Source code for plugins.imagearray

#
##
##  This file is part of pyFormex 1.0.7  (Mon Jun 17 12:20:39 CEST 2019)
##  pyFormex is a tool for generating, manipulating and transforming 3D
##  geometrical models by sequences of mathematical operations.
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##  Copyright 2004-2019 (C) Benedict Verhegghe (benedict.verhegghe@ugent.be)
##  Distributed under the GNU General Public License version 3 or later.
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##  This program is free software: you can redistribute it and/or modify
##  it under the terms of the GNU General Public License as published by
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##  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
##  GNU General Public License for more details.
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"""Convert bitmap images into numpy arrays.

This module contains functions to convert bitmap images into numpy
arrays and vice versa. There are functions to read image from file
into arrays, and to save image arrays to files. There is even a class
that reads a full stack of Dicom images into a 3D numpy array.

Some of this code was based on ideas found on the PyQwt mailing list.
"""
from __future__ import absolute_import, division, print_function

import numpy as np
import PIL.Image

import pyformex as pf
from pyformex import utils
from pyformex import arraytools as at
from pyformex import gui
from pyformex.gui import QtGui, QImage

QColor = QtGui.QColor

if gui.bindings == 'pyside2':
    QImage.numBytes = QImage.byteCount

####################################################################
# Import/export images using PIL


[docs]def image2array(filename, mode=None, flip=True): """ Read an image file into a numpy array. Parameters ---------- filename: :term:`path_like` The name of the file containing the image. mode: str, optional If provided, the image will be converted to the specified mode. The mode is a string defining the color channels to be returned. Typical values are '1' (black/white), 'L' (grayscale), 'LA' (gray with alpha), 'RGB' (three colors), 'RGBA' (three colors plus alpha). Default is to return the image as it is stored. flip: bool If True, the vertical axis will be inverted. This is the default, because image scanlines are stored from top to bottom, while opengl uses a vertical axis running from bottom to top. Set this to False when using images as fonts in :class:`FontTexture`, because the FontTexture engine itself takes account of the top-down image storage. """ im = PIL.Image.open(filename) if mode and im.mode != mode: im = im.convert(mode) im = np.array(im) if flip: im = np.flipud(im) return im
[docs]def array2image(ar, filename): """ Save an image stored in a numpy array to file. Parameters ---------- ar: array Array holding the pixel data. This is typically an Int8 type array with shape (height, width, 3) where the last axis holds the RGB color data. filename: :term:`path_like` The name of the file where the image is to be saved. """ img = PIL.Image.fromarray(ar) img.save(filename)
def image2string(filename): # defer import for startup efficiency im = PIL.Image.open(filename) nx, ny = im.size[0], im.size[1] try: data = im.tostring("raw", "RGBA", 0, -1) except SystemError: data = im.tostring("raw", "RGBX", 0, -1) return nx, ny, data #################################################################### # Handle images using QImage
[docs]def resizeImage(image, w=0, h=0): """ Load and optionally resize a QImage. Parameters ---------- image: :term:`qimage_like` QImage, or data that can be converted to a QImage, e.g. the name of a raster image file. w: int, optional If provided and >0, the image will be resized to this width. h: int, optional If provided and >0, the image will be resized to this height. Returns ------- QImage A QImage with the requested size (if provided). """ if not isinstance(image, QImage): image = QImage(image) W, H = image.width(), image.height() if w <= 0: w = W if h <= 0: h = H if w != W or h != H: image = image.scaled(w, h) return image
[docs]def qimage2numpy(image, resize=(0, 0), order='RGBA', flip=True, indexed=None): """ Transform a QImage to a :class:`numpy.ndarray`. Parameters ---------- image: :term:`qimage_like` A QImage or any data that can be converted to a QImage, e.g. the name of an image file, in any of the formats supported by Qt. The image can be a full color image or an indexed type. Only 32bit and 8bit images are currently supported. resize: tuple of ints A tuple of two integers (width,height). Positive value will force the image to be resized to this value. order: str String with a permutation/subset of the characters 'RGBA', defining the order in which the colors are returned. Default is RGBA, so that result[...,0] gives the red component. Note however that QImage stores in ARGB order. You may also specify a subset of the 'RGBA' characters, in which case you will only get some of the color components. An often used value is 'RGB' to get the colors without the alpha value. flip: bool If True, the image scanlines are flipped upside down. This is practical because image files are usually stored in top down order, while OpenGL uses an upwards positive direction, requiring a flip to show the image upright. indexed: bool or None. If True, the result will be an indexed image where each pixel color is an index into a color table. Non-indexed image data will be converted. If False, the result will be a full color array specifying the color of each pixel. Indexed images will be expanded to a full color array. If None (default), no conversion is done and the resulting data are dependent on the image format. In all cases both a color and a colortable will be returned, but the latter will be None for non-indexed images. Returns ------- colors: array An int8 array with shape (height,width,ncomp), holding the components of the color of each pixel. Order and number of components is as specified by the ``order`` argument. The default is 4 components in order 'RGBA'. This value is only returned if the image was not an indexed type or if ``indexed=False`` was specified, in which case indexed images will be converted to full color. colorindex: array An int array with shape (height,width) holding color indices into ``colortable``, which stores the actual color values. This value is only returned if the image was an indexed type or if ``indexed=True`` was specified, in which case nonindexed images will be converted to using color index and table. colortable: array or None. An int8 array with shape (ncolors,ncomp). This array stores all the colors used in the image, in the order specified by ``order`` This value is only returned if ``indexed`` is not False. Its value will be None if ``indexed`` is None (default) and the image was not indexed. Notes ----- This table summarizes the return values for each of the possible values of the ``indexed`` argument combined with indexed or nonindexed image data: =============== ====================== ====================== arg non-indexed image indexed image =============== ====================== ====================== indexed=None colors, None colorindex, colortable indexed=False colors colors indexed=True colorindex, colortable colorindex, colortable =============== ====================== ====================== """ image = resizeImage(image, *resize) pf.debug("IMAGE FORMAT %s" % image.format(), pf.DEBUG.IMAGE) if indexed: image = image.convertToFormat(QImage.Format_Indexed8) h, w = image.height(), image.width() if image.format() in (QImage.Format_ARGB32_Premultiplied, QImage.Format_ARGB32, QImage.Format_RGB32): buf = image.bits() if gui.bindings == 'pyqt4': buf = buf.asstring(image.numBytes()) ar = np.frombuffer(buf, dtype='ubyte', count=image.numBytes()).reshape(h, w, 4) idx = ['BGRA'.index(c) for c in order] ar = ar[..., idx] ct = None elif image.format() == QImage.Format_Indexed8: ct = np.array(image.colorTable(), dtype=np.uint32) #print("IMAGE FORMAT is INDEXED with %s colors" % ct.shape[0]) ct = ct.view(np.uint8).reshape(-1, 4) idx = ['BGRA'.index(c) for c in order] ct = ct[..., idx] buf = image.bits() if gui.bindings == 'pyqt4': buf = buf.asstring(image.numBytes()) ar = np.frombuffer(buf, dtype=np.uint8) if ar.size % h == 0: ar = ar.reshape(h, -1) if ar.shape[1] > w: # The QImage buffer always has a size corresponding # with a width that is a multiple of 8. Here we strip # off the padding pixels of the QImage buffer to the # reported width. ar = ar[:, :w] if ar.size != w*h: # This should no longer happen, since we have now adjusted # the numpy buffer width to the correct image width. pf.warning("Size of image data (%s) does not match the reported dimensions: %s x %s = %s" % (ar.size, w, h, w*h)) else: raise ValueError("qimage2numpy only supports 32bit and 8bit images. Your qimage format is %s" % image.format()) # Put upright as expected if flip: ar = np.flipud(ar) # Convert indexed to nonindexed if requested if indexed is False and ct is not None: ar = ct[ar] ct = None # Return only full colors if requested if indexed is False: return ar else: return ar, ct
[docs]def numpy2qimage(array): """ Convert a 2D or 3D integer numpy array into a QImage Parameters ---------- array: 2D or 3D int array If the input array is 2D, the array is converted into a gray image. If the input array is 3D, the last axis should have length 3 or 4 and represents the color channels in order RGB or RGBA. Notes ----- This is equivalent to calling :func:`gray2qimage` for a 2D array and :func:`rgb2qimage` for a 3D array. """ if np.ndim(array) == 2: return gray2qimage(array) elif np.ndim(array) == 3: return rgb2qimage(array) raise ValueError("can only convert 2D or 3D arrays")
[docs]def gray2qimage(gray): """ Convert a 2D numpy array to gray QImage. Parameters ---------- gray: uint8 array (height,width) Array with the grey values of an image with size (height,width). Returns ------- QImage A QImage with the corresponding gray image. The image format will be indexed. """ if len(gray.shape) != 2: raise ValueError("gray2QImage can only convert 2D arrays") gray = np.require(gray, np.uint8, 'C') h, w = gray.shape result = QImage(gray.data, w, h, QImage.Format_Indexed8) result.ndarray = gray for i in range(256): result.setColor(i, QColor(i, i, i).rgb()) return result
[docs]def rgb2qimage(rgb): """ Convert a 3D numpy array into a 32-bit QImage. Parameters ---------- rgb: int array (height,width,ncomp) Int array with the pixel values of the image. The data can have 3 (RGB) or 4 (RGBA) components. Returns ------- QImage A QImage with size (height,width) in the format RGB32 (3 components) or ARGB32 (4 components). """ if len(rgb.shape) != 3: raise ValueError("rgb2QImage expects the first (or last) dimension to contain exactly three (R,G,B) channels") if rgb.shape[2] != 3: raise ValueError("rgb2QImage can only convert 3D arrays") h, w, channels = rgb.shape # Qt expects 32bit BGRA data for color images: bgra = np.empty((h, w, 4), np.uint8, 'C') bgra[..., 0] = rgb[..., 2] bgra[..., 1] = rgb[..., 1] bgra[..., 2] = rgb[..., 0] if channels == 4: bgra[..., 3] = rgb[..., 3] fmt = QImage.Format_ARGB32 else: fmt = QImage.Format_RGB32 result = QImage(bgra.data, w, h, fmt) result.ndarray = bgra return result
[docs]def qimage2glcolor(image, resize=(0, 0)): """ Convert a bitmap image to corresponding OpenGL colors. Parameters ---------- image: :term:`qimage_like` A QImage or any data that can be converted to a QImage, e.g. the name of an image file, in any of the formats supported by Qt. The image can be a full color image or an indexed type. Only 32bit and 8bit images are currently supported. resize: tuple of ints A tuple of two integers (width,height). Positive value will force the image to be resized to this value. Returns ------- float array (w,h,3) Array of float values in the range 0.0 to 1.0, containing the OpenGL colors corresponding to the image RGB colors. By default the image is flipped upside-down because the vertical OpenGL axis points upwards, while bitmap images are stored downwards. """ c = qimage2numpy(image, resize=resize, order='RGB', flip=True, indexed=False) c = c.reshape(-1, 3) c = c / 255. return c, None
[docs]def removeAlpha(qim): """ Remove the alpha component from a QImage. Directly saving a QImage grabbed from the OpenGL buffers always results in an image with transparency. See https://savannah.nongnu.org/bugs/?36995 . This function will remove the alpha component from the QImage, so that it can be saved with opaque objects. Note: we did not find a way to do this directly on the QImage, so we go through a conversion to a numpy array and back. """ ar, cm = qimage2numpy(qim, flip=False) return rgb2qimage(ar[..., :3])
[docs]def saveGreyImage(a, f, flip=True): """ Save a 2D int array as a grey image. Parameters ---------- a: int array Int array (height,width) with values in the range 0..255. These are the grey values of the pixels. f: str Name of the file to write the image to. flip: bool If True (default), the vertical axis is flipped, so that images are stored starting at the top. If your data already have the vertical axis downwards, use flip=False. Note ---- This stores the image as an RGB image with equal values for all three color components. """ a = at.checkArray(a, ndim=2, kind='u', allow='i').astype(np.uint8) c = np.flipud(a) c = np.dstack([c, c, c]) im = numpy2qimage(c) im.save(f)
if utils.checkModule('pydicom') or pf.sphinx:
[docs] class DicomStack(object): """ A stack of DICOM images. Note ---- This class is only available if you have pydicom installed. The DicomStack class stores a collection of DICOM images and provides conversion to ndarray. The DicomStack is initialized by a list of file names. All input files are scanned for DICOM image data and non-DICOM files are skipped. From the DICOM files, the pixel and slice spacing are read, as well as the origin. The DICOM files are sorted in order of ascending origin_z value. While reading the DICOM files, the following attributes are set: - `files`: a list of the valid DICOM files, in order of ascending z-value. - `pixel_spacing`: a dict with an (x,y) pixel spacing tuple as key and a list of indices of the matching images as value. - `slice_thickness`: a list of the slice thicknesses of the images, in the same order as `files`. - `xy_origin`: a dict with an (x,y) position the pixel (0,0) as key and a list of indices of the matching images as value. - `z_origin`: a list of the z positions of the images, in the same order as `files`. - `rejected`: list of rejected files. """
[docs] class Object(object): """_A dummy object to allow attributes""" pass
def __init__(self, files, zsort=True, reverse=False): """Initialize the DicomStack.""" # defer import for startup efficiency import pydicom ok = [] rejected = [] for fn in files: obj = DicomStack.Object() dataset = pydicom.dcmread(fn) try: obj.fn = fn obj.image = dataset.pixel_array obj.spacing = dataset.PixelSpacing try: obj.spacingz = dataset.SpacingBetweenSlices except: obj.spacingz = None obj.origin = np.array(dataset.ImagePositionPatient) obj.intercept = dataset.RescaleIntercept obj.slope = dataset.RescaleSlope ok.append(obj) except: rejected.append(obj) raise if zsort: ok.sort(key=lambda obj: obj.origin[2], reverse=reverse) self.ok, self.rejected = ok, rejected
[docs] def nfiles(self): """Return the number of accepted files.""" return len(self.ok)
[docs] def files(self): """Return the list of accepted filenames""" return [obj.fn for obj in self.ok]
[docs] def rejected(self): """Return the list of rejected filenames""" return [obj.fn for obj in self.rejected]
[docs] def pspacing(self): """Return the pixel spacing and slice thickness. Return the pixel spacing (x,y) and the slice thickness (z) in the accepted images. Returns: a float array of shape (nfiles,3). """ return np.array([obj.spacing for obj in self.ok])
[docs] def origin(self): """Return the origin of all accepted images. Return the world position of the pixel (0,0) in all accepted images. Returns: a float array of shape (nfiles,3). """ return np.array([obj.origin for obj in self.ok])
[docs] def zvalues(self): """Return the zvalue of all accepted images. The zvalue is the z value of the origin of the image. Returns: a float array of shape (nfiles). """ return np.array([obj.origin[2] for obj in self.ok])
[docs] def zspacing(self): """Check for constant slice spacing.""" zval = self.zvalues() zdif = zval[1:] - zval[:-1] if np.allclose(zdif, zdif[0]): self.spacingz = zdif[0] else: self.spacingz = None return self.spacingz
[docs] def spacing(self): """Return uniform spacing parameters, if uniform.""" pspacing = self.pspacing() if np.allclose(pspacing[:, 0], pspacing[0, 0]) and \ np.allclose(pspacing[:, 1], pspacing[0, 1]): self.spacingp = pspacing[0] if self.zspacing(): return np.concatenate([self.spacingp, [self.spacingz]]) return None
[docs] def image(self, i): """Return the image at index i""" return self.ok[i].image
[docs] def pixar(self, raw=False): """Return the DicomStack as an array Returns all images in a single array. This is only succesful if all accepted images have the same size. """ if raw: data = np.dstack([obj.image for obj in self.ok]) else: data = np.dstack([obj.image*obj.slope+obj.intercept for obj in self.ok]) return data
[docs] def dicom2numpy(files): """ Easy conversion of a set of dicom images to a numpy array. Parameters ---------- files: list of :term:`path_like` List of file names containing the subsequent DICOM images in the stack. The file names should be in the correct order. Returns ------- pixar: int array (nfiles, height, width) Pixel array with the nfiles images. spacing: """ ds = DicomStack(files) return ds.pixar(), ds.spacing()[0]
# End