Resize</b> and <b>SaveImages</b> modules. For some high-content screening systems, thumbnail files are automatically created and have the text "thumb" in the name.</p>""" % globals()) self.thumbnail_image_name = cps.ImageNameSubscriber( "Select the thumbnail images", cps.NONE, doc=""" <i>(Used only if using thumbnails)</i><br> Select the name of the images to use for thumbnails.""") self.web_page_file_name = cps.Text("Webpage file name", "images1", metadata=True, doc=""" Enter the desired file name for the web page. <b>CreateWebPage</b> will add the .html extension if no extension is specified. If you have metadata associated with your images, you can name the file using metadata tags. %(USING_METADATA_TAGS_REF)s<br> For instance, if you have metadata tags named "Plate" and "Well", you can create separate per-plate, per-well web pages based on your metadata by inserting the tags "Plate_Well" to specify the name. %(USING_METADATA_HELP_REF)s.""" % globals()) self.directory_choice = CWPDirectoryPath( "Select the folder for the .html file", dir_choices=[ DIR_SAME, DIR_ABOVE, ABSOLUTE_FOLDER_NAME, DEFAULT_INPUT_FOLDER_NAME, DEFAULT_OUTPUT_FOLDER_NAME, DEFAULT_INPUT_SUBFOLDER_NAME, DEFAULT_OUTPUT_SUBFOLDER_NAME ], doc=""" This setting determines how <b>CreateWebPage</b> selects the folder for the .html file(s) it creates. <ul> <li><i>%(DIR_SAME)s</i>: Place the .html file(s) in the same folder as the files.</li> <li><i>%(DIR_ABOVE)s</i>: Place the .html file(s) in the image files' parent folder.</li> <li><i>%(ABSOLUTE_FOLDER_NAME)s</i>: Places the .html file(s) in a folder of your choosing. <b>CreateWebPage</b> will use absolute references for your image URLs if you choose this option.</li> <li><i>%(DEFAULT_INPUT_FOLDER_NAME)s</i>: Places the .html file(s) in the default input folder.</li> <li><i>%(DEFAULT_OUTPUT_FOLDER_NAME)s</i>: Places the .html file(s) in the default output folder.</li> <li><i>%(DEFAULT_INPUT_SUBFOLDER_NAME)s</i>: Places the .html file(s) in a subfolder of the default input folder. You will be prompted for the subfolder name after making this choice</li> <li><i>%(DEFAULT_OUTPUT_SUBFOLDER_NAME)s</i>: Places the .html file(s) in a subfolder of the default input folder. You will be prompted for the subfolder name after making this choice</li> </ul>""" % globals()) self.title = cps.Text("Webpage title", "Image", metadata=True, doc=""" This is the title that appears at the top of the browser window. If you have metadata associated with your images, you can name the file using metadata tags. %(USING_METADATA_TAGS_REF)sFor instance, if you have a metadata tag named "Plate", you can type "Plate: " and then insert the metadata tag "Plate" to display the plate metadata item. %(USING_METADATA_HELP_REF)s.""" % globals()) self.background_color = cps.Color("Webpage background color", "White", doc=""" This setting controls the background color for the web page.""") self.columns = cps.Integer("Number of columns", 1, minval=1, doc=""" This setting determines how many images are displayed in each row.""") self.table_border_width = cps.Integer("Table border width", 1, minval=0, doc=""" The table border width determines the width of the border around the entire grid of displayed images (i.e., the "table" of images) and is measured in pixels. This value can be set to zero, in which case you will not see the table border.""") self.table_border_color = cps.Color("Table border color", "White") self.image_spacing = cps.Integer("Image spacing", 1, minval=0, doc=""" The spacing between images ("table cells"), in pixels.""") self.image_border_width = cps.Integer("Image border width", 1, minval=0, doc=""" The image border width determines the width of the border around each image and is measured in pixels. This value can be set to zero, in which case you will not see the image border.""") self.create_new_window = cps.Choice( "Open new window when viewing full image?", [OPEN_ONCE, OPEN_EACH, OPEN_NO], doc=""" This controls the behavior of the thumbnail links. <ul> <li><i>%(OPEN_ONCE)s:</i> Your browser will open a new window when you click on the first thumbnail and will display subsequent images in the newly opened window. </li> <li><i>%(OPEN_EACH)s:</i> The browser will open a new window each time you click on a link.</li> <li><i>%(OPEN_NO)s:</i> The browser will reuse the current window to display the image</li> </ul>""" % globals()) self.wants_zip_file = cps.Binary( "Make a ZIP file containing the full-size images?", False, doc=""" ZIP files are a common archive and data compression file format, making it convenient to download all of the images represented on the web page with a single click. Select <i>%(YES)s</i> to create a ZIP file that contains all your images, compressed to reduce file size.""" % globals()) self.zipfile_name = cps.Text("Enter the ZIP file name", "Images.zip", metadata=True, doc=""" <i>(Used only if creating a ZIP file)</i><br> Specify the name for the ZIP file.""")
def create_settings(self): self.image_name = cps.ImageNameSubscriber("Select the input image", cps.NONE) self.combine_or_split = cps.Choice("Conversion method", [COMBINE, SPLIT], doc=''' How do you want to convert the color image? <ul> <li><i>%(SPLIT)s:</i> Splits the three channels (red, green, blue) of a color image into three separate grayscale images. </li> <li><i>%(COMBINE)s</i> Converts a color image to a grayscale image by combining the three channels (red, green, blue) together.</li> </ul>''' % globals()) self.rgb_or_channels = cps.Choice("Image type", [CH_RGB, CH_HSV, CH_CHANNELS], doc=""" Many images contain color channels other than red, green and blue. For instance, GIF and PNG formats can have an alpha channel that encodes transparency. TIF formats can have an arbitrary number of channels which represent pixel measurements made by different detectors, filters or lighting conditions. This setting provides three options to choose from: <ul> <li><i>%(CH_RGB)s:</i> The RGB (red,green,blue) color space is the typical model in which color images are stored. Choosing this option will split the image into any of the red, green and blue component images.</li> <li><i>%(CH_HSV)s:</i>The HSV (hue, saturation, value) color space is based on more intuitive color characteristics as tint, shade and tone. Choosing this option will split the image into any of the hue, saturation, and value component images.</li> <li><i>%(CH_CHANNELS)s:</i>This is a more complex model for images which involve more than three chnnels.</li> </ul>""" % globals()) # The following settings are used for the combine option self.grayscale_name = cps.ImageNameProvider("Name the output image", "OrigGray") self.red_contribution = cps.Float("Relative weight of the red channel", 1, 0, doc=''' <i>(Used only when combining channels)</i><br> Relative weights: If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.''') self.green_contribution = cps.Float( "Relative weight of the green channel", 1, 0, doc=''' <i>(Used only when combining channels)</i><br> Relative weights: If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.''') self.blue_contribution = cps.Float( "Relative weight of the blue channel", 1, 0, doc=''' <i>(Used only when combining channels)</i><br> Relative weights: If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.''') # The following settings are used for the split RGB option self.use_red = cps.Binary('Convert red to gray?', True) self.red_name = cps.ImageNameProvider('Name the output image', "OrigRed") self.use_green = cps.Binary('Convert green to gray?', True) self.green_name = cps.ImageNameProvider('Name the output image', "OrigGreen") self.use_blue = cps.Binary('Convert blue to gray?', True) self.blue_name = cps.ImageNameProvider('Name the output image', "OrigBlue") # The following settings are used for the split HSV ption self.use_hue = cps.Binary('Convert hue to gray?', True) self.hue_name = cps.ImageNameProvider('Name the output image', "OrigHue") self.use_saturation = cps.Binary('Convert saturation to gray?', True) self.saturation_name = cps.ImageNameProvider('Name the output image', "OrigSaturation") self.use_value = cps.Binary('Convert value to gray?', True) self.value_name = cps.ImageNameProvider('Name the output image', "OrigValue") # The alternative model: self.channels = [] self.add_channel(False) self.channel_button = cps.DoSomething("", "Add another channel", self.add_channel) self.channel_count = cps.HiddenCount(self.channels, "Channel count")
def create_settings(self): """Create your settings by subclassing this function create_settings is called at the end of initialization. You should create the setting variables for your module here: # Ask the user for the input image self.image_name = cellprofiler.settings.ImageNameSubscriber(...) # Ask the user for the name of the output image self.output_image = cellprofiler.settings.ImageNameProvider(...) # Ask the user for a parameter self.smoothing_size = cellprofiler.settings.Float(...) """ self.object_name = cps.ObjectNameSubscriber( "Select the objects to be edited", cps.NONE, doc=""" Choose a set of previously identified objects for editing, such as those produced by one of the <b>Identify</b> modules.""") self.filtered_objects = cps.ObjectNameProvider( "Name the edited objects", "EditedObjects", doc=""" Enter the name for the objects that remain after editing. These objects will be available for use by subsequent modules.""") self.allow_overlap = cps.Binary("Allow overlapping objects?", False, doc=""" <b>EditObjectsManually</b> can allow you to edit an object so that it overlaps another or it can prevent you from overlapping one object with another. Objects such as worms or the neurites of neurons may cross each other and might need to be edited with overlapping allowed, whereas a monolayer of cells might be best edited with overlapping off. Check this setting to allow overlaps or uncheck it to prevent them.""") self.wants_outlines = cps.Binary( "Retain outlines of the edited objects?", False, doc=""" Check this box if you want to keep images of the outlines of the objects that remain after editing. This image can be saved by downstream modules or overlayed on other images using the <b>OverlayOutlines</b> module.""") self.outlines_name = cps.OutlineNameProvider("Name the outline image", "EditedObjectOutlines", doc=""" <i>(Used only if you have selected to retain outlines of edited objects)</i><br> Enter a name for the outline image.""") self.renumber_choice = cps.Choice("Numbering of the edited objects", [R_RENUMBER, R_RETAIN], doc=""" Choose how to number the objects that remain after editing, which controls how edited objects are associated with their predecessors: <ul> <li><i>%(R_RENUMBER)s:</i> The module will number the objects that remain using consecutive numbers. This is a good choice if you do not plan to use measurements from the original objects and you only want to use the edited objects in downstream modules; the objects that remain after editing will not have gaps in numbering where removed objects are missing.</li> <li><i>%(R_RETAIN)s:</i> This option will retain each object's original number so that the edited object's number matches its original number. This allows any measurements you make from the edited objects to be directly aligned with measurements you might have made of the original, unedited objects (or objects directly associated with them).</li> </ul>""" % globals()) self.wants_image_display = cps.Binary("Display a guiding image?", True, doc=""" Check this setting to display an image and outlines of the objects. Leave the setting unchecked if you do not want a guide image while editing""") self.image_name = cps.ImageNameSubscriber("Select the guiding image", cps.NONE, doc=""" <i>(Used only if a guiding image is desired)</i><br> This is the image that will appear when editing objects. Choose an image supplied by a previous module.""")
def create_settings(self): self.x_source = cps.Choice("Type of measurement to plot on X-axis", SOURCE_CHOICE, doc=''' You can plot two types of measurements: <ul> <li><i>%(SOURCE_IM)s:</i> For a per-image measurement, one numerical value is recorded for each image analyzed. Per-image measurements are produced by many modules. Many have <b>MeasureImage</b> in the name but others do not (e.g., the number of objects in each image is a per-image measurement made by the <b>IdentifyObject</b> modules).</li> <li><i>%(SOURCE_OBJ)s:</i> For a per-object measurement, each identified object is measured, so there may be none or many numerical values recorded for each image analyzed. These are usually produced by modules with <b>MeasureObject</b> in the name.</li> </ul>''' % globals()) self.x_object = cps.ObjectNameSubscriber( 'Select the object to plot on the X-axis', cps.NONE, doc='''<i>(Used only when plotting objects)</i><br> Choose the name of objects identified by some previous module (such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>) whose measurements are to be displayed on the X-axis.''' ) self.x_axis = cps.Measurement( 'Select the measurement to plot on the X-axis', self.get_x_object, cps.NONE, doc=''' Choose the measurement (made by a previous module) to plot on the X-axis.''') self.y_source = cps.Choice("Type of measurement to plot on Y-axis", SOURCE_CHOICE, doc=''' You can plot two types of measurements: <ul> <li><i>%(SOURCE_IM)s:</i> For a per-image measurement, one numerical value is recorded for each image analyzed. Per-image measurements are produced by many modules. Many have <b>MeasureImage</b> in the name but others do not (e.g., the number of objects in each image is a per-image measurement made by <b>IdentifyObject</b> modules).</li> <li><i>%(SOURCE_OBJ)s:</i> For a per-object measurement, each identified object is measured, so there may be none or many numerical values recorded for each image analyzed. These are usually produced by modules with <b>MeasureObject</b> in the name.</li> </ul>''' % globals()) self.y_object = cps.ObjectNameSubscriber( 'Select the object to plot on the Y-axis', cps.NONE, doc='''<i>(Used only when plotting objects)</i><br> Choose the name of objects identified by some previous module (such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>) whose measurements are to be displayed on the Y-axis.''' ) self.y_axis = cps.Measurement( 'Select the measurement to plot on the Y-axis', self.get_y_object, cps.NONE, doc=''' Choose the measurement (made by a previous module) to plot on the Y-axis.''') self.xscale = cps.Choice('How should the X-axis be scaled?', SCALE_CHOICE, None, doc=''' The X-axis can be scaled with either a <i>linear</i> scale or a <i>log</i> (base 10) scaling. <p>Log scaling is useful when one of the measurements being plotted covers a large range of values; a log scale can bring out features in the measurements that would not easily be seen if the measurement is plotted linearly.</p>''') self.yscale = cps.Choice('How should the Y-axis be scaled?', SCALE_CHOICE, None, doc=''' The Y-axis can be scaled with either a <i>linear</i> scale or with a <i>log</i> (base 10) scaling. <p>Log scaling is useful when one of the measurements being plotted covers a large range of values; a log scale can bring out features in the measurements that would not easily be seen if the measurement is plotted linearly.</p>''') self.title = cps.Text('Enter a title for the plot, if desired', '', doc=''' Enter a title for the plot. If you leave this blank, the title will default to <i>(cycle N)</i> where <i>N</i> is the current image cycle being executed.''')
def add_when(self, can_delete=True): group = cps.SettingsGroup() group.append( "choice", cps.Choice("When should the email be sent?", S_ALL, doc=""" Select the kind of event that causes <b>SendEmail</b> to send an email. You have the following choices: <ul> <li><i>%(S_FIRST)s:</i> Send an email during processing of the first image cycle.</li> <li><i>%(S_LAST)s:</i> Send an email after all processing is complete.</li> <li><i>%(S_GROUP_START)s:</i> Send an email during the first cycle of each group of images.</li> <li><i>%(S_GROUP_END)s:</i> Send an email after all processing for a group is complete.</li> <li><i>%(S_EVERY_N)s</i> Send an email each time a certain number of image cycles have been processed. You will be prompted for the number of image cycles if you select this choice.</li> <li><i>%(S_CYCLE_N)s:</i> Send an email after the given number of image cycles have been processed. You will be prompted for the image cycle number if you select this choice. You can add more events if you want emails after more than one image cycle.</li> </ul>""" % globals())) group.append( "image_set_number", cps.Integer("Image cycle number", 1, minval=1, doc=''' <i>(Used only if sending email after a particular cycle number)</i><br> Send an email during processing of the given image cycle. For instance, if you enter 4, then <b>SendEmail</b> will send an email during processing of the fourth image cycle.''') ) group.append( "image_set_count", cps.Integer("Image cycle count", 1, minval=1, doc=''' <i>(Used only if sending email after every N cycles)</i><br> Send an email each time this number of image cycles have been processed. For instance, if you enter 4, then <b>SendEmail</b> will send an email during processing of the fourth, eighth, twelfth, etc. image cycles.''')) group.append( "message", cps.Text("Message text", "Notification from CellProfiler", metadata=True, doc=""" The body of the message sent from CellProfiler. Your message can include metadata values. For instance, if you group by plate and want to send an email after processing each plate, you could use the message "Finished processing plate \\g<Plate>". """)) if can_delete: group.append( "remover", cps.RemoveSettingButton("Remove this email event", "Remove event", self.when, group)) group.append("divider", cps.Divider()) self.when.append(group)
def create_settings(self): self.x_object = cps.ObjectNameSubscriber( 'Select the object to display on the X-axis', cps.NONE, doc=''' Choose the name of objects identified by some previous module (such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>) whose measurements are to be displayed on the X-axis.''' ) self.x_axis = cps.Measurement( 'Select the object measurement to plot on the X-axis', self.get_x_object, cps.NONE, doc=''' Choose the object measurement made by a previous module to display on the X-axis.''') self.y_object = cps.ObjectNameSubscriber( 'Select the object to display on the Y-axis', cps.NONE, doc=''' Choose the name of objects identified by some previous module (such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>) whose measurements are to be displayed on the Y-axis.''' ) self.y_axis = cps.Measurement( 'Select the object measurement to plot on the Y-axis', self.get_y_object, cps.NONE, doc=''' Choose the object measurement made by a previous module to display on the Y-axis.''') self.gridsize = cps.Integer('Select the grid size', 100, 1, 1000, doc=''' Enter the number of grid regions you want used on each axis. Increasing the number of grid regions increases the resolution of the plot.''') self.xscale = cps.Choice('How should the X-axis be scaled?', ['linear', 'log'], None, doc=''' The X-axis can be scaled either with a <i>linear</i> scale or with a <i>log</i> (base 10) scaling. <p>Using a log scaling is useful when one of the measurements being plotted covers a large range of values; a log scale can bring out features in the measurements that would not easily be seen if the measurement is plotted linearly.</p>''') self.yscale = cps.Choice('How should the Y-axis be scaled?', ['linear', 'log'], None, doc=''' The Y-axis can be scaled either with a <i>linear</i> scale or with a <i>log</i> (base 10) scaling. <p>Using a log scaling is useful when one of the measurements being plotted covers a large range of values; a log scale can bring out features in the measurements that would not easily be seen if the measurement is plotted linearly.</p>''') self.bins = cps.Choice('How should the colorbar be scaled?', ['linear', 'log'], None, doc=''' The colorbar can be scaled either with a <i>linear</i> scale or with a <i>log</i> (base 10) scaling. <p>Using a log scaling is useful when one of the measurements being plotted covers a large range of values; a log scale can bring out features in the measurements that would not easily be seen if the measurement is plotted linearly.''') maps = [m for m in matplotlib.cm.datad.keys() if not m.endswith('_r')] maps.sort() self.colormap = cps.Choice('Select the color map', maps, 'jet', doc=''' Select the color map for the density plot. See <a href="http://www.astro.princeton.edu/~msshin/science/code/matplotlib_cm/"> this page</a> for pictures of the available colormaps.''') self.title = cps.Text('Enter a title for the plot, if desired', '', doc=''' Enter a title for the plot. If you leave this blank, the title will default to <i>(cycle N)</i> where <i>N</i> is the current image cycle being executed.''')
def create_settings(self): self.image_name = cps.ImageNameSubscriber("Select the input image", "None", doc=""" What did you call the image to be cropped?""") self.cropped_image_name = cps.CroppingNameProvider( "Name the output image", "CropBlue", doc=""" What do you want to call the cropped image?""") self.shape = cps.Choice( "Select the cropping shape", [SH_RECTANGLE, SH_ELLIPSE, SH_IMAGE, SH_OBJECTS, SH_CROPPING], SH_RECTANGLE, doc=""" Into which shape would you like to crop? <ul> <li><i>Rectangle:</i> Self-explanatory</li> <li><i>Ellipse:</i> Self-explanatory</li> <li><i>Image:</i> Cropping will occur based on a binary image you specify. A choice box with available images will appear from which you can select an image. To crop into an arbitrary shape that you define, choose <i>Image</i> and use the <b>LoadSingleImage</b> module to load a black and white image that you have already prepared from a file. If you have created this image in a program such as Photoshop, this binary image should contain only the values 0 and 255, with zeros (black) for the parts you want to remove and 255 (white) for the parts you want to retain. Alternately, you may have previously generated a binary image using this module (e.g., using the <i>Ellipse</i> option) and saved it using the <b>SaveImages</b> module.<br> In any case, the image must be exactly the same starting size as your image and should contain a contiguous block of white pixels, because the cropping module may remove rows and columns that are completely blank.</li> <li><i>Objects:</i> Crop based on labeled objects identified by a previous <b>Identify</b> module.</li> <li><i>Previous cropping:</i> The cropping generated by a previous cropping module. A choice box with available images appears if you choose <i>Cropping</i>. The images in this box are ones that were generated by previous <b>Crop</b> modules. This <b>Crop</b> module will use the same cropping that was used to generate whichever image you choose.</li> </ul>""") self.crop_method = cps.Choice( "Select the cropping method", [CM_COORDINATES, CM_MOUSE], CM_COORDINATES, doc=""" Would you like to crop by typing in pixel coordinates or clicking with the mouse? <ul> <li><i>Coordinates:</i> For <i>Ellipse</i>, you will be asked to enter the geometric parameters of the ellipse. For <i>Rectangle</i>, you will be asked to specify the coordinates of the corners.</li> <li><i>Mouse:</i> For <i>Ellipse</i>, you will be asked to click five or more points to define an ellipse around the part of the image you want to analyze. Keep in mind that the more points you click, the longer it will take to calculate the ellipse shape. For <i>Rectangle</i>, you can click as many points as you like that are in the interior of the region you wish to retain.</li> </ul>""") self.individual_or_once = cps.Choice( "Apply which cycle's cropping pattern?", [IO_INDIVIDUALLY, IO_FIRST], IO_INDIVIDUALLY, doc=""" Should the cropping pattern in the first image cycle be applied to all subsequent image cycles (<i>First</i>) or should every image cycle be cropped individually (<i>Every</i>)?""" ) self.horizontal_limits = cps.IntegerOrUnboundedRange( "Left and right rectangle positions", minval=0, doc=""" <i>(Used only if Rectangle selected as cropping shape, or if using Plate Fix)</i><br> Specify the left and right positions for the bounding rectangle by selecting one of the following:<br> <ul> <li><i>Absolute</i> to specify these values as absolute pixel coordinates in the original image. For instance, you might enter "25", "225", and "Absolute" to create a 200x200 pixel image that is 25 pixels from the top-left corner.</li> <li><i>From edge</i> to specify position relative to the original image's edge. For instance, you might enter "25", "25", and "Edge" to crop 25 pixels from both the left and right edges of the image, irrespective of the image's original size.</li> </ul>""") self.vertical_limits = cps.IntegerOrUnboundedRange( "Top and bottom rectangle positions", minval=0, doc=""" <i>(Used only if Rectangle selected as cropping shape, or if using Plate Fix)</i><br> Specify the top and bottom positions for the bounding rectangle by selecting one of the following:<br> <ul> <li><i>Absolute</i> to specify these values as absolute pixel coordinates. For instance, you might enter "25", "225", and "Absolute" to create a 200x200 pixel image that's 25 pixels from the top-left corner.</li> <li><i>From edge</i> to specify position relative to the image edge. For instance, you might enter "25", "25", and "Edge" to crop 25 pixels from the edges of your images irrespective of their size.</li> </ul>""") self.ellipse_center = cps.Coordinates("Coordinates of ellipse center", (500, 500), doc=""" <i>(Used only if Ellipse selected as cropping shape)</i><br> What is the center pixel position of the ellipse?""" ) self.ellipse_x_radius = cps.Integer("Ellipse radius, X direction", 400, doc=""" <i>(Used only if Ellipse selected as cropping shape)</i><br> What is the radius of the ellipse in the X direction?""" ) self.ellipse_y_radius = cps.Integer("Ellipse radius, Y direction", 200, doc=""" <i>(Used only if Ellipse selected as cropping shape)</i><br> What is the radius of the ellipse in the Y direction?""" ) self.image_mask_source = cps.ImageNameSubscriber( "Select the masking image", "None", doc=""" <i>(Used only if Image selected as cropping shape)</i><br> What is the name of the image to use as a cropping mask?""" ) self.cropping_mask_source = cps.CroppingNameSubscriber( "Select the image with a cropping mask", "None", doc=""" <i>(Used only if Previous Cropping selected as cropping shape)</i><br> What is the name of the image with the associated cropping mask?""" ) self.objects_source = cps.ObjectNameSubscriber("Select the objects", "None", doc=""" <i>(Used only if Objects selected as cropping shape)</i><br> What are the objects to be used as a cropping mask?""" ) self.use_plate_fix = cps.Binary("Use Plate Fix?", False, doc=""" <i>(Used only if Image selected as cropping shape)</i><br> Do you want to use Plate Fix? When attempting to crop based on a previously identified object such as a rectangular plate, the plate may not have precisely straight edges: there might be a tiny, almost unnoticeable "appendage" sticking out. Without Plate Fix, the <b>Crop</b> module would not crop the image tightly enough: it would retain the tiny appendage, leaving a lot of blank space around the plate and potentially causing problems with later modules (especially IlluminationCorrection). Plate Fix takes the identified object and crops to exclude any minor appendages (technically, any horizontal or vertical line where the object covers less than 50% of the image). It also sets pixels around the edge of the object (for regions greater than 50% but less than 100%) that otherwise would be 0 to the background pixel value of your image, thus avoiding problems with other modules. <i>Important note:</i> Plate Fix uses the coordinates entered in the boxes normally used for rectangle cropping (Top, Left and Bottom, Right) to tighten the edges around your identified plate. This is done because in the majority of plate identifications you do not want to include the sides of the plate. If you would like the entire plate to be shown, you should enter "1:end" for both coordinates. If, for example, you would like to crop 80 pixels from each edge of the plate, you could enter Top, Left and Bottom, Right values of 80 and select <i>From edge</i>.""" ) self.remove_rows_and_columns = cps.Choice( "Remove empty rows and columns?", [RM_NO, RM_EDGES, RM_ALL], RM_NO, doc=""" Do you want to remove rows and columns that lack objects? Options are: <ul> <li><i>No:</i> Leave the image the same size. The cropped areas will be turned to black (zeroes)</li> <li><i>Edges:</i> Crop the image so that its top, bottom, left and right are at the first nonblank pixel for that edge</li> <li><i>All:</i> Remove any row or column of all-blank pixels, even from the internal portion of the image</li> </ul>""")
def create_settings(self): self.objects_name = cps.ObjectNameSubscriber( "Select the input objects", cps.NONE, doc="""Select the objects whose object numbers you want to reassign. You can use any objects that were created in previous modules, such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>.""" ) self.output_objects_name = cps.ObjectNameProvider( "Name the new objects", "RelabeledNuclei", doc= """What do you want to call the objects whose numbers have been reassigned? You can use this name in subsequent modules that take objects as inputs.""") self.relabel_option = cps.Choice( "Operation to perform", [OPTION_UNIFY, OPTION_SPLIT], doc= """Choose <i>Unify</i> to assign adjacent or nearby objects the same object number. Choose <i>Split</i> to give a unique number to non-adjacent objects that currently share the same object number.""") self.unify_option = cps.Choice("Unification to perform", [UNIFY_DISTANCE, UNIFY_PARENT], doc=""" <i>(Used only with the Unify option)</i><br> You can unify objects in one of two ways: <ul> <li><i>%(UNIFY_DISTANCE)s: </i> All objects within a certain pixel radius from each other will be unified</li> <li><i>%(UNIFY_PARENT)s: </i>All objects which share the same parent relationship to another object will be unified. This is not be confused with using the <b>RelateObjects</b> module, in which the related objects remain as individual objects. See <b>RelateObjects</b> for more details.</li> </ul> """ % globals()) self.parent_object = cps.Choice("Select the parent object", [cps.NONE], choices_fn=self.get_parent_choices, doc=""" Select the parent object that will be used to unify the child objects. Please note the following: <ul> <li>You must have established a parent-child relationship between the objects using a prior <b>RelateObjects</b> module.</li> <li>Primary objects and their associated secondary objects are already in a one-to-one parent-child relationship, so it makes no sense to unify them here.</li> </ul>""") self.distance_threshold = cps.Integer( "Maximum distance within which to unify objects", 0, minval=0, doc=""" <i>(Used only when Unifying by distance)</i><br> Objects that are less than or equal to the distance you enter here, in pixels, will be unified. If you choose zero (the default), only objects that are touching will be unified. Note that <i>Unify</i> will not actually connect or bridge the two objects by adding any new pixels; it simply assigns the same object number to the portions of the object. The new, unified object may therefore consist of two or more unconnected components.""") self.wants_image = cps.Binary("Unify using a grayscale image?", False, doc=""" <i>(Used only with the unify option)</i><br> <i>Unify</i> can use the objects' intensity features to determine whether two objects should be unified. If you choose to use a grayscale image, <i>Unify</i> will unify two objects only if they are within the distance you have specified <i>and</i> certain criteria about the objects within the grayscale image are met.""") self.image_name = cps.ImageNameSubscriber( "Select the grayscale image to guide unification", cps.NONE, doc=""" <i>(Used only if a grayscale image is to be used as a guide for unification)</i><br> Select the name of an image loaded or created by a previous module.""" ) self.minimum_intensity_fraction = cps.Float( "Minimum intensity fraction", .9, minval=0, maxval=1, doc=""" <i>(Used only if a grayscale image is to be used as a guide for unification)</i><br> Select the minimum acceptable intensity fraction. This will be used as described for the method you choose in the next setting.""") self.where_algorithm = cps.Choice("Method to find object intensity", [CA_CLOSEST_POINT, CA_CENTROIDS], doc=""" <i>(Used only if a grayscale image is to be used as a guide for unification)</i><br> You can use one of two methods to determine whether two objects should unified, assuming they meet the distance criteria (as specified above): <ul> <li><i>Centroids:</i> When the module considers merging two objects, this method identifies the centroid of each object, records the intensity value of the dimmer of the two centroids, multiplies this value by the <i>minimum intensity fraction</i> to generate a threshold, and draws a line between the centroids. The method will unify the two objects only if the intensity of every point along the line is above the threshold. For instance, if the intensity of one centroid is 0.75 and the other is 0.50 and the <i>minimum intensity fraction</i> has been chosen to be 0.9, all points along the line would need to have an intensity of min(0.75, 0.50) * 0.9 = 0.50 * 0.9 = 0.45.<br> This method works well for round cells whose maximum intensity is in the center of the cell: a single cell that was incorrectly segmented into two objects will typically not have a dim line between the centroids of the two halves and will be correctly unified.</li> <li><i>Closest point:</i> This method is useful for unifying irregularly shaped cells which are connected. It starts by assigning background pixels in the vicinity of the objects to the nearest object. Objects are then unified if each object has background pixels that are: <ul> <li>Within a distance threshold from each object;</li> <li>Above the minimum intensity fraction of the nearest object pixel;</li> <li>Adjacent to background pixels assigned to a neighboring object.</li> </ul> An example of a feature that satisfies the above constraints is a line of pixels that connect two neighboring objects and is roughly the same intensity as the boundary pixels of both (such as an axon connecting two neurons).</li> </ul>""") self.wants_outlines = cps.Binary( "Retain outlines of the relabeled objests?", False, doc="""<i>(Used only if objects are output)</i><br> Check this setting if you want to save an image of the outlines of the relabeled objects.""") self.outlines_name = cps.OutlineNameProvider( 'Name the outlines', 'RelabeledNucleiOutlines', doc="""<i>(Used only if outlined are to be retained)</i><br> Enter a name that will allow the outlines to be selected later in the pipeline.""" )
def create_settings(self): # # The ImageNameSubscriber "subscribes" to all ImageNameProviders in # prior modules. Modules before yours will put images into CellProfiler. # The ImageSubscriber gives your user a list of these images # which can then be used as inputs in your module. # self.input_image_name = cps.ImageNameSubscriber( # The text to the left of the edit box "Input image name:", # HTML help that gets displayed when the user presses the # help button to the right of the edit box doc="""This is the image that the module operates on. You can choose any image that is made available by a prior module. <br> <b>ImageTemplate</b> will do something to this image. """) # # The ImageNameProvider makes the image available to subsequent # modules. # self.output_image_name = cps.ImageNameProvider( "Output image name:", # The second parameter holds a suggested name for the image. "OutputImage", doc="""This is the image resulting from the operation.""") # # Here's a choice box - the user gets a drop-down list of what # can be done. # self.gradient_choice = cps.Choice( "Gradient choice:", # The choice takes a list of possibilities. The first one # is the default - the one the user will typically choose. [GRADIENT_MAGNITUDE, GRADIENT_DIRECTION_X, GRADIENT_DIRECTION_Y], # # Here, in the documentation, we do a little trick so that # we use the actual text that's displayed in the documentation. # # %(GRADIENT_MAGNITUDE)s will get changed into "Gradient magnitude" # etc. Python will look in globals() for the "GRADIENT_" names # and paste them in where it sees %(GRADIENT_...)s # # The <ul> and <li> tags make a neat bullet-point list in the docs # doc="""Choose what to calculate: <ul> <li><i>%(GRADIENT_MAGNITUDE)s</i> to calculate the magnitude of the gradient at each pixel.</li> <li><i>%(GRADIENT_DIRECTION_X)s</i> to get the relative contribution of the gradient in the X direction (.5 = no contribution, 0 to .5 = decreasing with increasing X, .5 to 1 = increasing with increasing X).</li> <li><i>%(GRADIENT_DIRECTION_Y)s</i> to get the relative contribution of the gradient in the Y direction.</li></ul> """ % globals()) # # A binary setting displays a checkbox. # self.automatic_smoothing = cps.Binary( "Automatically choose the smoothing scale?", # The default value is to choose automatically True, doc="""The module will automatically choose a smoothing scale for you if you leave this checked.""") # # We do a little smoothing which supplies a scale to the gradient. # # We use a float setting so that the user can give us a number # for the scale. The control will turn red if the user types in # an invalid scale. # self.scale = cps.Float( "Scale:", # The default value is 1 - a short-range scale 1, # We don't let the user type in really small values minval=.1, # or large values maxval=100, doc="""This is a scaling factor that supplies the sigma for a gaussian that's used to smooth the image. The gradient is calculated on the smoothed image, so large scales will give you long-range gradients and small scales will give you short-range gradients""")
def create_settings(self): threshold_methods = [ method for method in TM_METHODS if method != TM_BINARY_IMAGE ] self.image_name = cps.ImageNameSubscriber("Select the input image", doc=''' Choose the image to be thresholded.''') self.thresholded_image_name = cps.ImageNameProvider( "Name the output image", "ThreshBlue", doc=''' Enter a name for the thresholded image.''') self.binary = cps.Choice("Select the output image type", [GRAYSCALE, BINARY], doc=''' Two types of output images can be produced:<br> <ul> <li><i>%(GRAYSCALE)s:</i> The pixels that are retained after some pixels are set to zero or shifted (based on your selections for thresholding options) will have their original intensity values.</li> <li><i>%(BINARY)s:</i> The pixels that are retained after some pixels are set to zero (based on your selections for thresholding options) will be white and all other pixels will be black (zeroes).</li> </ul>''' % globals()) # if not binary: self.low_or_high = cps.Choice( "Set pixels below or above the threshold to zero?", [TH_BELOW_THRESHOLD, TH_ABOVE_THRESHOLD], doc=""" <i>(Used only when "%(GRAYSCALE)s" thresholding is selected)</i><br> This option adjusts how pixels above or below the threshold are handled: <ul> <li><i>%(TH_BELOW_THRESHOLD)s:</i> Set the dim pixels below the threshold to zero.</li> <li><i>%(TH_ABOVE_THRESHOLD)s:</i> Set the bright pixels above the threshold to zero.</li> </ul> """ % globals()) # if not binary and below threshold self.shift = cps.Binary( "Subtract the threshold value from the remaining pixel intensities?", False, doc=''' <i>(Used only if the output image is %(GRAYSCALE)s and pixels below a given intensity are to be set to zero)</i><br> Select <i>%(YES)s</i> to shift the value of the dim pixels by the threshold value.''' % globals()) # if not binary and above threshold self.dilation = cps.Float( "Number of pixels by which to expand the thresholding around those excluded bright pixels", 0.0, doc=''' <i>(Used only if the output image is grayscale and pixels above a given intensity are to be set to zero)</i><br> This setting is useful when attempting to exclude bright artifactual objects: first, set the threshold to exclude these bright objects; it may also be desirable to expand the thresholded region around those bright objects by a certain distance so as to avoid a "halo" effect.''' ) self.create_threshold_settings(threshold_methods) self.threshold_smoothing_choice.value = TSM_NONE
def create_settings(self): # Input settings self.input_color_choice = cps.Choice("Input image type", CC_ALL, doc=""" Specify whether you are combining several grayscale images or loading a single color image.""") self.wants_red_input = cps.Binary("Use a red image?", True, doc=""" Check this box to specify an image to use for the red channel.""") self.red_input_image = cps.ImageNameSubscriber("Select the red image", cps.NONE) self.wants_green_input = cps.Binary("Use a green image?", True, doc=""" Check this box to specify an image to use for the green channel.""" ) self.green_input_image = cps.ImageNameSubscriber( "Select the green image", cps.NONE) self.wants_blue_input = cps.Binary("Use a blue image?", True, doc=""" Check this box to specify an image to use for the blue channel.""") self.blue_input_image = cps.ImageNameSubscriber( "Select the blue image", cps.NONE) self.color_input_image = cps.ImageNameSubscriber( "Select the color image", cps.NONE, doc=''' Select the color image to use.''') # Output settings self.output_color_choice = cps.Choice("Output image type", CC_ALL, doc=""" Specify whether you want to produce several grayscale images or one color image.""" ) self.wants_red_output = cps.Binary("Produce a red image?", True) self.red_output_image = cps.ImageNameProvider("Name the red image", "InvertedRed") self.wants_green_output = cps.Binary("Produce a green image?", True) self.green_output_image = cps.ImageNameProvider( "Name the green image", "InvertedGreen") self.wants_blue_output = cps.Binary("Produce a blue image?", True) self.blue_output_image = cps.ImageNameProvider("Name the blue image", "InvertedBlue") self.color_output_image = cps.ImageNameProvider( "Name the inverted color image", "InvertedColor", doc=''' <i>(Used only when producing a color output image)</i><br> Enter a name for the inverted color image.''')
def create_settings(self): """Create your settings by subclassing this function create_settings is called at the end of initialization. You should create the setting variables for your module here: # Ask the user for the input image self.image_name = cellprofiler.settings.ImageNameSubscriber(...) # Ask the user for the name of the output image self.output_image = cellprofiler.settings.ImageNameProvider(...) # Ask the user for a parameter self.smoothing_size = cellprofiler.settings.Float(...) """ self.objects_or_image = cps.Choice( "Display object or image measurements?", [OI_OBJECTS, OI_IMAGE], doc=""" <ul> <li><i>%(OI_OBJECTS)s</i> displays measurements made on objects.</li> <li><i>%(OI_IMAGE)s</i> displays a single measurement made on an image.</li> </ul>""" % globals()) self.objects_name = cps.ObjectNameSubscriber( "Select the input objects", cps.NONE, doc=""" <i>(Used only when displaying object measurements)</i><br> Choose the name of objects identified by some previous module (such as <b>IdentifyPrimaryObjects</b> or <b>IdentifySecondaryObjects</b>).""") def object_fn(): if self.objects_or_image == OI_OBJECTS: return self.objects_name.value else: return cpmeas.IMAGE self.measurement = cps.Measurement("Measurement to display", object_fn, doc=""" Choose the measurement to display. This will be a measurement made by some previous module on either the whole image (if displaying a single image measurement) or on the objects you selected.""") self.wants_image = cps.Binary( "Display background image?", True, doc="""Choose whether or not to display the measurements on a background image. Usually, you will want to see the image context for the measurements, but it may be useful to save just the overlay of the text measurements and composite the overlay image and the original image later. Choose "Yes" to display the measurements on top of a background image or "No" to display the measurements on a black background.""") self.image_name = cps.ImageNameSubscriber( "Select the image on which to display the measurements", cps.NONE, doc=""" Choose the image to be displayed behind the measurements. This can be any image created or loaded by a previous module. If you have chosen not to display the background image, the image will only be used to determine the dimensions of the displayed image""" ) self.color_or_text = cps.Choice( "Display mode", [CT_TEXT, CT_COLOR], doc="""<i>(Used only when displaying object measurements)</i><br> Choose how to display the measurement information. If you choose %(CT_TEXT)s, <b>DisplayDataOnImage</b> will display the numeric value on top of each object. If you choose %(CT_COLOR)s, <b>DisplayDataOnImage</b> will convert the image to grayscale, if necessary, and display the portion of the image within each object using a hue that indicates the measurement value relative to the other objects in the set using the default color map. """ % globals()) self.colormap = cps.Colormap( "Color map", doc="""<i>(Used only when displaying object measurements)</i><br> This is the color map used as the color gradient for coloring the objects by their measurement values. """) self.text_color = cps.Color("Text color", "red", doc=""" This is the color that will be used when displaying the text. """) self.display_image = cps.ImageNameProvider( "Name the output image that has the measurements displayed", "DisplayImage", doc=""" The name that will be given to the image with the measurements superimposed. You can use this name to refer to the image in subsequent modules (such as <b>SaveImages</b>).""") self.font_size = cps.Integer("Font size (points)", 10, minval=1) self.decimals = cps.Integer("Number of decimals", 2, minval=0) self.saved_image_contents = cps.Choice("Image elements to save", [E_IMAGE, E_FIGURE, E_AXES], doc=""" This setting controls the level of annotation on the image: <ul> <li><i>%(E_IMAGE)s:</i> Saves the image with the overlaid measurement annotations.</li> <li><i>%(E_AXES)s:</i> Adds axes with tick marks and image coordinates.</li> <li><i>%(E_FIGURE)s:</i> Adds a title and other decorations.</li></ul>""" % globals()) self.offset = cps.Integer("Annotation offset (in pixels)", 0, doc=""" Add a pixel offset to the measurement. Normally, the text is placed at the object (or image) center, which can obscure relevant features of the object. This setting adds a specified offset to the text, in a random direction.""") self.color_map_scale_choice = cps.Choice( "Color map scale", [CMS_USE_MEASUREMENT_RANGE, CMS_MANUAL], doc="""<i>(Used only when displaying object measurements as a colormap)</i><br> <b>DisplayDataOnImage</b> assigns a color to each object's measurement value from a colormap when in colormap-mode, mapping the value to a color along the colormap's continuum. This mapping has implicit upper and lower bounds to its range which are the extremes of the colormap. This setting determines whether the extremes are the minimum and maximum values of the measurement from among the objects in the current image or manually-entered extremes. <ul> <li><i>%(CMS_USE_MEASUREMENT_RANGE)s:</i> Use the full range of colors to get the maximum contrast within the image. </li> <li><i>%(CMS_MANUAL)s:</i> Manually set the upper and lower bounds so that images with different maxima and minima can be compared by a uniform color mapping.</li> </ul> """ % globals()) self.color_map_scale = cps.FloatRange( "Color map range", value=(0.0, 1.0), doc="""<i>(Used only when setting a manual colormap range)</i><br> This setting determines the lower and upper bounds of the values for the color map. """)
def create_settings(self): '''Create the settings for the ExportToCellH5 module''' self.directory = cps.DirectoryPath( "Output file location", doc = """ This setting lets you choose the folder for the output files. %(IO_FOLDER_CHOICE_HELP_TEXT)s """ % globals()) def get_directory_fn(): '''Get the directory for the CellH5 file''' return self.directory.get_absolute_path() def set_directory_fn(path): dir_choice, custom_path = self.directory.get_parts_from_path(path) self.directory.join_parts(dir_choice, custom_path) self.file_name = cps.FilenameText( "Output file name", "DefaultOut.ch5", get_directory_fn = get_directory_fn, set_directory_fn = set_directory_fn, metadata = True, browse_msg = "Choose CellH5 file", mode = cps.FilenameText.MODE_APPEND, exts = [("CellH5 file (*.cellh5)", "*.ch5"), ("HDF5 file (*.h5)", "*.h5"), ("All files (*.*", "*.*")], doc = """ This setting lets you name your CellH5 file. If you choose an existing file, CellProfiler will add new data to the file or overwrite existing locations. <p>%(IO_WITH_METADATA_HELP_TEXT)s %(USING_METADATA_TAGS_REF)s. For instance, if you have a metadata tag named "Plate", you can create a per-plate folder by selecting one the subfolder options and then specifying the subfolder name as "\g<Plate>". The module will substitute the metadata values for the current image set for any metadata tags in the folder name.%(USING_METADATA_HELP_REF)s.</p> """ % globals()) self.overwrite_ok = cps.Binary( "Overwrite existing data without warning?", False, doc=""" Select <i>%(YES)s</i> to automatically overwrite any existing data for a site. Select <i>%(NO)s</i> to be prompted first. If you are running the pipeline on a computing cluster, select <i>%(YES)s</i> unless you want execution to stop because you will not be prompted to intervene. Also note that two instances of CellProfiler cannot write to the same file at the same time, so you must ensure that separate names are used on a cluster. """ % globals()) self.repack = cps.Binary( "Repack after analysis", True, doc=""" This setting determines whether CellProfiler in multiprocessing mode repacks the data at the end of analysis. If you select <i>%(YES)s</i>, CellProfiler will combine all of the satellite files into a single file upon completion. This option requires some extra temporary disk space and takes some time at the end of analysis, but results in a single file which may occupy less disk space. If you select <i>%(NO)s</i>, CellProfiler will create a master file using the name that you give and this file will have links to individual data files that contain the actual data. Using the data generated by this option requires that you keep the master file and the linked files together when copying them to a new folder. """ % globals()) self.plate_metadata = cps.Choice( "Plate metadata", [], value="Plate", choices_fn=self.get_metadata_choices, doc=""" This is the metadata tag that identifies the plate name of the images for the current cycle. Choose <i>None</i> if your assay does not have metadata for plate name. If your assay is slide-based, you can use a metadata item that identifies the slide as the choice for this setting and set the well and site metadata items to <i>None</i>.""") self.well_metadata = cps.Choice( "Well metadata", [], value="Well", choices_fn=self.get_metadata_choices, doc = """This is the metadata tag that identifies the well name for the images in the current cycle. Choose <i>None</i> if your assay does not have metadata for the well.""") self.site_metadata = cps.Choice( "Site metadata", [], value="Site", choices_fn = self.get_metadata_choices, doc = """This is the metadata tag that identifies the site name for the images in the current cycle. Choose <i>None</i> if your assay doesn't divide wells up into sites or if this tag is not required for other reasons.""") self.divider = cps.Divider() self.wants_to_choose_measurements = cps.Binary( "Choose measurements?", False, doc=""" This setting lets you choose between exporting all measurements or just the ones that you choose. Select <i>%(YES)s</i> to pick the measurements to be exported. Select <i>%(NO)s</i> to automatically export all measurements available at this stage of the pipeline. """ % globals()) self.measurements = cps.MeasurementMultiChoice( "Measurements to export", doc = """ <i>(Used only if choosing measurements.)</i> <br> This setting lets you choose individual measurements to be exported. Check the measurements you want to export. """) self.objects_to_export = [] self.add_objects_button = cps.DoSomething( "Add objects to export", "Add objects", self.add_objects) self.images_to_export = [] self.add_image_button = cps.DoSomething( "Add an image to export", "Add image", self.add_image) self.objects_count = cps.HiddenCount(self.objects_to_export) self.images_count = cps.HiddenCount(self.images_to_export)
def create_settings(self): #XXX needs to use cps.SettingsGroup class Operand(object): '''Represents the collection of settings needed by each operand''' def __init__(self, index, operation): self.__index = index self.__operation = operation self.__operand_choice = cps.Choice(self.operand_choice_text(), MC_ALL, doc=""" Is the operand an image or object measurement?""" ) self.__operand_objects = cps.ObjectNameSubscriber( self.operand_objects_text(), "None", doc=""" Which objects do you want to measure for this operation?""" ) self.__operand_measurement = cps.Measurement( self.operand_measurement_text(), self.object_fn, doc=""" Enter the category that was used to create the measurement. You will be prompted to add additional information depending on the type of measurement that is requested.""" ) self.__multiplicand = cps.Float( "Multiply the above operand by", 1, doc=""" By what number would you like to multiply the above operand?""" ) self.__exponent = cps.Float( "Raise the power of above operand by", 1, doc=""" To what power would you like to raise the above operand?""" ) @property def operand_choice(self): '''Either MC_IMAGE for image measurements or MC_OBJECT for object''' return self.__operand_choice @property def operand_objects(self): '''Get measurements from these objects''' return self.__operand_objects @property def operand_measurement(self): '''The measurement providing the value of the operand''' return self.__operand_measurement @property def multiplicand(self): '''Premultiply the measurement by this value''' return self.__multiplicand @property def exponent(self): '''Raise the measurement to this power''' return self.__exponent @property def object(self): '''The name of the object for measurement or "Image"''' if self.operand_choice == MC_IMAGE: return cpmeas.IMAGE else: return self.operand_objects.value def object_fn(self): if self.__operand_choice == MC_IMAGE: return cpmeas.IMAGE elif self.__operand_choice == MC_OBJECT: return self.__operand_objects.value else: raise NotImplementedError( "Measurement type %s is not supported" % self.__operand_choice.value) def operand_name(self): '''A fancy name based on what operation is being performed''' if self.__index == 0: return ("first operand" if self.__operation in (O_ADD, O_MULTIPLY) else "minuend" if self.__operation == O_SUBTRACT else "numerator") elif self.__index == 1: return ("second operand" if self.__operation in (O_ADD, O_MULTIPLY) else "subtrahend" if self.__operation == O_SUBTRACT else "denominator") def operand_choice_text(self): return self.operand_text("Select the %s measurement type") def operand_objects_text(self): return self.operand_text("Select the %s objects") def operand_text(self, format): return format % self.operand_name() def operand_measurement_text(self): return self.operand_text("Select the %s measurement") def settings(self): '''The operand settings to be saved in the output file''' return [ self.operand_choice, self.operand_objects, self.operand_measurement, self.multiplicand, self.exponent ] def visible_settings(self): '''The operand settings to be displayed''' self.operand_choice.text = self.operand_choice_text() self.operand_objects.text = self.operand_objects_text() self.operand_measurement.text = self.operand_measurement_text() result = [self.operand_choice] result += ([self.operand_objects] if self.operand_choice == MC_OBJECT \ else []) result += [ self.operand_measurement, self.multiplicand, self.exponent ] return (result) self.output_feature_name = cps.Text("Name the output measurement", "Measurement", doc=""" What do you want to call the measurement calculated by this module?""" ) self.operation = cps.Choice("Operation", O_ALL, doc=""" What arithmetic operation would you like to perform? <i>None</i> is useful if you simply want to select some of the later options in the module, such as multiplying or exponentiating your image by a constant.""" ) self.operands = (Operand(0, self.operation), Operand(1, self.operation)) self.spacer_1 = cps.Divider(line=True) self.spacer_2 = cps.Divider(line=True) self.spacer_3 = cps.Divider(line=True) self.wants_log = cps.Binary("Take log10 of result?", False, doc=""" Do you want the log (base 10) of the result?""" ) self.final_multiplicand = cps.Float("Multiply the result by", 1, doc=""" <i>(Used only for operations other than None)</i><br> By what number would you like to multiply the result?""" ) self.final_exponent = cps.Float("Raise the power of result by", 1, doc=""" <i>(Used only for operations other than None)</i><br> To what power would you like to raise the result?""" ) self.final_addend = cps.Float("Add to the result", 0, doc=""" What number would you like to add to the result?""" ) self.constrain_lower_bound = cps.Binary( "Constrain the result to a lower bound?", False, doc=""" Check this setting if you want the result to be constrained to a lower bound.""") self.lower_bound = cps.Float("Enter the lower bound", 0, doc=""" Enter the lower bound here.""") self.constrain_upper_bound = cps.Binary( "Constrain the result to an upper bound?", False, doc=""" Check this setting if you want the result to be constrained to an upper bound.""") self.upper_bound = cps.Float("Enter the upper bound", 1, doc=""" Enter the upper bound here.""")
def create_settings(self): '''Create the UI settings for this module''' self.recipients = [] self.recipient_count = cps.HiddenCount(self.recipients) self.add_recipient(False) self.add_recipient_button = cps.DoSomething( "Add a recipient address.", "Add address", self.add_recipient) if sys.platform.startswith("win"): user = os.environ.get("USERNAME","yourname@yourdomain") else: user = os.environ.get("USER","yourname@yourdomain") self.from_address = cps.Text( "Sender address", user, doc="""Enter the address for the email's "From" field.""") self.subject = cps.Text( "Subject line","CellProfiler notification", metadata=True, doc="""Enter the text for the email's subject line. If you have metadata associated with your images, you can use metadata tags here. %(USING_METADATA_TAGS_REF)s<br> For instance, if you have plate metadata, you might use the line, "CellProfiler: processing plate " and insert the metadata tag for the plate at the end. %(USING_METADATA_HELP_REF)s."""%globals()) self.smtp_server = cps.Text( "Server name", "mail", doc="""Enter the address of your SMTP server. You can ask your network administrator for your outgoing mail server which is often made up of part of your email address, e.g., "*****@*****.**". You might be able to find this information by checking your settings or preferences in whatever email program you use.""") self.port = cps.Integer( "Port", smtplib.SMTP_PORT, 0, 65535, doc="""Enter your server's SMTP port. The default (25) is the port used by most SMTP servers. Your network administrator may have set up SMTP to use a different port; also, the connection security settings may require a different port.""") self.connection_security = cps.Choice( "Select connection security", C_ALL, doc="""Select the connection security. Your network administrator can tell you which setting is appropriate, or you can check the settings on your favorite email program.""") self.use_authentication = cps.Binary( "Username and password required to login?", False, doc="""Check this box if you need to enter a username and password to authenticate.""") self.username = cps.Text( "Username", user, doc="""Enter your server's SMTP username.""") self.password = cps.Text( "Password", "", doc="""Enter your server's SMTP password.""") self.when = [] self.when_count = cps.HiddenCount(self.when) self.add_when(False) self.add_when_button = cps.DoSomething( "Add another email event","Add event", self.add_when, doc="""Press this button to add another event or condition. <b>SendEmail</b> will send an email when this event happens""")
def create_settings(self): self.delimiter = cps.CustomChoice( 'Select or enter the column delimiter', DELIMITERS, doc=""" What delimiter do you want to use? This is the character that separates columns in a file. The two default choices are tab and comma, but you can type in any single character delimiter you would prefer. Be sure that the delimiter you choose is not a character that is present within your data (for example, in file names).""" ) self.prepend_output_filename = cps.Binary( "Prepend the output file name to the data file names?", True, doc=""" This can be useful if you want to run a pipeline multiple times without overwriting the old results.""") self.directory = cps.DirectoryPath( "Output file location", dir_choices=[ DEFAULT_OUTPUT_FOLDER_NAME, DEFAULT_INPUT_FOLDER_NAME, ABSOLUTE_FOLDER_NAME, DEFAULT_INPUT_SUBFOLDER_NAME, DEFAULT_OUTPUT_SUBFOLDER_NAME ], doc="""This setting lets you choose the folder for the output files. %(IO_FOLDER_CHOICE_HELP_TEXT)s <p>%(IO_WITH_METADATA_HELP_TEXT)s %(USING_METADATA_TAGS_REF)s<br> For instance, if you have a metadata tag named "Plate", you can create a per-plate folder by selecting one of the subfolder options and then specifying the subfolder name as "\g<Plate>". The module will substitute the metadata values for the current image set for any metadata tags in the folder name. %(USING_METADATA_HELP_REF)s.</p>""" % globals()) self.add_metadata = cps.Binary( "Add image metadata columns to your object data file?", False, doc= """"Image_Metadata_" columns are normally exported in the Image data file, but if you check this box they will also be exported with the Object data file(s).""" ) self.excel_limits = cps.Binary( "Limit output to a size that is allowed in Excel?", False, doc=""" If your output has more than 256 columns, a window will open which allows you to select the columns you'd like to export. If your output exceeds 65,000 rows, you can still open the .csv in Excel, but not all rows will be visible.""" ) self.pick_columns = cps.Binary( "Select the columns of measurements to export?", False, doc=""" Checking this setting will open up a window that allows you to select the columns to export.""" ) self.columns = cps.MeasurementMultiChoice( "Press button to select measurements to export", doc= """<i>(Used only when selecting the columns of measurements to export)</i><br>This setting controls the columns to be exported. Press the button and check the measurements or categories to export""") self.wants_aggregate_means = cps.Binary( "Calculate the per-image mean values for object measurements?", False, doc=""" <b>ExportToSpreadsheet</b> can calculate population statistics over all the objects in each image and save that value as an aggregate measurement in the Image file. For instance, if you are measuring the area of the Nuclei objects and you check the box for this option, <b>ExportToSpreadsheet</b> will create a column in the Image file called "Mean_Nuclei_AreaShape_Area". <p>You may not want to use <b>ExportToSpreadsheet</b> to calculate these measurements if your pipeline generates a large number of per-object measurements; doing so might exceed Excel's limits on the number of columns (256). """ ) self.wants_aggregate_medians = cps.Binary( "Calculate the per-image median values for object measurements?", False) self.wants_aggregate_std = cps.Binary( "Calculate the per-image standard deviation values for object measurements?", False) self.wants_genepattern_file = cps.Binary( "Create a GenePattern GCT file?", False, doc=""" Create a GCT file compatible with <a href="http://www.broadinstitute.org/cancer/software/genepattern/">GenePattern</a>. The GCT file format is a tab-delimited text file format that describes a gene expression dataset; the specifics of the format are described <a href="http://www.broadinstitute.org/cancer/software/genepattern/tutorial/gp_fileformats.html#gct">here</a>. By converting your measurements into a GCT file, you can make use of GenePattern's data visualization and clustering methods. <p>Each row in the GCT file represents (ordinarily) a gene and each column represents a sample (in this case, a per-image set of measurements). In addition to any other spreadsheets desired, checking this box will produce a GCT file with the extension .gct, prepended with the text selection above. If per-image aggregate measurements are requested above, those measurements are included in the GCT file as well.</p>""") self.how_to_specify_gene_name = cps.Choice( "Select source of sample row name", GP_NAME_OPTIONS, GP_NAME_METADATA, doc=""" <i>(Used only if a GenePattern file is requested)</i><br> The first column of the GCT file is the unique identifier for each sample, which is ordinarily the gene name. This information may be specified in one of two ways: <ul> <li><i>Metadata:</i> If you used <b>LoadData</b> or <b>LoadImages</b> to input your images, you may use a per-image data measurement (such as metadata) that corresponds to the identifier for this column. %(USING_METADATA_HELP_REF)s.</li> <li><i>Image filename:</i> If the gene name is not available, the image filename can be used as a surrogate identifier.</li> </ul>""" % globals()) self.gene_name_column = cps.Measurement( "Select the metadata to use as the identifier", lambda: cpmeas.IMAGE, doc=""" <i>(Used only if a GenePattern file is requested and metadata is used to name each row)</i><br> Choose the measurement that corresponds to the identifier, such as metadata from <b>LoadData</b>'s input file. %(USING_METADATA_HELP_REF)s.""" % globals()) self.use_which_image_for_gene_name = cps.ImageNameSubscriber( "Select the image to use as the identifier", "None", doc=""" <i>(Used only if a GenePattern file is requested and image filename is used to name each row)</i><br> Select which image whose filename will be used to identify each sample row.""" ) self.wants_everything = cps.Binary( "Export all measurements, using default file names?", True, doc="""Check this setting to export every measurement. <b>ExportToSpreadsheet</b> will create one file per object type, as well as per-image, per-experiment and object relationships, if relevant. It will use the object name as the file name, optionally prepending the output file name if specified above. Leave this box unchecked to specify which objects should be exported or to override the automatic names.""") self.object_groups = [] self.add_object_group() self.add_button = cps.DoSomething("", "Add another data set", self.add_object_group)
def create_settings(self): self.scheme_choice = cps.Choice( "Select a color scheme", [SCHEME_RGB, SCHEME_CMYK, SCHEME_STACK],doc=""" This module can use one of two color schemes to combine images:<br/> <ul><li><i>%(SCHEME_RGB)s</i>: Each input image determines the intensity of one of the color channels: red, green, and blue.</li> <li><i>%(SCHEME_CMYK)s</i>: Three of the input images are combined to determine the colors (cyan, magenta, and yellow) and a fourth is used only for brightness. The cyan image adds equally to the green and blue intensities. The magenta image adds equally to the red and blue intensities. The yellow image adds equally to the red and green intensities.</li> <li><i>%(SCHEME_STACK)s</i>: The channels are stacked in order. An arbitrary number of channels is allowed.</li> </ul>"""%globals()) # # # # # # # # # # # # # # # # # # RGB settings # # # # # # # # # # # # # # # # # self.red_image_name = cps.ImageNameSubscriber( "Select the image to be colored red", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.green_image_name = cps.ImageNameSubscriber( "Select the image to be colored green", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.blue_image_name = cps.ImageNameSubscriber( "Select the image to be colored blue", can_be_blank = True,blank_text = LEAVE_THIS_BLACK) self.rgb_image_name = cps.ImageNameProvider( "Name the output image","ColorImage") self.red_adjustment_factor = cps.Float( "Relative weight for the red image", value=1,minval=0,doc=''' <i>(Used only if %(SCHEME_RGB)s is selected as the color scheme)</i><br> Enter the relative weight for the red image. If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) self.green_adjustment_factor = cps.Float( "Relative weight for the green image", value=1,minval=0,doc=''' <i>(Used only if %(SCHEME_RGB)s is selected as the color scheme)</i><br> Enter the relative weight for the green image. If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) self.blue_adjustment_factor = cps.Float( "Relative weight for the blue image", value=1, minval=0,doc=''' <i>(Used only if %(SCHEME_RGB)s is selected as the color scheme)</i><br> Enter the relative weight for the blue image. If all relative weights are equal, all three colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) # # # # # # # # # # # # # # # # CYMK settings # # # # # # # # # # # # # # # self.cyan_image_name = cps.ImageNameSubscriber( "Select the image to be colored cyan", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.magenta_image_name = cps.ImageNameSubscriber( "Select the image to be colored magenta", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.yellow_image_name = cps.ImageNameSubscriber( "Select the image to be colored yellow", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.gray_image_name = cps.ImageNameSubscriber( "Select the image that determines brightness", can_be_blank = True, blank_text = LEAVE_THIS_BLACK) self.cyan_adjustment_factor = cps.Float( "Relative weight for the cyan image", value=1, minval=0,doc=''' <i>(Used only if %(SCHEME_CMYK)s is selected as the color scheme)</i><br> Enter the relative weight for the cyan image. If all relative weights are equal, all colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) self.magenta_adjustment_factor = cps.Float( "Relative weight for the magenta image", value=1, minval=0,doc=''' <i>(Used only if %(SCHEME_CMYK)s is selected as the color scheme)</i><br> Enter the relative weight for the magenta image. If all relative weights are equal, all colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) self.yellow_adjustment_factor = cps.Float( "Relative weight for the yellow image", value=1,minval=0,doc=''' <i>(Used only if %(SCHEME_CMYK)s is selected as the color scheme)</i><br> Enter the relative weight for the yellow image. If all relative weights are equal, all colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) self.gray_adjustment_factor = cps.Float( "Relative weight for the brightness image", value=1,minval=0,doc=''' <i>(Used only if %(SCHEME_CMYK)s is selected as the color scheme)</i><br> Enter the relative weight for the brightness image. If all relative weights are equal, all colors contribute equally in the final image. To weight colors relative to each other, increase or decrease the relative weights.'''%globals()) # # # # # # # # # # # # # # # # Stack settings # # # # # # # # # # # # # # # self.stack_channels = [] self.add_stack_channel_cb(can_remove = False) self.add_stack_channel = cps.DoSomething("","Add another channel", self.add_stack_channel_cb)
def create_settings(self): self.obj_or_img = cps.Choice( "Compare segmented objects, or foreground/background?", O_ALL) self.ground_truth = cps.ImageNameSubscriber( "Select the image to be used as the ground truth basis for calculating the amount of overlap", cps.NONE, doc=""" <i>(Used only when comparing foreground/background)</i> <br> This binary (black and white) image is known as the "ground truth" image. It can be the product of segmentation performed by hand, or the result of another segmentation algorithm whose results you would like to compare.""" ) self.test_img = cps.ImageNameSubscriber( "Select the image to be used to test for overlap", cps.NONE, doc=""" <i>(Used only when comparing foreground/background)</i> <br> This binary (black and white) image is what you will compare with the ground truth image. It is known as the "test image".""" ) self.object_name_GT = cps.ObjectNameSubscriber( "Select the objects to be used as the ground truth basis for calculating the amount of overlap", cps.NONE, doc=""" <i>(Used only when comparing segmented objects)</i> <br> Choose which set of objects will used as the "ground truth" objects. It can be the product of segmentation performed by hand, or the result of another segmentation algorithm whose results you would like to compare. See the <b>Load</b> modules for more details on loading objects.""") self.object_name_ID = cps.ObjectNameSubscriber( "Select the objects to be tested for overlap against the ground truth", cps.NONE, doc=""" <i>(Used only when comparing segmented objects)</i> <br> This set of objects is what you will compare with the ground truth objects. It is known as the "test object." """ ) self.wants_emd = cps.Binary( "Calculate earth mover's distance?", False, doc="""The earth mover's distance computes the shortest distance that would have to be travelled to move each foreground pixel in the test image to some foreground pixel in the reference image. "Earth mover's" refers to an analogy: the pixels are "earth" that has to be moved by some machine at the smallest possible cost. <br> It would take too much memory and processing time to compute the exact earth mover's distance, so <b>CalculateImageOverlap</b> chooses representative foreground pixels in each image and assigns each foreground pixel to its closest representative. The earth mover's distance is then computed for moving the foreground pixels associated with each representative in the test image to those in the reference image. """) self.max_points = cps.Integer("Maximum # of points", value=250, minval=100, doc=""" <i>(Used only when computing the earth mover's distance)</i> <br> This is the number of representative points that will be taken from the foreground of the test image and from the foreground of the reference image using the point selection method (see below). """) self.decimation_method = cps.Choice("Point selection method", choices=[DM_KMEANS, DM_SKEL], doc=""" <i>(Used only when computing the earth mover's distance)</i> <br> The point selection setting determines how the representative points are chosen. <ul> <li><i>%(DM_KMEANS)s:</i> Select to pick representative points using a K-Means clustering technique. The foregrounds of both images are combined and representatives are picked that minimize the distance to the nearest representative. The same representatives are then used for the test and reference images.</li> <li><i>%(DM_SKEL)s:</i> Select to skeletonize the image and pick points eqidistant along the skeleton. </li> </ul> <dl> <dd><img src="memory:%(PROTIP_RECOMEND_ICON)s"> <i>%(DM_KMEANS)s</i> is a choice that's generally applicable to all images. <i>%(DM_SKEL)s</i> is best suited to long, skinny objects such as worms or neurites.</dd> </dl> """ % globals()) self.max_distance = cps.Integer("Maximum distance", value=250, minval=1, doc=""" <i>(Used only when computing the earth mover's distance)</i> <br> This setting sets an upper bound to the distance penalty assessed during the movement calculation. As an example, the score for moving 10 pixels from one location to a location that is 100 pixels away is 10*100, but if the maximum distance were set to 50, the score would be 10*50 instead. <br> The maximum distance should be set to the largest reasonable distance that pixels could be expected to move from one image to the next. """) self.penalize_missing = cps.Binary("Penalize missing pixels", value=False, doc=""" <i>(Used only when computing the earth mover's distance)</i> <br> If one image has more foreground pixels than the other, the earth mover's distance is not well-defined because there is no destination for the extra source pixels or vice-versa. It's reasonable to assess a penalty for the discrepancy when comparing the accuracy of a segmentation because the discrepancy represents an error. It's also reasonable to assess no penalty if the goal is to compute the cost of movement, for example between two frames in a time-lapse movie, because the discrepancy is likely caused by noise or artifacts in segmentation. Set this setting to "Yes" to assess a penalty equal to the maximum distance times the absolute difference in number of foreground pixels in the two images. Set this setting to "No" to assess no penalty. """)
def get_command_settings(self, command, d): '''Get the settings associated with the current command d - the dictionary that persists the setting. None = regular ''' key = command.get_unicode_value() if not d.has_key(key): try: module_info = command.get_selected_leaf()[2] except cps.ValidationError: logger.info("Could not find command %s" % key) return [] result = [] inputs = module_info.getInputs() for module_item in inputs: field_type = module_item.getType() label = module_item.getLabel() if label is None: label = module_item.getName() if module_item.isOutput(): # if both, qualify which is for input and which for output label = "%s (Input)" % label minimum = module_item.getMinimumValue() maximum = module_item.getMaximumValue() default = module_item.loadValue() description = module_item.getDescription() if field_type == ij2.FT_BOOL: value = (J.is_instance_of(default, 'java/lang/Boolean') and J.call(default, "booleanValue", "()Z")) setting = cps.Binary(label, value=value, doc=description) elif field_type == ij2.FT_INTEGER: if J.is_instance_of(default, 'java/lang/Number'): value = J.call(default, "intValue", "()I") elif minimum is not None: value = minimum elif maximum is not None: value = maximum else: value = 0 setting = cps.Integer(label, value=value, doc=description) elif field_type == ij2.FT_FLOAT: if J.is_instance_of(default, 'java/lang/Number'): value = J.call(default, "doubleValue", "()D") elif minimum is not None: value = minimum elif maximum is not None: value = maximum else: value = 0 setting = cps.Float(label, value=value, doc=description) elif field_type == ij2.FT_STRING: choices = module_item.getChoices() value = J.to_string(default) if choices is not None: choices = J.get_collection_wrapper(choices) setting = cps.Choice(label, choices, value, doc=description) else: setting = cps.Text(label, value, doc=description) elif field_type == ij2.FT_COLOR: value = "#ffffff" setting = cps.Color(label, value, doc=description) elif field_type == ij2.FT_IMAGE: setting = cps.ImageNameSubscriber(label, "InputImage", doc=description) elif field_type == ij2.FT_TABLE: setting = IJTableSubscriber(label, "InputTable", doc=description) elif field_type == ij2.FT_FILE: setting = cps.FilenameText(label, None, doc=description) else: continue result.append((setting, module_item)) for output in module_info.getOutputs(): field_type = output.getType() label = output.getLabel() if label is None: label = output.getName() if output.isInput(): # if both, qualify which is for input and which for output label = "%s (Output)" % label if field_type == ij2.FT_IMAGE: result.append( (cps.ImageNameProvider(label, "ImageJImage", doc=description), output)) elif field_type == ij2.FT_TABLE: result.append((IJTableProvider(label, "ImageJTable", doc=description), output)) d[key] = result else: result = d[key] return [setting for setting, module_info in result]
def create_settings(self): self.sub_object_name = cps.ObjectNameSubscriber( 'Select the input child objects', cps.NONE, doc=""" Child objects are defined as those objects contained within the parent object. For example, when relating speckles to the nuclei that contains them, the speckles are the children.""") self.parent_name = cps.ObjectNameSubscriber( 'Select the input parent objects', cps.NONE, doc=""" Parent objects are defined as those objects which encompass the child object. For example, when relating speckles to the nuclei that contains them, the nuclei are the parents.""") self.find_parent_child_distances = cps.Choice( "Calculate child-parent distances?", D_ALL, doc=""" Choose the method to calculate distances of each child to its parent. <ul> <li><i>%(D_NONE)s:</i> Do not calculate any distances.</li> <li><i>%(D_MINIMUM)s:</i> The distance from the centroid of the child object to the closest perimeter point on the parent object.</li> <li><i>%(D_CENTROID)s:</i> The distance from the centroid of the child object to the centroid of the parent. </li> <li><i>%(D_BOTH)s:</i> Calculate both the <i>%(D_MINIMUM)s</i> and <i>%(D_CENTROID)s</i> distances.</li> </ul>""" % globals()) self.wants_step_parent_distances = cps.Binary( "Calculate distances to other parents?", False, doc=""" <i>(Used only if calculating distances)</i><br> Select <i>%(YES)s</i> to calculate the distances of the child objects to some other objects. These objects must be either parents or children of your parent object in order for this module to determine the distances. For instance, you might find "Nuclei" using <b>IdentifyPrimaryObjects</b>, find "Cells" using <b>IdentifySecondaryObjects</b> and find "Cytoplasm" using <b>IdentifyTertiaryObjects</b>. You can use <b>Relate</b> to relate speckles to cells and then measure distances to nuclei and cytoplasm. You could not use <b>RelateObjects</b> to relate speckles to cytoplasm and then measure distances to nuclei, because nuclei is neither a direct parent or child of cytoplasm.""" % globals()) self.step_parent_names = [] self.add_step_parent(can_delete=False) self.add_step_parent_button = cps.DoSomething("", "Add another parent", self.add_step_parent) self.wants_per_parent_means = cps.Binary( 'Calculate per-parent means for all child measurements?', False, doc=""" Select <i>%(YES)s</i> to calculate the per-parent mean values of every upstream measurement made with the children objects and stores them as a measurement for the parent; the nomenclature of this new measurements is "Mean_<child>_<category>_<feature>". For this reason, this module should be placed <i>after</i> all <b>Measure</b> modules that make measurements of the children objects.""" % globals())
def create_settings(self): '''Create the settings for the module''' logger.debug("Creating RunImageJ module settings") J.activate_awt() logger.debug("Activated AWT") self.command_or_macro = cps.Choice("Run an ImageJ command or macro?", [CM_COMMAND, CM_MACRO], doc=""" This setting determines whether <b>RunImageJ</b> runs either a: <ul> <li><i>%(CM_COMMAND)s:</i> Select from a list of available ImageJ commands (those items contained in the ImageJ menus); or</li> <li><i>%(CM_MACRO)s:</i> A series of ImageJ commands/plugins that you write yourself.</li> </ul>""" % globals()) # # Load the commands in visible_settings so that we don't call # ImageJ unless someone tries the module # self.command = self.make_command_choice("Command", doc=""" <i>(Used only if running a %(CM_COMMAND)s)</i><br> The command to execute when the module runs.""" % globals()) self.command_settings_dictionary = {} self.command_settings = [] self.command_settings_count = cps.HiddenCount( self.command_settings, "Command settings count") self.pre_command_settings_dictionary = {} self.pre_command_settings = [] self.pre_command_settings_count = cps.HiddenCount( self.pre_command_settings, "Prepare group command settings count") self.post_command_settings_dictionary = {} self.post_command_settings = [] self.post_command_settings_count = cps.HiddenCount( self.post_command_settings, "Post-group command settings count") self.macro = cps.Text("Macro", """import imagej.command.CommandService; cmdSvcClass = CommandService.class; cmdSvc = ImageJ.getService(cmdSvcClass); cmdSvc.run("imagej.core.commands.assign.InvertDataValues", new Object [] {"allPlanes", true}).get();""", multiline=True, doc=""" <i>(Used only if running a %(CM_MACRO)s)</i><br> This is the ImageJ macro to be executed. The syntax for ImageJ macros depends on the scripting language engine chosen. We suggest that you use the Beanshell scripting language <a href="http://www.beanshell.org/manual/contents.html"> (Beanshell documentation)</a>.""" % globals()) all_engines = ij2.get_script_service(get_context()).getLanguages() self.language_dictionary = dict([(engine.getLanguageName(), engine) for engine in all_engines]) self.macro_language = cps.Choice( "Macro language", choices=self.language_dictionary.keys(), doc=""" This setting chooses the scripting language used to execute any macros in this module""") self.wants_to_set_current_image = cps.Binary( "Input the currently active image in ImageJ?", True, doc=""" Check this setting if you want to set the currently active ImageJ image using an image from a prior CellProfiler module. <p>Leave it unchecked to use the currently active image in ImageJ. You may want to do this if you have an output image from a prior <b>RunImageJ</b> that you want to perform further operations upon before retrieving the final result back to CellProfiler.</p>""") self.current_input_image_name = cps.ImageNameSubscriber( "Select the input image", doc=""" <i>(Used only if setting the currently active image)</i><br> This is the CellProfiler image that will become ImageJ's currently active image. The ImageJ commands and macros in this module will perform their operations on this image. You may choose any image produced by a prior CellProfiler module.""") self.wants_to_get_current_image = cps.Binary( "Retrieve the currently active image from ImageJ?", True, doc=""" Check this setting if you want to retrieve ImageJ's currently active image after running the command or macro. <p>Leave the setting unchecked if the pipeline does not need to access the current ImageJ image. For example, you might want to run further ImageJ operations with additional <b>RunImageJ</b> upon the current image prior to retrieving the final image back to CellProfiler.</p>""") self.current_output_image_name = cps.ImageNameProvider( "Name the current output image", "ImageJImage", doc=""" <i>(Used only if retrieving the currently active image from ImageJ)</i><br> This is the CellProfiler name for ImageJ's current image after processing by the command or macro. The image will be a snapshot of the current image after the command has run, and will be available for processing by subsequent CellProfiler modules.""" ) self.pause_before_proceeding = cps.Binary( "Wait for ImageJ before continuing?", False, doc=""" Some ImageJ commands and macros are interactive; you may want to adjust the image in ImageJ before continuing. Check this box to stop CellProfiler while you adjust the image in ImageJ. Leave the box unchecked to immediately use the image. <p>This command will not wait if CellProfiler is executed in batch mode. See <i>%(BATCH_PROCESSING_HELP_REF)s</i> for more details on batch processing.</p>""" % globals()) self.prepare_group_choice = cps.Choice( "Function to run before each group of images?", [CM_NOTHING, CM_COMMAND, CM_MACRO], doc=""" You can run an ImageJ macro or a command <i>before</i> each group of images. This can be useful in order to set up ImageJ before processing a stack of images. Choose <i>%(CM_NOTHING)s</i> if you do not want to run a command or macro, <i>%(CM_COMMAND)s</i> to choose a command to run or <i>%(CM_MACRO)s</i> to run a macro. """ % globals()) logger.debug("Finding ImageJ commands") self.prepare_group_command = self.make_command_choice("Command", doc=""" <i>(Used only if running a command before an image group)</i><br> Select the command to execute before processing a group of images.""" ) self.prepare_group_macro = cps.Text("Macro", 'run("Invert");', multiline=True, doc=""" <i>(Used only if running a macro before an image group)</i><br> This is the ImageJ macro to be executed before processing a group of images. For help on writing macros, see <a href="http://rsb.info.nih.gov/ij/developer/macro/macros.html">here</a>.""" ) self.post_group_choice = cps.Choice( "Function to run after each group of images?", [CM_NOTHING, CM_COMMAND, CM_MACRO], doc=""" You can run an ImageJ macro or a command <i>after</i> each group of images. This can be used to do some sort of operation on a whole stack of images that have been accumulated by the group operation. Choose <i>%(CM_NOTHING)s</i> if you do not want to run a command or macro, <i>%(CM_COMMAND)s</i> to choose a command to run or <i>%(CM_MACRO)s</i> to run a macro. """ % globals()) self.post_group_command = self.make_command_choice("Command", doc=""" <i>(Used only if running a command after an image group)</i><br> The command to execute after processing a group of images.""") self.post_group_macro = cps.Text("Macro", 'run("Invert");', multiline=True, doc=""" <i>(Used only if running a macro after an image group)</i><br> This is the ImageJ macro to be executed after processing a group of images. For help on writing macros, see <a href="http://rsb.info.nih.gov/ij/developer/macro/macros.html">here</a>.""" ) self.wants_post_group_image = cps.Binary( "Retrieve the image output by the group operation?", False, doc=""" You can retrieve the image that is currently active in ImageJ at the end of macro processing and use it later in CellProfiler. The image will only be available during the last cycle of the image group. Check this setting to use the active image in CellProfiler or leave it unchecked if you do not want to use the active image. """) self.post_group_output_image = cps.ImageNameProvider( "Name the group output image", "ImageJGroupImage", doc=""" <i>(Used only if retrieving an image after an image group operation)</i><br> This setting names the output image produced by the ImageJ command or macro that CellProfiler runs after processing all images in the group. The image is only available at the last cycle in the group""", provided_attributes={ cps.AGGREGATE_IMAGE_ATTRIBUTE: True, cps.AVAILABLE_ON_LAST_ATTRIBUTE: True }) self.show_imagej_button = cps.DoSomething("Show ImageJ", "Show", self.on_show_imagej, doc=""" Press this button to show the ImageJ user interface. You can use the user interface to run ImageJ commands or set up ImageJ before a CellProfiler run.""") logger.debug("Finished creating settings")
def create_settings(self): self.image_name = cps.ImageNameSubscriber( "Select the input image", cps.NONE, doc='''Select the image to be rescaled.''') self.rescaled_image_name = cps.ImageNameProvider( "Name the output image", "RescaledBlue", doc='''Enter the name of output rescaled image.''') self.rescale_method = cps.Choice('Rescaling method', choices=M_ALL, doc=''' There are a number of options for rescaling the input image: <ul> <li><i>%(M_STRETCH)s:</i> Find the minimum and maximum values within the unmasked part of the image (or the whole image if there is no mask) and rescale every pixel so that the minimum has an intensity of zero and the maximum has an intensity of one.</li> <li><i>%(M_MANUAL_INPUT_RANGE)s:</i> Pixels are scaled from their user-specified original range to the range 0 to 1. Options are available to handle values outside of the original range.<br> To convert 12-bit images saved in 16-bit format to the correct range, use the range 0 to 0.0625. The value 0.0625 is equivalent to 2<sup>12</sup> divided by 2<sup>16</sup>, so it will convert a 16 bit image containing only 12 bits of data to the proper range.</li> <li><i>%(M_MANUAL_IO_RANGE)s:</i> Pixels are scaled from their original range to the new target range. Options are available to handle values outside of the original range.</li> <li><i>%(M_DIVIDE_BY_IMAGE_MINIMUM)s:</i> Divide the intensity value of each pixel by the image's minimum intensity value so that all pixel intensities are equal to or greater than 1. The rescaled image can serve as an illumination correction function in <b>CorrectIlluminationApply</b>.</li> <li><i>%(M_DIVIDE_BY_IMAGE_MAXIMUM)s:</i> Divide the intensity value of each pixel by the image's maximum intensity value so that all pixel intensities are less than or equal to 1.</li> <li><i>%(M_DIVIDE_BY_VALUE)s:</i> Divide the intensity value of each pixel by the value entered.</li> <li><i>%(M_DIVIDE_BY_MEASUREMENT)s:</i> The intensity value of each pixel is divided by some previously calculated measurement. This measurement can be the output of some other module or can be a value loaded by the <b>Metadata</b> module.</li> <li><i>%(M_SCALE_BY_IMAGE_MAXIMUM)s:</i> Scale an image so that its maximum value is the same as the maximum value within the reference image.</li> <li><i>%(M_CONVERT_TO_8_BIT)s:</i> Images in CellProfiler are normally stored as a floating point number in the range of 0 to 1. This option converts these images to class uint8, meaning an 8 bit integer in the range of 0 to 255, reducing the amount of memory required to store the image. <i>Warning:</i> Most CellProfiler modules require the incoming image to be in the standard 0 to 1 range, so this conversion may cause downstream modules to behave in unexpected ways.</li> </ul>''' % globals()) self.wants_automatic_low = cps.Choice( 'Method to calculate the minimum intensity', LOW_ALL, doc=""" <i>(Used only if "%(M_MANUAL_IO_RANGE)s" is selected)</i><br> This setting controls how the minimum intensity is determined. <ul> <li><i>%(CUSTOM_VALUE)s:</i> Enter the minimum intensity manually below.</li> <li><i>%(LOW_EACH_IMAGE)s</i>: use the lowest intensity in this image as the minimum intensity for rescaling</li> <li><i>%(LOW_ALL_IMAGES)s</i>: use the lowest intensity from all images in the image group or the experiment if grouping is not being used. <b>Note:</b> Choosing this option may have undesirable results for a large ungrouped experiment split into a number of batches. Each batch will open all images from the chosen channel at the start of the run. This sort of synchronized action may have a severe impact on your network file system.</li> </ul> """ % globals()) self.wants_automatic_high = cps.Choice( 'Method to calculate the maximum intensity', HIGH_ALL, doc=""" <i>(Used only if "%(M_MANUAL_IO_RANGE)s" is selected)</i><br> This setting controls how the maximum intensity is determined. <ul> <li><i>%(CUSTOM_VALUE)s</i>: Enter the maximum intensity manually below.</li> <li><i>%(HIGH_EACH_IMAGE)s</i>: Use the highest intensity in this image as the maximum intensity for rescaling</li> <li><i>%(HIGH_ALL_IMAGES)s</i>: Use the highest intensity from all images in the image group or the experiment if grouping is not being used. <b>Note:</b> Choosing this option may have undesirable results for a large ungrouped experiment split into a number of batches. Each batch will open all images from the chosen channel at the start of the run. This sort of synchronized action may have a severe impact on your network file system.</li> </ul> """ % globals()) self.source_low = cps.Float( 'Lower intensity limit for the input image', 0) self.source_high = cps.Float( 'Upper intensity limit for the input image', 1) self.source_scale = cps.FloatRange( 'Intensity range for the input image', (0, 1)) self.dest_scale = cps.FloatRange( 'Intensity range for the output image', (0, 1)) self.low_truncation_choice = cps.Choice( 'Method to rescale pixels below the lower limit', [R_MASK, R_SET_TO_ZERO, R_SET_TO_CUSTOM, R_SCALE], doc=''' <i>(Used only if "%(M_MANUAL_IO_RANGE)s" is selected)</i><br> There are several ways to handle values less than the lower limit of the intensity range: <ul> <li><i>%(R_MASK)s:</i> Creates a mask for the output image. All pixels below the lower limit will be masked out.</li> <li><i>%(R_SET_TO_ZERO)s:</i> Sets all pixels below the lower limit to zero.</li> <li><i>%(R_SET_TO_CUSTOM)s:</i> Sets all pixels below the lower limit to a custom value.</li> <li><i>%(R_SCALE)s:</i> Scales pixels with values below the lower limit using the same offset and divisor as other pixels. The results will be less than zero.</li> </ul>''' % globals()) self.custom_low_truncation = cps.Float( "Custom value for pixels below lower limit", 0, doc=""" <i>(Used only if "%(M_MANUAL_IO_RANGE)s" and "%(R_SET_TO_CUSTOM)s are selected)</i><br> enter the custom value to be assigned to pixels with values below the lower limit.""" % globals()) self.high_truncation_choice = cps.Choice( 'Method to rescale pixels above the upper limit', [R_MASK, R_SET_TO_ONE, R_SET_TO_CUSTOM, R_SCALE], doc=""" <i>(Used only if "%(M_MANUAL_IO_RANGE)s" is selected)</i><br> There are several ways to handle values greater than the upper limit of the intensity range; Options are described in the Help for the equivalent lower limit question.""" ) self.custom_high_truncation = cps.Float( "Custom value for pixels below upper limit", 0, doc=""" <i>(Used only if "%(M_MANUAL_IO_RANGE)s" and "%(R_SET_TO_CUSTOM)s are selected)</i><br> Enter the custom value to be assigned to pixels with values above the upper limit.""" ) self.matching_image_name = cps.ImageNameSubscriber( "Select image to match in maximum intensity", cps.NONE, doc=""" <i>(Used only if "%(M_SCALE_BY_IMAGE_MAXIMUM)s" is selected)</i><br> Select the image whose maximum you want the rescaled image to match.""" % globals()) self.divisor_value = cps.Float("Divisor value", 1, minval=np.finfo(float).eps, doc=""" <i>(Used only if "%(M_DIVIDE_BY_VALUE)s" is selected)</i><br> Enter the value to use as the divisor for the final image.""" % globals()) self.divisor_measurement = cps.Measurement("Divisor measurement", lambda: cpmeas.IMAGE, doc=""" <i>(Used only if "%(M_DIVIDE_BY_MEASUREMENT)s" is selected)</i><br> Select the measurement value to use as the divisor for the final image.""" % globals())
def add_single_measurement(self, can_delete=True): '''Add a single measurement to the group of single measurements can_delete - True to include a "remove" button, False if you're not allowed to remove it. ''' group = cps.SettingsGroup() if can_delete: group.append("divider", cps.Divider(line=True)) group.append( "object_name", cps.ObjectNameSubscriber( "Select the object to be classified", "None", doc="""The name of the objects to be classified. You can choose from objects created by any previous module. See <b>IdentifyPrimaryObjects</b>, <b>IdentifySecondaryObjects</b>, or <b>IdentifyTertiaryObjects</b>.""")) def object_fn(): return group.object_name.value group.append( "measurement", cps.Measurement( "Select the measurement to classify by", object_fn, doc= """Select a measurement made by a previous module. The objects will be classified according to their values for this measurement.""")) group.append( "bin_choice", cps.Choice( "Select bin spacing", [BC_EVEN, BC_CUSTOM], doc="""You can either specify bins of equal size, bounded by upper and lower limits, or you can specify custom values that define the edges of each bin with a threshold. <i>Note:</i> If you would like two bins, choose <i>Custom-defined bins</i> and then provide a single threshold when asked. <i>Evenly spaced bins</i> creates the indicated number of bins at evenly spaced intervals between the low and high threshold. You also have the option to create bins for objects that fall below or above the low and high threhsold""")) group.append( "bin_count", cps.Integer( "Number of bins", 3, minval=1, doc="""This is the number of bins that will be created between the low and high threshold""")) group.append( "low_threshold", cps.Float( "Lower threshold", 0, doc= """<i>(Used only if Evenly spaced bins selected)</i><br>This is the threshold that separates the lowest bin from the others. The lower threshold, upper threshold, and number of bins define the thresholds of bins between the lowest and highest.""")) group.append( "wants_low_bin", cps.Binary( "Use a bin for objects below the threshold?", False, doc="""Check this box if you want to create a bin for objects whose values fall below the low threshold. Leave the box unchecked if you do not want a bin for these objects.""")) def min_upper_threshold(): return group.low_threshold.value + np.finfo(float).eps group.append( "high_threshold", cps.Float( "Upper threshold", 1, minval=cps.NumberConnector(min_upper_threshold), doc= """<i>(Used only if Evenly spaced bins selected)</i><br> This is the threshold that separates the last bin from the others. <i>Note:</i> If you would like two bins, choose <i>Custom-defined bins</i>.""" )) group.append( "wants_high_bin", cps.Binary( "Use a bin for objects above the threshold?", False, doc="""Check this box if you want to create a bin for objects whose values are above the high threshold. Leave the box unchecked if you do not want a bin for these objects.""")) group.append( "custom_thresholds", cps.Text( "Enter the custom thresholds separating the values between bins", "0,1", doc=""" <i>(Used only if Custom thresholds selected)</i><br> This setting establishes the threshold values for the bins. You should enter one threshold between each bin, separating thresholds with commas (for example, <i>0.3, 1.5, 2.1</i> for four bins). The module will create one more bin than there are thresholds.""")) group.append( "wants_custom_names", cps.Binary( "Give each bin a name?", False, doc="""This option lets you assign custom names to bins you have specified. If you leave this unchecked, the module will assign names based on the measurements and the bin number.""")) group.append( "bin_names", cps.Text("Enter the bin names separated by commas", "None", doc=""" <i>(Used only if Give each bin a name? is checked)</i><br> Enter names for each of the bins, separated by commas. An example including three bins might be <i>First,Second,Third</i>.""" )) group.append( "wants_images", cps.Binary( "Retain an image of the objects classified by their measurements, for use later in the pipeline (for example, in SaveImages)?", False)) group.append( "image_name", cps.ImageNameProvider("Name the output image", "ClassifiedNuclei")) group.can_delete = can_delete def number_of_bins(): '''Return the # of bins in this classification''' if group.bin_choice == BC_EVEN: value = group.bin_count.value else: value = len(group.custom_thresholds.value.split(",")) - 1 if group.wants_low_bin: value += 1 if group.wants_high_bin: value += 1 return value group.number_of_bins = number_of_bins def measurement_name(): '''Get the measurement name to use inside the bin name Account for conflicts with previous measurements ''' measurement_name = group.measurement.value other_same = 0 for other in self.single_measurements: if id(other) == id(group): break if other.measurement.value == measurement_name: other_same += 1 if other_same > 0: measurement_name += str(other_same) return measurement_name def bin_feature_names(): '''Return the feature names for each bin''' if group.wants_custom_names: return [ name.strip() for name in group.bin_names.value.split(",") ] return [ '_'.join((measurement_name(), 'Bin_%d' % (i + 1))) for i in range(number_of_bins()) ] group.bin_feature_names = bin_feature_names def validate_group(): bin_name_count = len(bin_feature_names()) bin_count = number_of_bins() if bin_count < 1: bad_setting = (group.bin_count if group.bin_choice == BC_EVEN else group.custom_thresholds) raise cps.ValidationError( "You must have at least one bin in order to take measurements. " "Either add more bins or ask for bins for objects above or below threshold", bad_setting) if bin_name_count != number_of_bins(): raise cps.ValidationError( "The number of bin names (%d) does not match the number of bins (%d)." % (bin_name_count, bin_count), group.bin_names) if group.bin_choice == BC_CUSTOM: try: [ float(x.strip()) for x in group.custom_thresholds.value.split(",") ] except ValueError: raise cps.ValidationError( 'Custom thresholds must be a comma-separated list ' 'of numbers (example: "1.0, 2.3, 4.5")', group.custom_thresholds) group.validate_group = validate_group if can_delete: group.remove_settings_button = cps.RemoveSettingButton( "", "Remove the above classification", self.single_measurements, group) self.single_measurements.append(group)
def add_flag(self, can_delete=True): group = cps.SettingsGroup() group.append("divider1", cps.Divider(line=False)) group.append("measurement_settings", []) group.append("measurement_count", cps.HiddenCount(group.measurement_settings)) group.append( "category", cps.Text("Name the flag's category", "Metadata", doc=''' Name a measurement category in which the flag should reside. Metadata allows you to later group images in the <b>LoadImages</b> module based on the flag, if you load the flag data in a future pipeline via the <b>LoadData</b> module. Otherwise, you might choose to have the flag stored in the "Image" category or using some other word you prefer. The flag is stored as a per-image measurement whose name is a combination of the flag's category and feature name, underscore delimited. For instance, if the measurement category is "Metadata" and the feature name is "QCFlag", then the default measurement name would be "Metadata_QCFlag". %s''' % USING_METADATA_HELP_REF)) group.append( "feature_name", cps.Text("Name the flag", "QCFlag", doc=''' The flag is stored as a per-image measurement whose name is a combination of the flag's category and feature name, underscore delimited. For instance, if the measurement category is "Metadata" and the feature name is "QCFlag", then the default measurement name would be "Metadata_QCFlag".''' )) group.append( "combination_choice", cps.Choice( "Flag if any, or all, measurement(s) fails to meet the criteria?", [C_ANY, C_ALL], doc=''' <ul> <li><i>Any:</i> An image will be flagged if any of its measurements fail. This can be useful for flagging images possessing multiple QC flaws; for example, you can flag all bright images and all out of focus images with one flag.</li> <li><i>All:</i> A flag will only be assigned if all measurements fail. This can be useful for flagging images that possess only a combination of QC flaws; for example, you can flag only images that are both bright and out of focus.</li> </ul>''')) group.append( "wants_skip", cps.Binary( "Skip image set if flagged?", False, doc="""You can skip the remainder of the pipeline for image sets that are flagged by checking this setting. If you check this setting, CellProfiler will not run subsequent modules in the pipeline on the images in any image set that is flagged. CellProfiler will continue to process the pipeline if you leave the setting unchecked.<p> You may want to check this setting in order to filter out unwanted images during processing. For instance, you may want to exclude out of focus images when running <b>CorrectIllumination_Calculate</b>. You can do this with a pipeline that measures image quality and flags inappropriate images before it runs <b>CorrectIllumination_Calculate</b>""")) group.append( "add_measurement_button", cps.DoSomething("", "Add another measurement", self.add_measurement, group)) self.add_measurement(group, False if not can_delete else True) if can_delete: group.append( "remover", cps.RemoveSettingButton("", "Remove this flag", self.flags, group)) group.append("divider2", cps.Divider(line=True)) self.flags.append(group)
def create_settings(self): """Create the settings for the module Create the settings for the module during initialization. """ self.contrast_choice = cps.Choice( "Should each classification decision be based on a single measurement or on the combination of a pair of measurements?", [BY_SINGLE_MEASUREMENT, BY_TWO_MEASUREMENTS], doc="""This setting controls how classifications are recorded:<br> <ul><li><i>Single measurements</i>: Classifies each object based on a single measurement.</li> <li><i>Pair of measurements</i>: Classifies each object based on a pair of measurements taken together (that is, an object must meet two criteria to belong to a class).</li></ul>""" ) ############### Single measurement settings ################## # # A list holding groupings for each of the single measurements # to be done # self.single_measurements = [] # # A count of # of measurements # self.single_measurement_count = cps.HiddenCount( self.single_measurements) # # Add one single measurement to start off # self.add_single_measurement(False) # # A button to press to get another measurement # self.add_measurement_button = cps.DoSomething( "", "Add another classification", self.add_single_measurement) # ############### Two-measurement settings ##################### # # The object for the contrasting method # self.object_name = cps.ObjectNameSubscriber( "Enter the object name", "None", doc="""Select the object that you want to measure from the list. This should be an object created by a previous module such as <b>IdentifyPrimaryObjects</b>, <b>IdentifySecondaryObjects</b>, or <b>IdentifyTertiaryObjects</b>.""") # # The two measurements for the contrasting method # def object_fn(): return self.object_name.value self.first_measurement = cps.Measurement( "Select the first measurement", object_fn, doc="""Select a measurement made on the above object. This is the first of two measurements that will be contrasted together. The measurement should be one made on the object in a prior module.""") self.first_threshold_method = cps.Choice( "Method to select the cutoff", [TM_MEAN, TM_MEDIAN, TM_CUSTOM], doc="""Objects are classified as being above or below a cutoff value for a measurement. You can set this cutoff threshold in one of three ways:<br> <ul><li><i>Mean</i>: At the mean of the measurement's value for all objects in the image cycle.</li> <li><i>Median</i>: At the median of the measurement's value for all objects in the image set.</li> <li><i>Custom</i>: You specify a custom threshold value.</li></ul>""" ) self.first_threshold = cps.Float( "Enter the cutoff value", .5, doc="""This is the cutoff value separating objects in the two classes.""") self.second_measurement = cps.Measurement( "Select the second measurement", object_fn, doc="""Select a measurement made on the above object. This is the second of two measurements that will be contrasted together. The measurement should be one made on the object in a prior module.""") self.second_threshold_method = cps.Choice( "Method to select the cutoff", [TM_MEAN, TM_MEDIAN, TM_CUSTOM], doc="""Objects are classified as being above or below a cutoff value for a measurement. You can set this cutoff threshold in one of three ways:<br> <ul><li><i>Mean</i>: At the mean of the measurement's value for all objects in the image cycle.</li> <li><i>Median</i>: At the median of the measurement's value for all objects in the image set.</li> <li><i>Custom</i>: You specify a custom threshold value.</li></ul>""" ) self.second_threshold = cps.Float( "Enter the cutoff value", .5, doc="""This is the cutoff value separating objects in the two classes.""") self.wants_custom_names = cps.Binary( "Use custom names for the bins?", False, doc="""Check this if you want to specify the names of each bin measurement. If you leave the box unchecked, the module will create names based on the measurements. (For instance, for "Intensity_MeanIntensity_Green" and "Intensity_TotalIntensity_Blue", the module generates measurements such as "Classify_Intensity_MeanIntensity_Green_High_Intensity_TotalIntensity_Low").""" ) self.low_low_custom_name = cps.Text("Enter the low-low bin name", "low_low", doc=""" <i>(Used only if using a pair of measurements)</i><br> Name of the measurement for objects that fall below the threshold for both measurements.""") self.low_high_custom_name = cps.Text("Enter the low-high bin name", "low_high", doc=""" <i>(Used only if using a pair of measurements)</i><br> Name of the measurement for objects whose first measurement is below threshold and whose second measurement is above threshold.""") self.high_low_custom_name = cps.Text("Enter the high-low bin name", "high_low", doc=""" <i>(Used only if using a pair of measurements)</i><br> Name of the measurement for objects whose first measurement is above threshold and whose second measurement is below threshold.""") self.high_high_custom_name = cps.Text("Enter the high-high bin name", "high_high", doc=""" <i>(Used only if using a pair of measurements)</i><br> Name of the measurement for objects that are above the threshold for both measurements.""") self.wants_image = cps.Binary( "Retain an image of the objects classified by their measurements, for use later in the pipeline (for example, in SaveImages)?", False) self.image_name = cps.ImageNameProvider( "Enter the image name", "None", doc="""Name that will be associated with the graph image. You can specify this name in a <b>SaveImages</b> module if you want to save the image.""")
def create_settings(self): '''Create the initial settings and name the module''' self.target_name = cps.ObjectNameProvider('Name the output objects', 'FilteredBlue', doc=""" What do you want to call the filtered objects? This will be the name for the collection of objects that are retained after applying the filter(s).""" ) self.object_name = cps.ObjectNameSubscriber( 'Select the object to filter', 'None', doc=""" What object would you like to filter? This setting also controls which measurement choices appear for filtering: you can only filter based on measurements made on the object you select. If you intend to use a measurement calculated by the <b>CalculateMath</b> module to to filter objects, select the first operand's object here, because <b>CalculateMath</b> measurements are stored with the first operand's object.""") self.spacer_1 = cps.Divider(line=False) self.mode = cps.Choice( 'Select the filtering mode', [MODE_MEASUREMENTS, MODE_RULES, MODE_BORDER], doc="""You can choose from the following options: <ul> <li><i>%(MODE_MEASUREMENTS)s</i>: Specify a per-object measurement made by an upstream module in the pipeline.</li> <li><i>%(MODE_RULES)s</i>: Use a file containing rules generated by CellProfiler Analyst. You will need to ensure that the measurements specified by the rules file are produced by upstream modules in the pipeline.</li> <li><i>%(MODE_BORDER)s</i>: Remove objects touching the border of the image and/or the edges of an image mask.</li> </ul>""" % globals()) self.spacer_2 = cps.Divider(line=False) self.measurements = [] self.measurement_count = cps.HiddenCount(self.measurements, "Measurement count") self.add_measurement(False) self.add_measurement_button = cps.DoSomething( "Add another measurement", "Add", self.add_measurement) self.filter_choice = cps.Choice("Select the filtering method", FI_ALL, FI_LIMITS, doc=""" <i>(Used only if filtering using measurements)</i><br> There are five different ways to filter objects: <ul> <li><i>Limits:</i> Keep an object if its measurement value falls within a range you specify.</li> <li><i>Maximal:</i> Keep the object with the maximum value for the measurement of interest. If multiple objects share a maximal value, retain one object selected arbitrarily per image.</li> <li><i>Minimal:</i> Keep the object with the minimum value for the measurement of interest. If multiple objects share a minimal value, retain one object selected arbitrarily per image.</li> <li><i>Maximal per object:</i> This option requires you to choose a parent object. The parent object might contain several child objects of choice (for instance, mitotic spindles within a cell or FISH probe spots within a nucleus). Only the child object whose measurements equal the maximum child-measurement value among that set of child objects will be kept (for example, the longest spindle in each cell). You do not have to explicitly relate objects before using this module.</li> <li><i>Minimal per object:</i> Same as <i>Maximal per object</i>, except filtering is based on the minimum value.</li> </ul>""") self.enclosing_object_name = cps.ObjectNameSubscriber( 'Select the objects that contain the filtered objects', 'None', doc=""" <i>(Used only if a per-object filtering method is selected)</i><br> This setting selects the container (i.e., parent) objects for the <i>Maximal per object</i> and <i>Minimal per object</i> filtering choices.""" ) self.rules_directory = cps.DirectoryPath( "Rules file location", doc="""<i>(Used only when filtering by rules)</i> <br> Select the location of the rules file that will be used for filtering. %(IO_FOLDER_CHOICE_HELP_TEXT)s""" % globals()) def get_rules_class_choices(pipeline): try: rules = self.get_rules() nclasses = len(rules.rules[0].weights[0]) return [str(i) for i in range(1, nclasses + 1)] except: return [str(i) for i in range(1, 3)] self.rules_class = cps.Choice( "Class number", choices=["1", "2"], choices_fn=get_rules_class_choices, doc="""<i>(Used only when filtering by rules)</i> <br> Select which of the classes to keep when filtering. The CellProfiler Analyst classifier user interface lists the names of the classes in order. By default, these are the positive (class 1) and negative (class 2) classes. <b>FilterObjects</b> uses the first class from CellProfiler Analyst if you choose "1", etc.""") def get_directory_fn(): '''Get the directory for the rules file name''' return self.rules_directory.get_absolute_path() def set_directory_fn(path): dir_choice, custom_path = self.rules_directory.get_parts_from_path( path) self.rules_directory.join_parts(dir_choice, custom_path) self.rules_file_name = cps.FilenameText( "Rules file name", "rules.txt", get_directory_fn=get_directory_fn, set_directory_fn=set_directory_fn, doc="""<i>(Used only when filtering using rules)</i> <br>The name of the file holding the rules. Each line of this file should be a rule naming a measurement to be made on the object you selected, for instance:<pre>IF (Nuclei_AreaShape_Area < 351.3, [0.79, -0.79], [-0.94, 0.94])</pre><br><br> The above rule will score +0.79 for the positive category and -0.94 for the negative category for nuclei whose area is less than 351.3 pixels and will score the opposite for nuclei whose area is larger. The filter adds positive and negative and keeps only objects whose positive score is higher than the negative score. <p>Note that if the rules are obtained from CellProfiler Analyst, the objects that are removed are those represented by the second number between the brackets.</p>""" ) self.wants_outlines = cps.Binary( 'Retain outlines of the identified objects?', False) self.outlines_name = cps.OutlineNameProvider('Name the outline image', 'FilteredObjects', doc=''' <i>(Used only if the outline image is to be retained for later use in the pipeline)</i> <br> Choose a name by which the outline image can be selected later in the pipeline. <p><i>Special note on saving images:</i> You can use the settings in this module to pass object outlines along to the module <b>OverlayOutlines</b>, and then save them with the <b>SaveImages</b> module. Also, the identified objects themselves can be passed along to the object processing module <b>ConvertToImage</b> and then saved with the <b>SaveImages</b> module.''' ) self.additional_objects = [] self.additional_object_count = cps.HiddenCount( self.additional_objects, "Additional object count") self.spacer_3 = cps.Divider(line=False) self.additional_object_button = cps.DoSomething( 'Relabel additional objects to match the filtered object?', 'Add an additional object', self.add_additional_object, doc=""" Click this button to add an object to receive the same post-filtering labels as the filtered object. This is useful in making sure that labeling is maintained between related objects (e.g., primary and secondary objects) after filtering.""" )
def create_settings(self): self.filter_choice = cps.Choice("Filter choice", [S_GAUSSIAN, S_SOBEL]) self.input_image_name = cps.ImageNameSubscriber("Input image") self.output_image_name = cps.ImageNameProvider("Output image", "Filtered")