vedo.volume
Work with volumetric datasets (voxel data).
1import glob 2import os 3import time 4from weakref import ref as weak_ref_to 5from typing import Self, Union, List, Iterable 6 7import numpy as np 8 9import vedo.vtkclasses as vtki 10 11import vedo 12from vedo import transformations 13from vedo import utils 14from vedo.mesh import Mesh 15from vedo.core import VolumeAlgorithms 16from vedo.visual import VolumeVisual 17 18 19__docformat__ = "google" 20 21__doc__ = """ 22Work with volumetric datasets (voxel data). 23 24 25""" 26 27__all__ = ["Volume"] 28 29 30########################################################################## 31class Volume(VolumeAlgorithms, VolumeVisual): 32 """ 33 Class to describe dataset that are defined on "voxels", 34 the 3D equivalent of 2D pixels. 35 """ 36 def __init__( 37 self, 38 inputobj=None, 39 dims=None, 40 origin=None, 41 spacing=None, 42 ) -> None: 43 """ 44 This class can be initialized with a numpy object, 45 a `vtkImageData` or a list of 2D bmp files. 46 47 Arguments: 48 origin : (list) 49 set volume origin coordinates 50 spacing : (list) 51 voxel dimensions in x, y and z. 52 dims : (list) 53 specify the dimensions of the volume. 54 55 Example: 56 ```python 57 from vedo import Volume 58 vol = Volume("path/to/mydata/rec*.bmp") 59 vol.show() 60 ``` 61 62 Examples: 63 - [numpy2volume1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume1.py) 64 65  66 67 - [read_volume2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/read_volume2.py) 68 69  70 71 .. note:: 72 if a `list` of values is used for `alphas` this is interpreted 73 as a transfer function along the range of the scalar. 74 """ 75 super().__init__() 76 77 self.name = "Volume" 78 self.filename = "" 79 self.file_size = "" 80 81 self.info = {} 82 self.time = time.time() 83 84 self.actor = vtki.vtkVolume() 85 self.actor.retrieve_object = weak_ref_to(self) 86 self.properties = self.actor.GetProperty() 87 88 self.transform = None 89 self.point_locator = None 90 self.cell_locator = None 91 self.line_locator = None 92 93 ################### 94 if isinstance(inputobj, str): 95 if "https://" in inputobj: 96 inputobj = vedo.file_io.download(inputobj, verbose=False) # fpath 97 elif os.path.isfile(inputobj): 98 self.filename = inputobj 99 else: 100 inputobj = sorted(glob.glob(inputobj)) 101 102 ################### 103 inputtype = str(type(inputobj)) 104 105 # print('Volume inputtype', inputtype, c='b') 106 107 if inputobj is None: 108 img = vtki.vtkImageData() 109 110 elif utils.is_sequence(inputobj): 111 112 if isinstance(inputobj[0], str) and ".bmp" in inputobj[0].lower(): 113 # scan sequence of BMP files 114 ima = vtki.new("ImageAppend") 115 ima.SetAppendAxis(2) 116 pb = utils.ProgressBar(0, len(inputobj)) 117 for i in pb.range(): 118 f = inputobj[i] 119 if "_rec_spr" in f: # OPT specific 120 continue 121 picr = vtki.new("BMPReader") 122 picr.SetFileName(f) 123 picr.Update() 124 mgf = vtki.new("ImageMagnitude") 125 mgf.SetInputData(picr.GetOutput()) 126 mgf.Update() 127 ima.AddInputData(mgf.GetOutput()) 128 pb.print("loading...") 129 ima.Update() 130 img = ima.GetOutput() 131 132 else: 133 134 if len(inputobj.shape) == 1: 135 varr = utils.numpy2vtk(inputobj) 136 else: 137 varr = utils.numpy2vtk(inputobj.ravel(order="F")) 138 varr.SetName("input_scalars") 139 140 img = vtki.vtkImageData() 141 if dims is not None: 142 img.SetDimensions(dims[2], dims[1], dims[0]) 143 else: 144 if len(inputobj.shape) == 1: 145 vedo.logger.error("must set dimensions (dims keyword) in Volume") 146 raise RuntimeError() 147 img.SetDimensions(inputobj.shape) 148 img.GetPointData().AddArray(varr) 149 img.GetPointData().SetActiveScalars(varr.GetName()) 150 151 elif isinstance(inputobj, vtki.vtkImageData): 152 img = inputobj 153 154 elif isinstance(inputobj, str): 155 if "https://" in inputobj: 156 inputobj = vedo.file_io.download(inputobj, verbose=False) 157 img = vedo.file_io.loadImageData(inputobj) 158 self.filename = inputobj 159 160 else: 161 vedo.logger.error(f"cannot understand input type {inputtype}") 162 return 163 164 if dims is not None: 165 img.SetDimensions(dims) 166 167 if origin is not None: 168 img.SetOrigin(origin) 169 170 if spacing is not None: 171 img.SetSpacing(spacing) 172 173 self.dataset = img 174 self.transform = None 175 176 ##################################### 177 mapper = vtki.new("SmartVolumeMapper") 178 mapper.SetInputData(img) 179 self.actor.SetMapper(mapper) 180 181 if img.GetPointData().GetScalars(): 182 if img.GetPointData().GetScalars().GetNumberOfComponents() == 1: 183 self.properties.SetShade(True) 184 self.properties.SetInterpolationType(1) 185 self.cmap("RdBu_r") 186 self.alpha([0.0, 0.0, 0.2, 0.4, 0.8, 1.0]) 187 self.alpha_gradient(None) 188 self.properties.SetScalarOpacityUnitDistance(1.0) 189 190 self.pipeline = utils.OperationNode( 191 "Volume", comment=f"dims={tuple(self.dimensions())}", c="#4cc9f0" 192 ) 193 ####################################################################### 194 195 @property 196 def mapper(self): 197 """Return the underlying `vtkMapper` object.""" 198 return self.actor.GetMapper() 199 200 @mapper.setter 201 def mapper(self, mapper): 202 """ 203 Set the underlying `vtkMapper` object. 204 205 Arguments: 206 mapper : (str, vtkMapper) 207 either 'gpu', 'opengl_gpu', 'fixed' or 'smart' 208 """ 209 if isinstance(mapper, 210 (vtki.get_class("Mapper"), vtki.get_class("ImageResliceMapper")) 211 ): 212 pass 213 elif mapper is None: 214 mapper = vtki.new("SmartVolumeMapper") 215 elif "gpu" in mapper: 216 mapper = vtki.new("GPUVolumeRayCastMapper") 217 elif "opengl_gpu" in mapper: 218 mapper = vtki.new("OpenGLGPUVolumeRayCastMapper") 219 elif "smart" in mapper: 220 mapper = vtki.new("SmartVolumeMapper") 221 elif "fixed" in mapper: 222 mapper = vtki.new("FixedPointVolumeRayCastMapper") 223 else: 224 print("Error unknown mapper type", [mapper]) 225 raise RuntimeError() 226 self.actor.SetMapper(mapper) 227 228 def c(self, *args, **kwargs) -> Self: 229 """Deprecated. Use `Volume.cmap()` instead.""" 230 vedo.logger.warning("Volume.c() is deprecated, use Volume.cmap() instead") 231 return self.cmap(*args, **kwargs) 232 233 def _update(self, data, reset_locators=False): 234 # reset_locators here is dummy 235 self.dataset = data 236 self.mapper.SetInputData(data) 237 self.dataset.GetPointData().Modified() 238 self.mapper.Modified() 239 self.mapper.Update() 240 return self 241 242 def __str__(self): 243 """Print a summary for the `Volume` object.""" 244 module = self.__class__.__module__ 245 name = self.__class__.__name__ 246 out = vedo.printc( 247 f"{module}.{name} at ({hex(self.memory_address())})".ljust(75), 248 c="c", bold=True, invert=True, return_string=True, 249 ) 250 out += "\x1b[0m\x1b[36;1m" 251 252 out+= "name".ljust(14) + ": " + str(self.name) + "\n" 253 if self.filename: 254 out+= "filename".ljust(14) + ": " + str(self.filename) + "\n" 255 256 out+= "dimensions".ljust(14) + ": " + str(self.shape) + "\n" 257 258 out+= "origin".ljust(14) + ": " 259 out+= utils.precision(self.origin(), 6) + "\n" 260 261 out+= "center".ljust(14) + ": " 262 out+= utils.precision(self.center(), 6) + "\n" 263 264 out+= "spacing".ljust(14) + ": " 265 out+= utils.precision(self.spacing(), 6) + "\n" 266 267 bnds = self.bounds() 268 bx1, bx2 = utils.precision(bnds[0], 3), utils.precision(bnds[1], 3) 269 by1, by2 = utils.precision(bnds[2], 3), utils.precision(bnds[3], 3) 270 bz1, bz2 = utils.precision(bnds[4], 3), utils.precision(bnds[5], 3) 271 out+= "bounds".ljust(14) + ":" 272 out+= " x=(" + bx1 + ", " + bx2 + ")," 273 out+= " y=(" + by1 + ", " + by2 + ")," 274 out+= " z=(" + bz1 + ", " + bz2 + ")\n" 275 276 out+= "memory size".ljust(14) + ": " 277 out+= str(int(self.dataset.GetActualMemorySize()/1024+0.5))+" MB\n" 278 279 st = self.dataset.GetScalarTypeAsString() 280 out+= "scalar size".ljust(14) + ": " 281 out+= str(self.dataset.GetScalarSize()) + f" bytes ({st})\n" 282 out+= "scalar range".ljust(14) + ": " 283 out+= str(self.dataset.GetScalarRange()) + "\n" 284 285 #utils.print_histogram(self, logscale=True, bins=8, height=15, c="b", bold=True) 286 return out.rstrip() + "\x1b[0m" 287 288 def _repr_html_(self): 289 """ 290 HTML representation of the Volume object for Jupyter Notebooks. 291 292 Returns: 293 HTML text with the image and some properties. 294 """ 295 import io 296 import base64 297 from PIL import Image 298 299 library_name = "vedo.volume.Volume" 300 help_url = "https://vedo.embl.es/docs/vedo/volume.html" 301 302 arr = self.thumbnail(azimuth=0, elevation=-60, zoom=1.4, axes=True) 303 304 im = Image.fromarray(arr) 305 buffered = io.BytesIO() 306 im.save(buffered, format="PNG", quality=100) 307 encoded = base64.b64encode(buffered.getvalue()).decode("utf-8") 308 url = "data:image/png;base64," + encoded 309 image = f"<img src='{url}'></img>" 310 311 # statisitics 312 bounds = "<br/>".join( 313 [ 314 utils.precision(min_x, 4) + " ... " + utils.precision(max_x, 4) 315 for min_x, max_x in zip(self.bounds()[::2], self.bounds()[1::2]) 316 ] 317 ) 318 319 help_text = "" 320 if self.name: 321 help_text += f"<b> {self.name}:   </b>" 322 help_text += '<b><a href="' + help_url + '" target="_blank">' + library_name + "</a></b>" 323 if self.filename: 324 dots = "" 325 if len(self.filename) > 30: 326 dots = "..." 327 help_text += f"<br/><code><i>({dots}{self.filename[-30:]})</i></code>" 328 329 pdata = "" 330 if self.dataset.GetPointData().GetScalars(): 331 if self.dataset.GetPointData().GetScalars().GetName(): 332 name = self.dataset.GetPointData().GetScalars().GetName() 333 pdata = "<tr><td><b> point data array </b></td><td>" + name + "</td></tr>" 334 335 cdata = "" 336 if self.dataset.GetCellData().GetScalars(): 337 if self.dataset.GetCellData().GetScalars().GetName(): 338 name = self.dataset.GetCellData().GetScalars().GetName() 339 cdata = "<tr><td><b> voxel data array </b></td><td>" + name + "</td></tr>" 340 341 img = self.dataset 342 343 allt = [ 344 "<table>", 345 "<tr>", 346 "<td>", 347 image, 348 "</td>", 349 "<td style='text-align: center; vertical-align: center;'><br/>", 350 help_text, 351 "<table>", 352 "<tr><td><b> bounds </b> <br/> (x/y/z) </td><td>" + str(bounds) + "</td></tr>", 353 "<tr><td><b> dimensions </b></td><td>" + str(img.GetDimensions()) + "</td></tr>", 354 "<tr><td><b> voxel spacing </b></td><td>" 355 + utils.precision(img.GetSpacing(), 3) 356 + "</td></tr>", 357 "<tr><td><b> in memory size </b></td><td>" 358 + str(int(img.GetActualMemorySize() / 1024)) 359 + "MB</td></tr>", 360 pdata, 361 cdata, 362 "<tr><td><b> scalar range </b></td><td>" 363 + utils.precision(img.GetScalarRange(), 4) 364 + "</td></tr>", 365 "</table>", 366 "</table>", 367 ] 368 return "\n".join(allt) 369 370 def copy(self, deep=True) -> "Volume": 371 """Return a copy of the Volume. Alias of `clone()`.""" 372 return self.clone(deep=deep) 373 374 def clone(self, deep=True) -> "Volume": 375 """Return a clone copy of the Volume. Alias of `copy()`.""" 376 if deep: 377 newimg = vtki.vtkImageData() 378 newimg.CopyStructure(self.dataset) 379 newimg.CopyAttributes(self.dataset) 380 newvol = Volume(newimg) 381 else: 382 newvol = Volume(self.dataset) 383 384 prop = vtki.vtkVolumeProperty() 385 prop.DeepCopy(self.properties) 386 newvol.actor.SetProperty(prop) 387 newvol.properties = prop 388 389 newvol.pipeline = utils.OperationNode("clone", parents=[self], c="#bbd0ff", shape="diamond") 390 return newvol 391 392 def astype(self, dtype: Union[str, int]) -> Self: 393 """ 394 Reset the type of the scalars array. 395 396 Arguments: 397 dtype : (str) 398 the type of the scalars array in 399 ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"] 400 """ 401 if dtype in ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"]: 402 caster = vtki.new("ImageCast") 403 caster.SetInputData(self.dataset) 404 caster.SetOutputScalarType(int(vtki.array_types[dtype])) 405 caster.ClampOverflowOn() 406 caster.Update() 407 self._update(caster.GetOutput()) 408 self.pipeline = utils.OperationNode(f"astype({dtype})", parents=[self], c="#4cc9f0") 409 else: 410 vedo.logger.error(f"astype(): unknown type {dtype}") 411 raise ValueError() 412 return self 413 414 def component_weight(self, i: int, weight: float) -> Self: 415 """Set the scalar component weight in range [0,1].""" 416 self.properties.SetComponentWeight(i, weight) 417 return self 418 419 def xslice(self, i: int) -> Mesh: 420 """Extract the slice at index `i` of volume along x-axis.""" 421 vslice = vtki.new("ImageDataGeometryFilter") 422 vslice.SetInputData(self.dataset) 423 nx, ny, nz = self.dataset.GetDimensions() 424 if i > nx - 1: 425 i = nx - 1 426 vslice.SetExtent(i, i, 0, ny, 0, nz) 427 vslice.Update() 428 m = Mesh(vslice.GetOutput()) 429 m.pipeline = utils.OperationNode(f"xslice {i}", parents=[self], c="#4cc9f0:#e9c46a") 430 return m 431 432 def yslice(self, j: int) -> Mesh: 433 """Extract the slice at index `j` of volume along y-axis.""" 434 vslice = vtki.new("ImageDataGeometryFilter") 435 vslice.SetInputData(self.dataset) 436 nx, ny, nz = self.dataset.GetDimensions() 437 if j > ny - 1: 438 j = ny - 1 439 vslice.SetExtent(0, nx, j, j, 0, nz) 440 vslice.Update() 441 m = Mesh(vslice.GetOutput()) 442 m.pipeline = utils.OperationNode(f"yslice {j}", parents=[self], c="#4cc9f0:#e9c46a") 443 return m 444 445 def zslice(self, k: int) -> Mesh: 446 """Extract the slice at index `i` of volume along z-axis.""" 447 vslice = vtki.new("ImageDataGeometryFilter") 448 vslice.SetInputData(self.dataset) 449 nx, ny, nz = self.dataset.GetDimensions() 450 if k > nz - 1: 451 k = nz - 1 452 vslice.SetExtent(0, nx, 0, ny, k, k) 453 vslice.Update() 454 m = Mesh(vslice.GetOutput()) 455 m.pipeline = utils.OperationNode(f"zslice {k}", parents=[self], c="#4cc9f0:#e9c46a") 456 return m 457 458 def slice_plane(self, origin: List[float], normal: List[float], autocrop=False, border=0.5, mode="linear") -> Mesh: 459 """ 460 Extract the slice along a given plane position and normal. 461 462 Two metadata arrays are added to the output Mesh: 463 - "shape" : contains the shape of the slice 464 - "original_bounds" : contains the original bounds of the slice 465 One can access them with e.g. `myslice.metadata["shape"]`. 466 467 Arguments: 468 origin : (list) 469 position of the plane 470 normal : (list) 471 normal to the plane 472 autocrop : (bool) 473 crop the output to the minimal possible size 474 border : (float) 475 add a border to the output slice 476 mode : (str) 477 interpolation mode, one of the following: "linear", "nearest", "cubic" 478 479 Example: 480 - [slice_plane1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane1.py) 481 482  483 484 - [slice_plane2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane2.py) 485 486  487 488 - [slice_plane3.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane3.py) 489 490  491 """ 492 newaxis = utils.versor(normal) 493 pos = np.array(origin) 494 initaxis = (0, 0, 1) 495 crossvec = np.cross(initaxis, newaxis) 496 angle = np.arccos(np.dot(initaxis, newaxis)) 497 T = vtki.vtkTransform() 498 T.PostMultiply() 499 T.RotateWXYZ(np.rad2deg(angle), crossvec.tolist()) 500 T.Translate(pos.tolist()) 501 502 reslice = vtki.new("ImageReslice") 503 reslice.SetResliceAxes(T.GetMatrix()) 504 reslice.SetInputData(self.dataset) 505 reslice.SetOutputDimensionality(2) 506 reslice.SetTransformInputSampling(True) 507 reslice.SetGenerateStencilOutput(False) 508 if border: 509 reslice.SetBorder(True) 510 reslice.SetBorderThickness(border) 511 else: 512 reslice.SetBorder(False) 513 if mode == "linear": 514 reslice.SetInterpolationModeToLinear() 515 elif mode == "nearest": 516 reslice.SetInterpolationModeToNearestNeighbor() 517 elif mode == "cubic": 518 reslice.SetInterpolationModeToCubic() 519 else: 520 vedo.logger.error(f"in slice_plane(): unknown interpolation mode {mode}") 521 raise ValueError() 522 reslice.SetAutoCropOutput(not autocrop) 523 reslice.Update() 524 img = reslice.GetOutput() 525 526 vslice = vtki.new("ImageDataGeometryFilter") 527 vslice.SetInputData(img) 528 vslice.Update() 529 530 msh = Mesh(vslice.GetOutput()).apply_transform(T) 531 msh.properties.LightingOff() 532 533 d0, d1, _ = img.GetDimensions() 534 varr1 = utils.numpy2vtk([d1, d0], name="shape") 535 varr2 = utils.numpy2vtk(img.GetBounds(), name="original_bounds") 536 msh.dataset.GetFieldData().AddArray(varr1) 537 msh.dataset.GetFieldData().AddArray(varr2) 538 msh.pipeline = utils.OperationNode("slice_plane", parents=[self], c="#4cc9f0:#e9c46a") 539 return msh 540 541 def slab(self, slice_range=(), axis='z', operation="mean") -> Mesh: 542 """ 543 Extract a slab from a `Volume` by combining 544 all of the slices of an image to create a single slice. 545 546 Returns a `Mesh` containing metadata which 547 can be accessed with e.g. `mesh.metadata["slab_range"]`. 548 549 Metadata: 550 slab_range : (list) 551 contains the range of slices extracted 552 slab_axis : (str) 553 contains the axis along which the slab was extracted 554 slab_operation : (str) 555 contains the operation performed on the slab 556 slab_bounding_box : (list) 557 contains the bounding box of the slab 558 559 Arguments: 560 slice_range : (list) 561 range of slices to extract 562 axis : (str) 563 axis along which to extract the slab 564 operation : (str) 565 operation to perform on the slab, 566 allowed values are: "sum", "min", "max", "mean". 567 568 Example: 569 - [slab.py](https://github.com/marcomusy/vedo/blob/master/examples/volumetric/slab_vol.py) 570 571  572 """ 573 if len(slice_range) != 2: 574 vedo.logger.error("in slab(): slice_range is empty or invalid") 575 raise ValueError() 576 577 islab = vtki.new("ImageSlab") 578 islab.SetInputData(self.dataset) 579 580 if operation in ["+", "add", "sum"]: 581 islab.SetOperationToSum() 582 elif "min" in operation: 583 islab.SetOperationToMin() 584 elif "max" in operation: 585 islab.SetOperationToMax() 586 elif "mean" in operation: 587 islab.SetOperationToMean() 588 else: 589 vedo.logger.error(f"in slab(): unknown operation {operation}") 590 raise ValueError() 591 592 dims = self.dimensions() 593 if axis == 'x': 594 islab.SetOrientationToX() 595 if slice_range[0] > dims[0]-1: 596 slice_range[0] = dims[0]-1 597 if slice_range[1] > dims[0]-1: 598 slice_range[1] = dims[0]-1 599 elif axis == 'y': 600 islab.SetOrientationToY() 601 if slice_range[0] > dims[1]-1: 602 slice_range[0] = dims[1]-1 603 if slice_range[1] > dims[1]-1: 604 slice_range[1] = dims[1]-1 605 elif axis == 'z': 606 islab.SetOrientationToZ() 607 if slice_range[0] > dims[2]-1: 608 slice_range[0] = dims[2]-1 609 if slice_range[1] > dims[2]-1: 610 slice_range[1] = dims[2]-1 611 else: 612 vedo.logger.error(f"Error in slab(): unknown axis {axis}") 613 raise RuntimeError() 614 615 islab.SetSliceRange(slice_range) 616 islab.Update() 617 618 msh = Mesh(islab.GetOutput()).lighting('off') 619 msh.mapper.SetLookupTable(utils.ctf2lut(self, msh)) 620 msh.mapper.SetScalarRange(self.scalar_range()) 621 622 msh.metadata["slab_range"] = slice_range 623 msh.metadata["slab_axis"] = axis 624 msh.metadata["slab_operation"] = operation 625 626 # compute bounds of slab 627 origin = list(self.origin()) 628 spacing = list(self.spacing()) 629 if axis == 'x': 630 msh.metadata["slab_bounding_box"] = [ 631 origin[0] + slice_range[0]*spacing[0], 632 origin[0] + slice_range[1]*spacing[0], 633 origin[1], 634 origin[1] + dims[1]*spacing[1], 635 origin[2], 636 origin[2] + dims[2]*spacing[2], 637 ] 638 elif axis == 'y': 639 msh.metadata["slab_bounding_box"] = [ 640 origin[0], 641 origin[0] + dims[0]*spacing[0], 642 origin[1] + slice_range[0]*spacing[1], 643 origin[1] + slice_range[1]*spacing[1], 644 origin[2], 645 origin[2] + dims[2]*spacing[2], 646 ] 647 elif axis == 'z': 648 msh.metadata["slab_bounding_box"] = [ 649 origin[0], 650 origin[0] + dims[0]*spacing[0], 651 origin[1], 652 origin[1] + dims[1]*spacing[1], 653 origin[2] + slice_range[0]*spacing[2], 654 origin[2] + slice_range[1]*spacing[2], 655 ] 656 657 msh.pipeline = utils.OperationNode( 658 f"slab{slice_range}", 659 comment=f"axis={axis}, operation={operation}", 660 parents=[self], 661 c="#4cc9f0:#e9c46a", 662 ) 663 msh.name = "SlabMesh" 664 return msh 665 666 667 def warp( 668 self, 669 source: Union["vedo.Points", List], 670 target: Union["vedo.Points", List], 671 sigma=1, mode="3d", fit=True, 672 ) -> Self: 673 """ 674 Warp volume scalars within a Volume by specifying 675 source and target sets of points. 676 677 Arguments: 678 source : (Points, list) 679 the list of source points 680 target : (Points, list) 681 the list of target points 682 fit : (bool) 683 fit/adapt the old bounding box to the warped geometry 684 """ 685 if isinstance(source, vedo.Points): 686 source = source.vertices 687 if isinstance(target, vedo.Points): 688 target = target.vertices 689 690 NLT = transformations.NonLinearTransform() 691 NLT.source_points = source 692 NLT.target_points = target 693 NLT.sigma = sigma 694 NLT.mode = mode 695 696 self.apply_transform(NLT, fit=fit) 697 self.pipeline = utils.OperationNode("warp", parents=[self], c="#4cc9f0") 698 return self 699 700 def apply_transform( 701 self, 702 T: Union[transformations.LinearTransform, transformations.NonLinearTransform], 703 fit=True, interpolation="cubic", 704 ) -> Self: 705 """ 706 Apply a transform to the scalars in the volume. 707 708 Arguments: 709 T : (LinearTransform, NonLinearTransform) 710 The transformation to be applied 711 fit : (bool) 712 fit/adapt the old bounding box to the modified geometry 713 interpolation : (str) 714 one of the following: "nearest", "linear", "cubic" 715 """ 716 if utils.is_sequence(T): 717 T = transformations.LinearTransform(T) 718 719 TI = T.compute_inverse() 720 721 reslice = vtki.new("ImageReslice") 722 reslice.SetInputData(self.dataset) 723 reslice.SetResliceTransform(TI.T) 724 reslice.SetOutputDimensionality(3) 725 if "lin" in interpolation.lower(): 726 reslice.SetInterpolationModeToLinear() 727 elif "near" in interpolation.lower(): 728 reslice.SetInterpolationModeToNearestNeighbor() 729 elif "cubic" in interpolation.lower(): 730 reslice.SetInterpolationModeToCubic() 731 else: 732 vedo.logger.error( 733 f"in apply_transform: unknown interpolation mode {interpolation}") 734 raise ValueError() 735 reslice.SetAutoCropOutput(fit) 736 reslice.Update() 737 self._update(reslice.GetOutput()) 738 self.transform = T 739 self.pipeline = utils.OperationNode( 740 "apply_transform", parents=[self], c="#4cc9f0") 741 return self 742 743 def imagedata(self) -> vtki.vtkImageData: 744 """ 745 DEPRECATED: 746 Use `Volume.dataset` instead. 747 748 Return the underlying `vtkImagaData` object. 749 """ 750 print("Volume.imagedata() is deprecated, use Volume.dataset instead") 751 return self.dataset 752 753 def modified(self) -> Self: 754 """ 755 Mark the object as modified. 756 757 Example: 758 759 - [numpy2volume0.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume0.py) 760 """ 761 scals = self.dataset.GetPointData().GetScalars() 762 if scals: 763 scals.Modified() 764 return self 765 766 def tonumpy(self) -> np.ndarray: 767 """ 768 Get read-write access to voxels of a Volume object as a numpy array. 769 770 When you set values in the output image, you don't want numpy to reallocate the array 771 but instead set values in the existing array, so use the [:] operator. 772 773 Example: 774 `arr[:] = arr*2 + 15` 775 776 If the array is modified add a call to: 777 `volume.modified()` 778 when all your modifications are completed. 779 """ 780 narray_shape = tuple(reversed(self.dataset.GetDimensions())) 781 782 scals = self.dataset.GetPointData().GetScalars() 783 comps = scals.GetNumberOfComponents() 784 if comps == 1: 785 narray = utils.vtk2numpy(scals).reshape(narray_shape) 786 narray = np.transpose(narray, axes=[2, 1, 0]) 787 else: 788 narray = utils.vtk2numpy(scals).reshape(*narray_shape, comps) 789 narray = np.transpose(narray, axes=[2, 1, 0, 3]) 790 791 # narray = utils.vtk2numpy(self.dataset.GetPointData().GetScalars()).reshape(narray_shape) 792 # narray = np.transpose(narray, axes=[2, 1, 0]) 793 return narray 794 795 @property 796 def shape(self) -> np.ndarray: 797 """Return the nr. of voxels in the 3 dimensions.""" 798 return np.array(self.dataset.GetDimensions()) 799 800 def dimensions(self) -> np.ndarray: 801 """Return the nr. of voxels in the 3 dimensions.""" 802 return np.array(self.dataset.GetDimensions()) 803 804 def scalar_range(self) -> np.ndarray: 805 """Return the range of the scalar values.""" 806 return np.array(self.dataset.GetScalarRange()) 807 808 def spacing(self, s=None) -> Union[Self, Iterable[float]]: 809 """Set/get the voxels size in the 3 dimensions.""" 810 if s is not None: 811 self.dataset.SetSpacing(s) 812 return self 813 return np.array(self.dataset.GetSpacing()) 814 815 def origin(self, s=None) -> Union[Self, Iterable[float]]: 816 """ 817 Set/get the origin of the volumetric dataset. 818 819 The origin is the position in world coordinates of the point index (0,0,0). 820 This point does not have to be part of the dataset, in other words, 821 the dataset extent does not have to start at (0,0,0) and the origin 822 can be outside of the dataset bounding box. 823 The origin plus spacing determine the position in space of the points. 824 """ 825 if s is not None: 826 self.dataset.SetOrigin(s) 827 return self 828 return np.array(self.dataset.GetOrigin()) 829 830 def pos(self, p=None) -> Union[Self, Iterable[float]]: 831 """Set/get the position of the volumetric dataset.""" 832 if p is not None: 833 self.origin(p) 834 return self 835 return self.origin() 836 837 def center(self) -> np.ndarray: 838 """Get the center of the volumetric dataset.""" 839 # note that this does not have the set method like origin and spacing 840 return np.array(self.dataset.GetCenter()) 841 842 def shift(self, s: list) -> Self: 843 """Shift the volumetric dataset by a vector.""" 844 self.origin(self.origin() + np.array(s)) 845 return self 846 847 def rotate_x(self, angle: float, rad=False, around=None) -> Self: 848 """ 849 Rotate around x-axis. If angle is in radians set `rad=True`. 850 851 Use `around` to define a pivoting point. 852 """ 853 if angle == 0: 854 return self 855 LT = transformations.LinearTransform().rotate_x(angle, rad, around) 856 return self.apply_transform(LT, fit=True, interpolation="linear") 857 858 def rotate_y(self, angle: float, rad=False, around=None) -> Self: 859 """ 860 Rotate around y-axis. If angle is in radians set `rad=True`. 861 862 Use `around` to define a pivoting point. 863 """ 864 if angle == 0: 865 return self 866 LT = transformations.LinearTransform().rotate_y(angle, rad, around) 867 return self.apply_transform(LT, fit=True, interpolation="linear") 868 869 def rotate_z(self, angle: float, rad=False, around=None) -> Self: 870 """ 871 Rotate around z-axis. If angle is in radians set `rad=True`. 872 873 Use `around` to define a pivoting point. 874 """ 875 if angle == 0: 876 return self 877 LT = transformations.LinearTransform().rotate_z(angle, rad, around) 878 return self.apply_transform(LT, fit=True, interpolation="linear") 879 880 def get_cell_from_ijk(self, ijk: list) -> int: 881 """ 882 Get the voxel id number at the given ijk coordinates. 883 884 Arguments: 885 ijk : (list) 886 the ijk coordinates of the voxel 887 """ 888 return self.dataset.ComputeCellId(ijk) 889 890 def get_point_from_ijk(self, ijk: list) -> int: 891 """ 892 Get the point id number at the given ijk coordinates. 893 894 Arguments: 895 ijk : (list) 896 the ijk coordinates of the voxel 897 """ 898 return self.dataset.ComputePointId(ijk) 899 900 def permute_axes(self, x: int, y: int, z: int) -> Self: 901 """ 902 Reorder the axes of the Volume by specifying 903 the input axes which are supposed to become the new X, Y, and Z. 904 """ 905 imp = vtki.new("ImagePermute") 906 imp.SetFilteredAxes(x, y, z) 907 imp.SetInputData(self.dataset) 908 imp.Update() 909 self._update(imp.GetOutput()) 910 self.pipeline = utils.OperationNode( 911 f"permute_axes({(x,y,z)})", parents=[self], c="#4cc9f0" 912 ) 913 return self 914 915 def resample(self, new_spacing: List[float], interpolation=1) -> Self: 916 """ 917 Resamples a `Volume` to be larger or smaller. 918 919 This method modifies the spacing of the input. 920 Linear interpolation is used to resample the data. 921 922 Arguments: 923 new_spacing : (list) 924 a list of 3 new spacings for the 3 axes 925 interpolation : (int) 926 0=nearest_neighbor, 1=linear, 2=cubic 927 """ 928 rsp = vtki.new("ImageResample") 929 oldsp = self.spacing() 930 for i in range(3): 931 if oldsp[i] != new_spacing[i]: 932 rsp.SetAxisOutputSpacing(i, new_spacing[i]) 933 rsp.InterpolateOn() 934 rsp.SetInterpolationMode(interpolation) 935 rsp.OptimizationOn() 936 rsp.Update() 937 self._update(rsp.GetOutput()) 938 self.pipeline = utils.OperationNode( 939 "resample", comment=f"spacing: {tuple(new_spacing)}", parents=[self], c="#4cc9f0" 940 ) 941 return self 942 943 944 def threshold(self, above=None, below=None, replace=None, replace_value=None) -> Self: 945 """ 946 Binary or continuous volume thresholding. 947 Find the voxels that contain a value above/below the input values 948 and replace them with a new value (default is 0). 949 """ 950 th = vtki.new("ImageThreshold") 951 th.SetInputData(self.dataset) 952 953 # sanity checks 954 if above is not None and below is not None: 955 if above == below: 956 return self 957 if above > below: 958 vedo.logger.warning("in volume.threshold(), above > below, skip.") 959 return self 960 961 ## cases 962 if below is not None and above is not None: 963 th.ThresholdBetween(above, below) 964 965 elif above is not None: 966 th.ThresholdByUpper(above) 967 968 elif below is not None: 969 th.ThresholdByLower(below) 970 971 ## 972 if replace is not None: 973 th.SetReplaceIn(True) 974 th.SetInValue(replace) 975 else: 976 th.SetReplaceIn(False) 977 978 if replace_value is not None: 979 th.SetReplaceOut(True) 980 th.SetOutValue(replace_value) 981 else: 982 th.SetReplaceOut(False) 983 984 th.Update() 985 self._update(th.GetOutput()) 986 self.pipeline = utils.OperationNode("threshold", parents=[self], c="#4cc9f0") 987 return self 988 989 def crop(self, left=None, right=None, back=None, front=None, bottom=None, top=None, VOI=()) -> Self: 990 """ 991 Crop a `Volume` object. 992 993 Arguments: 994 left : (float) 995 fraction to crop from the left plane (negative x) 996 right : (float) 997 fraction to crop from the right plane (positive x) 998 back : (float) 999 fraction to crop from the back plane (negative y) 1000 front : (float) 1001 fraction to crop from the front plane (positive y) 1002 bottom : (float) 1003 fraction to crop from the bottom plane (negative z) 1004 top : (float) 1005 fraction to crop from the top plane (positive z) 1006 VOI : (list) 1007 extract Volume Of Interest expressed in voxel numbers 1008 1009 Example: 1010 `vol.crop(VOI=(xmin, xmax, ymin, ymax, zmin, zmax)) # all integers nrs` 1011 """ 1012 extractVOI = vtki.new("ExtractVOI") 1013 extractVOI.SetInputData(self.dataset) 1014 1015 if VOI: 1016 extractVOI.SetVOI(VOI) 1017 else: 1018 d = self.dataset.GetDimensions() 1019 bx0, bx1, by0, by1, bz0, bz1 = 0, d[0]-1, 0, d[1]-1, 0, d[2]-1 1020 if left is not None: bx0 = int((d[0]-1)*left) 1021 if right is not None: bx1 = int((d[0]-1)*(1-right)) 1022 if back is not None: by0 = int((d[1]-1)*back) 1023 if front is not None: by1 = int((d[1]-1)*(1-front)) 1024 if bottom is not None: bz0 = int((d[2]-1)*bottom) 1025 if top is not None: bz1 = int((d[2]-1)*(1-top)) 1026 extractVOI.SetVOI(bx0, bx1, by0, by1, bz0, bz1) 1027 extractVOI.Update() 1028 self._update(extractVOI.GetOutput()) 1029 1030 self.pipeline = utils.OperationNode( 1031 "crop", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1032 ) 1033 return self 1034 1035 def append(self, *volumes, axis="z", preserve_extents=False) -> Self: 1036 """ 1037 Take the components from multiple inputs and merges them into one output. 1038 Except for the append axis, all inputs must have the same extent. 1039 All inputs must have the same number of scalar components. 1040 The output has the same origin and spacing as the first input. 1041 The origin and spacing of all other inputs are ignored. 1042 All inputs must have the same scalar type. 1043 1044 Arguments: 1045 axis : (int, str) 1046 axis expanded to hold the multiple images 1047 preserve_extents : (bool) 1048 if True, the extent of the inputs is used to place 1049 the image in the output. The whole extent of the output is the union of the input 1050 whole extents. Any portion of the output not covered by the inputs is set to zero. 1051 The origin and spacing is taken from the first input. 1052 1053 Example: 1054 ```python 1055 from vedo import Volume, dataurl 1056 vol = Volume(dataurl+'embryo.tif') 1057 vol.append(vol, axis='x').show().close() 1058 ``` 1059  1060 """ 1061 ima = vtki.new("ImageAppend") 1062 ima.SetInputData(self.dataset) 1063 # if not utils.is_sequence(volumes): 1064 # volumes = [volumes] 1065 for volume in volumes: 1066 if isinstance(volume, vtki.vtkImageData): 1067 ima.AddInputData(volume) 1068 else: 1069 ima.AddInputData(volume.dataset) 1070 ima.SetPreserveExtents(preserve_extents) 1071 if axis == "x": 1072 axis = 0 1073 elif axis == "y": 1074 axis = 1 1075 elif axis == "z": 1076 axis = 2 1077 ima.SetAppendAxis(axis) 1078 ima.Update() 1079 self._update(ima.GetOutput()) 1080 1081 self.pipeline = utils.OperationNode( 1082 "append", 1083 parents=[self, *volumes], 1084 c="#4cc9f0", 1085 comment=f"dims={tuple(self.dimensions())}", 1086 ) 1087 return self 1088 1089 def pad(self, voxels=10, value=0) -> Self: 1090 """ 1091 Add the specified number of voxels at the `Volume` borders. 1092 Voxels can be a list formatted as `[nx0, nx1, ny0, ny1, nz0, nz1]`. 1093 1094 Arguments: 1095 voxels : (int, list) 1096 number of voxels to be added (or a list of length 4) 1097 value : (int) 1098 intensity value (gray-scale color) of the padding 1099 1100 Example: 1101 ```python 1102 from vedo import Volume, dataurl, show 1103 iso = Volume(dataurl+'embryo.tif').isosurface() 1104 vol = iso.binarize(spacing=(100, 100, 100)).pad(10) 1105 vol.dilate([15,15,15]) 1106 show(iso, vol.isosurface(), N=2, axes=1) 1107 ``` 1108  1109 """ 1110 x0, x1, y0, y1, z0, z1 = self.dataset.GetExtent() 1111 pf = vtki.new("ImageConstantPad") 1112 pf.SetInputData(self.dataset) 1113 pf.SetConstant(value) 1114 if utils.is_sequence(voxels): 1115 pf.SetOutputWholeExtent( 1116 x0 - voxels[0], x1 + voxels[1], 1117 y0 - voxels[2], y1 + voxels[3], 1118 z0 - voxels[4], z1 + voxels[5], 1119 ) 1120 else: 1121 pf.SetOutputWholeExtent( 1122 x0 - voxels, x1 + voxels, 1123 y0 - voxels, y1 + voxels, 1124 z0 - voxels, z1 + voxels, 1125 ) 1126 pf.Update() 1127 self._update(pf.GetOutput()) 1128 self.pipeline = utils.OperationNode( 1129 "pad", comment=f"{voxels} voxels", parents=[self], c="#f28482" 1130 ) 1131 return self 1132 1133 def resize(self, newdims: List[int]) -> Self: 1134 """Increase or reduce the number of voxels of a Volume with interpolation.""" 1135 rsz = vtki.new("ImageResize") 1136 rsz.SetResizeMethodToOutputDimensions() 1137 rsz.SetInputData(self.dataset) 1138 rsz.SetOutputDimensions(newdims) 1139 rsz.Update() 1140 self.dataset = rsz.GetOutput() 1141 self._update(self.dataset) 1142 self.pipeline = utils.OperationNode( 1143 "resize", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1144 ) 1145 return self 1146 1147 def normalize(self) -> Self: 1148 """Normalize that scalar components for each point.""" 1149 norm = vtki.new("ImageNormalize") 1150 norm.SetInputData(self.dataset) 1151 norm.Update() 1152 self._update(norm.GetOutput()) 1153 self.pipeline = utils.OperationNode("normalize", parents=[self], c="#4cc9f0") 1154 return self 1155 1156 def mirror(self, axis="x") -> Self: 1157 """ 1158 Mirror flip along one of the cartesian axes. 1159 """ 1160 img = self.dataset 1161 1162 ff = vtki.new("ImageFlip") 1163 ff.SetInputData(img) 1164 if axis.lower() == "x": 1165 ff.SetFilteredAxis(0) 1166 elif axis.lower() == "y": 1167 ff.SetFilteredAxis(1) 1168 elif axis.lower() == "z": 1169 ff.SetFilteredAxis(2) 1170 else: 1171 vedo.logger.error("mirror must be set to either x, y, z or n") 1172 raise RuntimeError() 1173 ff.Update() 1174 self._update(ff.GetOutput()) 1175 self.pipeline = utils.OperationNode(f"mirror {axis}", parents=[self], c="#4cc9f0") 1176 return self 1177 1178 def operation(self, operation: str, volume2=None) -> "Volume": 1179 """ 1180 Perform operations with `Volume` objects. 1181 Keyword `volume2` can be a constant `float`. 1182 1183 Possible operations are: 1184 ``` 1185 and, or, xor, nand, nor, not, 1186 +, -, /, 1/x, sin, cos, exp, log, 1187 abs, **2, sqrt, min, max, atan, atan2, median, 1188 mag, dot, gradient, divergence, laplacian. 1189 ``` 1190 1191 Example: 1192 ```py 1193 from vedo import Box, show 1194 vol1 = Box(size=(35,10, 5)).binarize() 1195 vol2 = Box(size=( 5,10,35)).binarize() 1196 vol = vol1.operation("xor", vol2) 1197 show([[vol1, vol2], 1198 ["vol1 xor vol2", vol]], 1199 N=2, axes=1, viewup="z", 1200 ).close() 1201 ``` 1202 1203 Note: 1204 For logic operations, the two volumes must have the same bounds. 1205 If they do not, a larger image is created to contain both and the 1206 volumes are resampled onto the larger image before the operation is 1207 performed. This can be slow and memory intensive. 1208 1209 See also: 1210 - [volume_operations.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/volume_operations.py) 1211 """ 1212 op = operation.lower() 1213 image1 = self.dataset 1214 1215 if op in ["and", "or", "xor", "nand", "nor"]: 1216 1217 if not np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()): 1218 # create a larger image to contain both 1219 b1 = image1.GetBounds() 1220 b2 = volume2.dataset.GetBounds() 1221 b = [ 1222 min(b1[0], b2[0]), 1223 max(b1[1], b2[1]), 1224 min(b1[2], b2[2]), 1225 max(b1[3], b2[3]), 1226 min(b1[4], b2[4]), 1227 max(b1[5], b2[5]), 1228 ] 1229 dims1 = image1.GetDimensions() 1230 dims2 = volume2.dataset.GetDimensions() 1231 dims = [max(dims1[0], dims2[0]), max(dims1[1], dims2[1]), max(dims1[2], dims2[2])] 1232 1233 image = vtki.vtkImageData() 1234 image.SetDimensions(dims) 1235 spacing = ( 1236 (b[1] - b[0]) / dims[0], 1237 (b[3] - b[2]) / dims[1], 1238 (b[5] - b[4]) / dims[2], 1239 ) 1240 image.SetSpacing(spacing) 1241 image.SetOrigin((b[0], b[2], b[4])) 1242 image.AllocateScalars(vtki.VTK_UNSIGNED_CHAR, 1) 1243 image.GetPointData().GetScalars().FillComponent(0, 0) 1244 1245 interp1 = vtki.new("ImageReslice") 1246 interp1.SetInputData(image1) 1247 interp1.SetOutputExtent(image.GetExtent()) 1248 interp1.SetOutputOrigin(image.GetOrigin()) 1249 interp1.SetOutputSpacing(image.GetSpacing()) 1250 interp1.SetInterpolationModeToNearestNeighbor() 1251 interp1.Update() 1252 imageA = interp1.GetOutput() 1253 1254 interp2 = vtki.new("ImageReslice") 1255 interp2.SetInputData(volume2.dataset) 1256 interp2.SetOutputExtent(image.GetExtent()) 1257 interp2.SetOutputOrigin(image.GetOrigin()) 1258 interp2.SetOutputSpacing(image.GetSpacing()) 1259 interp2.SetInterpolationModeToNearestNeighbor() 1260 interp2.Update() 1261 imageB = interp2.GetOutput() 1262 1263 else: 1264 imageA = image1 1265 imageB = volume2.dataset 1266 1267 img_logic = vtki.new("ImageLogic") 1268 img_logic.SetInput1Data(imageA) 1269 img_logic.SetInput2Data(imageB) 1270 img_logic.SetOperation(["and", "or", "xor", "nand", "nor"].index(op)) 1271 img_logic.Update() 1272 1273 out_vol = Volume(img_logic.GetOutput()) 1274 out_vol.pipeline = utils.OperationNode( 1275 "operation", comment=f"{op}", parents=[self, volume2], c="#4cc9f0", shape="cylinder" 1276 ) 1277 return out_vol ###################################################### 1278 1279 if volume2 and isinstance(volume2, Volume): 1280 # assert image1.GetScalarType() == volume2.dataset.GetScalarType(), "volumes have different scalar types" 1281 # make sure they have the same bounds: 1282 assert np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()), "volumes have different bounds" 1283 # make sure they have the same spacing: 1284 assert np.allclose(image1.GetSpacing(), volume2.dataset.GetSpacing()), "volumes have different spacing" 1285 # make sure they have the same origin: 1286 assert np.allclose(image1.GetOrigin(), volume2.dataset.GetOrigin()), "volumes have different origin" 1287 1288 mf = None 1289 if op in ["median"]: 1290 mf = vtki.new("ImageMedian3D") 1291 mf.SetInputData(image1) 1292 elif op in ["mag"]: 1293 mf = vtki.new("ImageMagnitude") 1294 mf.SetInputData(image1) 1295 elif op in ["dot"]: 1296 mf = vtki.new("ImageDotProduct") 1297 mf.SetInput1Data(image1) 1298 mf.SetInput2Data(volume2.dataset) 1299 elif op in ["grad", "gradient"]: 1300 mf = vtki.new("ImageGradient") 1301 mf.SetDimensionality(3) 1302 mf.SetInputData(image1) 1303 elif op in ["div", "divergence"]: 1304 mf = vtki.new("ImageDivergence") 1305 mf.SetInputData(image1) 1306 elif op in ["laplacian"]: 1307 mf = vtki.new("ImageLaplacian") 1308 mf.SetDimensionality(3) 1309 mf.SetInputData(image1) 1310 elif op in ["not"]: 1311 mf = vtki.new("ImageLogic") 1312 mf.SetInput1Data(image1) 1313 mf.SetOperation(4) 1314 1315 if mf is not None: 1316 mf.Update() 1317 vol = Volume(mf.GetOutput()) 1318 vol.pipeline = utils.OperationNode( 1319 "operation", comment=f"{op}", parents=[self], c="#4cc9f0", shape="cylinder" 1320 ) 1321 return vol ###################################################### 1322 1323 mat = vtki.new("ImageMathematics") 1324 mat.SetInput1Data(image1) 1325 1326 K = None 1327 1328 if utils.is_number(volume2): 1329 K = volume2 1330 mat.SetConstantK(K) 1331 mat.SetConstantC(K) 1332 1333 elif volume2 is not None: # assume image2 is a constant value 1334 mat.SetInput2Data(volume2.dataset) 1335 1336 # ########################### 1337 if op in ["+", "add", "plus"]: 1338 if K: 1339 mat.SetOperationToAddConstant() 1340 else: 1341 mat.SetOperationToAdd() 1342 1343 elif op in ["-", "subtract", "minus"]: 1344 if K: 1345 mat.SetConstantC(-float(K)) 1346 mat.SetOperationToAddConstant() 1347 else: 1348 mat.SetOperationToSubtract() 1349 1350 elif op in ["*", "multiply", "times"]: 1351 if K: 1352 mat.SetOperationToMultiplyByK() 1353 else: 1354 mat.SetOperationToMultiply() 1355 1356 elif op in ["/", "divide"]: 1357 if K: 1358 mat.SetConstantK(1.0 / K) 1359 mat.SetOperationToMultiplyByK() 1360 else: 1361 mat.SetOperationToDivide() 1362 1363 elif op in ["1/x", "invert"]: 1364 mat.SetOperationToInvert() 1365 elif op in ["sin"]: 1366 mat.SetOperationToSin() 1367 elif op in ["cos"]: 1368 mat.SetOperationToCos() 1369 elif op in ["exp"]: 1370 mat.SetOperationToExp() 1371 elif op in ["log"]: 1372 mat.SetOperationToLog() 1373 elif op in ["abs"]: 1374 mat.SetOperationToAbsoluteValue() 1375 elif op in ["**2", "square"]: 1376 mat.SetOperationToSquare() 1377 elif op in ["sqrt", "sqr"]: 1378 mat.SetOperationToSquareRoot() 1379 elif op in ["min"]: 1380 mat.SetOperationToMin() 1381 elif op in ["max"]: 1382 mat.SetOperationToMax() 1383 elif op in ["atan"]: 1384 mat.SetOperationToATAN() 1385 elif op in ["atan2"]: 1386 mat.SetOperationToATAN2() 1387 else: 1388 vedo.logger.error(f"unknown operation {operation}") 1389 raise RuntimeError() 1390 mat.Update() 1391 1392 self._update(mat.GetOutput()) 1393 1394 self.pipeline = utils.OperationNode( 1395 "operation", comment=f"{op}", parents=[self, volume2], shape="cylinder", c="#4cc9f0" 1396 ) 1397 return self 1398 1399 def frequency_pass_filter(self, low_cutoff=None, high_cutoff=None, order=1) -> Self: 1400 """ 1401 Low-pass and high-pass filtering become trivial in the frequency domain. 1402 A portion of the pixels/voxels are simply masked or attenuated. 1403 This function applies a high pass Butterworth filter that attenuates the 1404 frequency domain image. 1405 1406 The gradual attenuation of the filter is important. 1407 A simple high-pass filter would simply mask a set of pixels in the frequency domain, 1408 but the abrupt transition would cause a ringing effect in the spatial domain. 1409 1410 Arguments: 1411 low_cutoff : (list) 1412 the cutoff frequencies for x, y and z 1413 high_cutoff : (list) 1414 the cutoff frequencies for x, y and z 1415 order : (int) 1416 order determines sharpness of the cutoff curve 1417 """ 1418 # https://lorensen.github.io/VTKExamples/site/Cxx/ImageProcessing/IdealHighPass 1419 fft = vtki.new("ImageFFT") 1420 fft.SetInputData(self.dataset) 1421 fft.Update() 1422 out = fft.GetOutput() 1423 1424 if high_cutoff: 1425 blp = vtki.new("ImageButterworthLowPass") 1426 blp.SetInputData(out) 1427 blp.SetCutOff(high_cutoff) 1428 blp.SetOrder(order) 1429 blp.Update() 1430 out = blp.GetOutput() 1431 1432 if low_cutoff: 1433 bhp = vtki.new("ImageButterworthHighPass") 1434 bhp.SetInputData(out) 1435 bhp.SetCutOff(low_cutoff) 1436 bhp.SetOrder(order) 1437 bhp.Update() 1438 out = bhp.GetOutput() 1439 1440 rfft = vtki.new("ImageRFFT") 1441 rfft.SetInputData(out) 1442 rfft.Update() 1443 1444 ecomp = vtki.new("ImageExtractComponents") 1445 ecomp.SetInputData(rfft.GetOutput()) 1446 ecomp.SetComponents(0) 1447 ecomp.Update() 1448 self._update(ecomp.GetOutput()) 1449 self.pipeline = utils.OperationNode("frequency_pass_filter", parents=[self], c="#4cc9f0") 1450 return self 1451 1452 def smooth_gaussian(self, sigma=(2, 2, 2), radius=None) -> Self: 1453 """ 1454 Performs a convolution of the input Volume with a gaussian. 1455 1456 Arguments: 1457 sigma : (float, list) 1458 standard deviation(s) in voxel units. 1459 A list can be given to smooth in the three direction differently. 1460 radius : (float, list) 1461 radius factor(s) determine how far out the gaussian 1462 kernel will go before being clamped to zero. A list can be given too. 1463 """ 1464 gsf = vtki.new("ImageGaussianSmooth") 1465 gsf.SetDimensionality(3) 1466 gsf.SetInputData(self.dataset) 1467 if utils.is_sequence(sigma): 1468 gsf.SetStandardDeviations(sigma) 1469 else: 1470 gsf.SetStandardDeviation(sigma) 1471 if radius is not None: 1472 if utils.is_sequence(radius): 1473 gsf.SetRadiusFactors(radius) 1474 else: 1475 gsf.SetRadiusFactor(radius) 1476 gsf.Update() 1477 self._update(gsf.GetOutput()) 1478 self.pipeline = utils.OperationNode("smooth_gaussian", parents=[self], c="#4cc9f0") 1479 return self 1480 1481 def smooth_median(self, neighbours=(2, 2, 2)) -> Self: 1482 """ 1483 Median filter that replaces each pixel with the median value 1484 from a rectangular neighborhood around that pixel. 1485 """ 1486 imgm = vtki.new("ImageMedian3D") 1487 imgm.SetInputData(self.dataset) 1488 if utils.is_sequence(neighbours): 1489 imgm.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1490 else: 1491 imgm.SetKernelSize(neighbours, neighbours, neighbours) 1492 imgm.Update() 1493 self._update(imgm.GetOutput()) 1494 self.pipeline = utils.OperationNode("smooth_median", parents=[self], c="#4cc9f0") 1495 return self 1496 1497 def erode(self, neighbours=(2, 2, 2)) -> Self: 1498 """ 1499 Replace a voxel with the minimum over an ellipsoidal neighborhood of voxels. 1500 If `neighbours` of an axis is 1, no processing is done on that axis. 1501 1502 Examples: 1503 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1504 1505  1506 """ 1507 ver = vtki.new("ImageContinuousErode3D") 1508 ver.SetInputData(self.dataset) 1509 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1510 ver.Update() 1511 self._update(ver.GetOutput()) 1512 self.pipeline = utils.OperationNode("erode", parents=[self], c="#4cc9f0") 1513 return self 1514 1515 def dilate(self, neighbours=(2, 2, 2)) -> Self: 1516 """ 1517 Replace a voxel with the maximum over an ellipsoidal neighborhood of voxels. 1518 If `neighbours` of an axis is 1, no processing is done on that axis. 1519 1520 Check also `erode()` and `pad()`. 1521 1522 Examples: 1523 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1524 """ 1525 ver = vtki.new("ImageContinuousDilate3D") 1526 ver.SetInputData(self.dataset) 1527 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1528 ver.Update() 1529 self._update(ver.GetOutput()) 1530 self.pipeline = utils.OperationNode("dilate", parents=[self], c="#4cc9f0") 1531 return self 1532 1533 def magnitude(self) -> Self: 1534 """Colapses components with magnitude function.""" 1535 imgm = vtki.new("ImageMagnitude") 1536 imgm.SetInputData(self.dataset) 1537 imgm.Update() 1538 self._update(imgm.GetOutput()) 1539 self.pipeline = utils.OperationNode("magnitude", parents=[self], c="#4cc9f0") 1540 return self 1541 1542 def topoints(self) -> "vedo.Points": 1543 """ 1544 Extract all image voxels as points. 1545 This function takes an input `Volume` and creates an `Mesh` 1546 that contains the points and the point attributes. 1547 1548 Examples: 1549 - [vol2points.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/vol2points.py) 1550 """ 1551 v2p = vtki.new("ImageToPoints") 1552 v2p.SetInputData(self.dataset) 1553 v2p.Update() 1554 mpts = vedo.Points(v2p.GetOutput()) 1555 mpts.pipeline = utils.OperationNode("topoints", parents=[self], c="#4cc9f0:#e9c46a") 1556 return mpts 1557 1558 def euclidean_distance(self, anisotropy=False, max_distance=None) -> "Volume": 1559 """ 1560 Implementation of the Euclidean DT (Distance Transform) using Saito's algorithm. 1561 The distance map produced contains the square of the Euclidean distance values. 1562 The algorithm has a O(n^(D+1)) complexity over n x n x...x n images in D dimensions. 1563 1564 Check out also: https://en.wikipedia.org/wiki/Distance_transform 1565 1566 Arguments: 1567 anisotropy : bool 1568 used to define whether Spacing should be used in the 1569 computation of the distances. 1570 max_distance : bool 1571 any distance bigger than max_distance will not be 1572 computed but set to this specified value instead. 1573 1574 Examples: 1575 - [euclidian_dist.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/euclidian_dist.py) 1576 """ 1577 euv = vtki.new("ImageEuclideanDistance") 1578 euv.SetInputData(self.dataset) 1579 euv.SetConsiderAnisotropy(anisotropy) 1580 if max_distance is not None: 1581 euv.InitializeOn() 1582 euv.SetMaximumDistance(max_distance) 1583 euv.SetAlgorithmToSaito() 1584 euv.Update() 1585 vol = Volume(euv.GetOutput()) 1586 vol.pipeline = utils.OperationNode("euclidean_distance", parents=[self], c="#4cc9f0") 1587 return vol 1588 1589 def correlation_with(self, vol2: "Volume", dim=2) -> "Volume": 1590 """ 1591 Find the correlation between two volumetric data sets. 1592 Keyword `dim` determines whether the correlation will be 3D, 2D or 1D. 1593 The default is a 2D Correlation. 1594 1595 The output size will match the size of the first input. 1596 The second input is considered the correlation kernel. 1597 """ 1598 imc = vtki.new("ImageCorrelation") 1599 imc.SetInput1Data(self.dataset) 1600 imc.SetInput2Data(vol2.dataset) 1601 imc.SetDimensionality(dim) 1602 imc.Update() 1603 vol = Volume(imc.GetOutput()) 1604 1605 vol.pipeline = utils.OperationNode("correlation_with", parents=[self, vol2], c="#4cc9f0") 1606 return vol 1607 1608 def scale_voxels(self, scale=1) -> Self: 1609 """Scale the voxel content by factor `scale`.""" 1610 rsl = vtki.new("ImageReslice") 1611 rsl.SetInputData(self.dataset) 1612 rsl.SetScalarScale(scale) 1613 rsl.Update() 1614 self._update(rsl.GetOutput()) 1615 self.pipeline = utils.OperationNode( 1616 "scale_voxels", comment=f"scale={scale}", parents=[self], c="#4cc9f0" 1617 ) 1618 return self
32class Volume(VolumeAlgorithms, VolumeVisual): 33 """ 34 Class to describe dataset that are defined on "voxels", 35 the 3D equivalent of 2D pixels. 36 """ 37 def __init__( 38 self, 39 inputobj=None, 40 dims=None, 41 origin=None, 42 spacing=None, 43 ) -> None: 44 """ 45 This class can be initialized with a numpy object, 46 a `vtkImageData` or a list of 2D bmp files. 47 48 Arguments: 49 origin : (list) 50 set volume origin coordinates 51 spacing : (list) 52 voxel dimensions in x, y and z. 53 dims : (list) 54 specify the dimensions of the volume. 55 56 Example: 57 ```python 58 from vedo import Volume 59 vol = Volume("path/to/mydata/rec*.bmp") 60 vol.show() 61 ``` 62 63 Examples: 64 - [numpy2volume1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume1.py) 65 66  67 68 - [read_volume2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/read_volume2.py) 69 70  71 72 .. note:: 73 if a `list` of values is used for `alphas` this is interpreted 74 as a transfer function along the range of the scalar. 75 """ 76 super().__init__() 77 78 self.name = "Volume" 79 self.filename = "" 80 self.file_size = "" 81 82 self.info = {} 83 self.time = time.time() 84 85 self.actor = vtki.vtkVolume() 86 self.actor.retrieve_object = weak_ref_to(self) 87 self.properties = self.actor.GetProperty() 88 89 self.transform = None 90 self.point_locator = None 91 self.cell_locator = None 92 self.line_locator = None 93 94 ################### 95 if isinstance(inputobj, str): 96 if "https://" in inputobj: 97 inputobj = vedo.file_io.download(inputobj, verbose=False) # fpath 98 elif os.path.isfile(inputobj): 99 self.filename = inputobj 100 else: 101 inputobj = sorted(glob.glob(inputobj)) 102 103 ################### 104 inputtype = str(type(inputobj)) 105 106 # print('Volume inputtype', inputtype, c='b') 107 108 if inputobj is None: 109 img = vtki.vtkImageData() 110 111 elif utils.is_sequence(inputobj): 112 113 if isinstance(inputobj[0], str) and ".bmp" in inputobj[0].lower(): 114 # scan sequence of BMP files 115 ima = vtki.new("ImageAppend") 116 ima.SetAppendAxis(2) 117 pb = utils.ProgressBar(0, len(inputobj)) 118 for i in pb.range(): 119 f = inputobj[i] 120 if "_rec_spr" in f: # OPT specific 121 continue 122 picr = vtki.new("BMPReader") 123 picr.SetFileName(f) 124 picr.Update() 125 mgf = vtki.new("ImageMagnitude") 126 mgf.SetInputData(picr.GetOutput()) 127 mgf.Update() 128 ima.AddInputData(mgf.GetOutput()) 129 pb.print("loading...") 130 ima.Update() 131 img = ima.GetOutput() 132 133 else: 134 135 if len(inputobj.shape) == 1: 136 varr = utils.numpy2vtk(inputobj) 137 else: 138 varr = utils.numpy2vtk(inputobj.ravel(order="F")) 139 varr.SetName("input_scalars") 140 141 img = vtki.vtkImageData() 142 if dims is not None: 143 img.SetDimensions(dims[2], dims[1], dims[0]) 144 else: 145 if len(inputobj.shape) == 1: 146 vedo.logger.error("must set dimensions (dims keyword) in Volume") 147 raise RuntimeError() 148 img.SetDimensions(inputobj.shape) 149 img.GetPointData().AddArray(varr) 150 img.GetPointData().SetActiveScalars(varr.GetName()) 151 152 elif isinstance(inputobj, vtki.vtkImageData): 153 img = inputobj 154 155 elif isinstance(inputobj, str): 156 if "https://" in inputobj: 157 inputobj = vedo.file_io.download(inputobj, verbose=False) 158 img = vedo.file_io.loadImageData(inputobj) 159 self.filename = inputobj 160 161 else: 162 vedo.logger.error(f"cannot understand input type {inputtype}") 163 return 164 165 if dims is not None: 166 img.SetDimensions(dims) 167 168 if origin is not None: 169 img.SetOrigin(origin) 170 171 if spacing is not None: 172 img.SetSpacing(spacing) 173 174 self.dataset = img 175 self.transform = None 176 177 ##################################### 178 mapper = vtki.new("SmartVolumeMapper") 179 mapper.SetInputData(img) 180 self.actor.SetMapper(mapper) 181 182 if img.GetPointData().GetScalars(): 183 if img.GetPointData().GetScalars().GetNumberOfComponents() == 1: 184 self.properties.SetShade(True) 185 self.properties.SetInterpolationType(1) 186 self.cmap("RdBu_r") 187 self.alpha([0.0, 0.0, 0.2, 0.4, 0.8, 1.0]) 188 self.alpha_gradient(None) 189 self.properties.SetScalarOpacityUnitDistance(1.0) 190 191 self.pipeline = utils.OperationNode( 192 "Volume", comment=f"dims={tuple(self.dimensions())}", c="#4cc9f0" 193 ) 194 ####################################################################### 195 196 @property 197 def mapper(self): 198 """Return the underlying `vtkMapper` object.""" 199 return self.actor.GetMapper() 200 201 @mapper.setter 202 def mapper(self, mapper): 203 """ 204 Set the underlying `vtkMapper` object. 205 206 Arguments: 207 mapper : (str, vtkMapper) 208 either 'gpu', 'opengl_gpu', 'fixed' or 'smart' 209 """ 210 if isinstance(mapper, 211 (vtki.get_class("Mapper"), vtki.get_class("ImageResliceMapper")) 212 ): 213 pass 214 elif mapper is None: 215 mapper = vtki.new("SmartVolumeMapper") 216 elif "gpu" in mapper: 217 mapper = vtki.new("GPUVolumeRayCastMapper") 218 elif "opengl_gpu" in mapper: 219 mapper = vtki.new("OpenGLGPUVolumeRayCastMapper") 220 elif "smart" in mapper: 221 mapper = vtki.new("SmartVolumeMapper") 222 elif "fixed" in mapper: 223 mapper = vtki.new("FixedPointVolumeRayCastMapper") 224 else: 225 print("Error unknown mapper type", [mapper]) 226 raise RuntimeError() 227 self.actor.SetMapper(mapper) 228 229 def c(self, *args, **kwargs) -> Self: 230 """Deprecated. Use `Volume.cmap()` instead.""" 231 vedo.logger.warning("Volume.c() is deprecated, use Volume.cmap() instead") 232 return self.cmap(*args, **kwargs) 233 234 def _update(self, data, reset_locators=False): 235 # reset_locators here is dummy 236 self.dataset = data 237 self.mapper.SetInputData(data) 238 self.dataset.GetPointData().Modified() 239 self.mapper.Modified() 240 self.mapper.Update() 241 return self 242 243 def __str__(self): 244 """Print a summary for the `Volume` object.""" 245 module = self.__class__.__module__ 246 name = self.__class__.__name__ 247 out = vedo.printc( 248 f"{module}.{name} at ({hex(self.memory_address())})".ljust(75), 249 c="c", bold=True, invert=True, return_string=True, 250 ) 251 out += "\x1b[0m\x1b[36;1m" 252 253 out+= "name".ljust(14) + ": " + str(self.name) + "\n" 254 if self.filename: 255 out+= "filename".ljust(14) + ": " + str(self.filename) + "\n" 256 257 out+= "dimensions".ljust(14) + ": " + str(self.shape) + "\n" 258 259 out+= "origin".ljust(14) + ": " 260 out+= utils.precision(self.origin(), 6) + "\n" 261 262 out+= "center".ljust(14) + ": " 263 out+= utils.precision(self.center(), 6) + "\n" 264 265 out+= "spacing".ljust(14) + ": " 266 out+= utils.precision(self.spacing(), 6) + "\n" 267 268 bnds = self.bounds() 269 bx1, bx2 = utils.precision(bnds[0], 3), utils.precision(bnds[1], 3) 270 by1, by2 = utils.precision(bnds[2], 3), utils.precision(bnds[3], 3) 271 bz1, bz2 = utils.precision(bnds[4], 3), utils.precision(bnds[5], 3) 272 out+= "bounds".ljust(14) + ":" 273 out+= " x=(" + bx1 + ", " + bx2 + ")," 274 out+= " y=(" + by1 + ", " + by2 + ")," 275 out+= " z=(" + bz1 + ", " + bz2 + ")\n" 276 277 out+= "memory size".ljust(14) + ": " 278 out+= str(int(self.dataset.GetActualMemorySize()/1024+0.5))+" MB\n" 279 280 st = self.dataset.GetScalarTypeAsString() 281 out+= "scalar size".ljust(14) + ": " 282 out+= str(self.dataset.GetScalarSize()) + f" bytes ({st})\n" 283 out+= "scalar range".ljust(14) + ": " 284 out+= str(self.dataset.GetScalarRange()) + "\n" 285 286 #utils.print_histogram(self, logscale=True, bins=8, height=15, c="b", bold=True) 287 return out.rstrip() + "\x1b[0m" 288 289 def _repr_html_(self): 290 """ 291 HTML representation of the Volume object for Jupyter Notebooks. 292 293 Returns: 294 HTML text with the image and some properties. 295 """ 296 import io 297 import base64 298 from PIL import Image 299 300 library_name = "vedo.volume.Volume" 301 help_url = "https://vedo.embl.es/docs/vedo/volume.html" 302 303 arr = self.thumbnail(azimuth=0, elevation=-60, zoom=1.4, axes=True) 304 305 im = Image.fromarray(arr) 306 buffered = io.BytesIO() 307 im.save(buffered, format="PNG", quality=100) 308 encoded = base64.b64encode(buffered.getvalue()).decode("utf-8") 309 url = "data:image/png;base64," + encoded 310 image = f"<img src='{url}'></img>" 311 312 # statisitics 313 bounds = "<br/>".join( 314 [ 315 utils.precision(min_x, 4) + " ... " + utils.precision(max_x, 4) 316 for min_x, max_x in zip(self.bounds()[::2], self.bounds()[1::2]) 317 ] 318 ) 319 320 help_text = "" 321 if self.name: 322 help_text += f"<b> {self.name}:   </b>" 323 help_text += '<b><a href="' + help_url + '" target="_blank">' + library_name + "</a></b>" 324 if self.filename: 325 dots = "" 326 if len(self.filename) > 30: 327 dots = "..." 328 help_text += f"<br/><code><i>({dots}{self.filename[-30:]})</i></code>" 329 330 pdata = "" 331 if self.dataset.GetPointData().GetScalars(): 332 if self.dataset.GetPointData().GetScalars().GetName(): 333 name = self.dataset.GetPointData().GetScalars().GetName() 334 pdata = "<tr><td><b> point data array </b></td><td>" + name + "</td></tr>" 335 336 cdata = "" 337 if self.dataset.GetCellData().GetScalars(): 338 if self.dataset.GetCellData().GetScalars().GetName(): 339 name = self.dataset.GetCellData().GetScalars().GetName() 340 cdata = "<tr><td><b> voxel data array </b></td><td>" + name + "</td></tr>" 341 342 img = self.dataset 343 344 allt = [ 345 "<table>", 346 "<tr>", 347 "<td>", 348 image, 349 "</td>", 350 "<td style='text-align: center; vertical-align: center;'><br/>", 351 help_text, 352 "<table>", 353 "<tr><td><b> bounds </b> <br/> (x/y/z) </td><td>" + str(bounds) + "</td></tr>", 354 "<tr><td><b> dimensions </b></td><td>" + str(img.GetDimensions()) + "</td></tr>", 355 "<tr><td><b> voxel spacing </b></td><td>" 356 + utils.precision(img.GetSpacing(), 3) 357 + "</td></tr>", 358 "<tr><td><b> in memory size </b></td><td>" 359 + str(int(img.GetActualMemorySize() / 1024)) 360 + "MB</td></tr>", 361 pdata, 362 cdata, 363 "<tr><td><b> scalar range </b></td><td>" 364 + utils.precision(img.GetScalarRange(), 4) 365 + "</td></tr>", 366 "</table>", 367 "</table>", 368 ] 369 return "\n".join(allt) 370 371 def copy(self, deep=True) -> "Volume": 372 """Return a copy of the Volume. Alias of `clone()`.""" 373 return self.clone(deep=deep) 374 375 def clone(self, deep=True) -> "Volume": 376 """Return a clone copy of the Volume. Alias of `copy()`.""" 377 if deep: 378 newimg = vtki.vtkImageData() 379 newimg.CopyStructure(self.dataset) 380 newimg.CopyAttributes(self.dataset) 381 newvol = Volume(newimg) 382 else: 383 newvol = Volume(self.dataset) 384 385 prop = vtki.vtkVolumeProperty() 386 prop.DeepCopy(self.properties) 387 newvol.actor.SetProperty(prop) 388 newvol.properties = prop 389 390 newvol.pipeline = utils.OperationNode("clone", parents=[self], c="#bbd0ff", shape="diamond") 391 return newvol 392 393 def astype(self, dtype: Union[str, int]) -> Self: 394 """ 395 Reset the type of the scalars array. 396 397 Arguments: 398 dtype : (str) 399 the type of the scalars array in 400 ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"] 401 """ 402 if dtype in ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"]: 403 caster = vtki.new("ImageCast") 404 caster.SetInputData(self.dataset) 405 caster.SetOutputScalarType(int(vtki.array_types[dtype])) 406 caster.ClampOverflowOn() 407 caster.Update() 408 self._update(caster.GetOutput()) 409 self.pipeline = utils.OperationNode(f"astype({dtype})", parents=[self], c="#4cc9f0") 410 else: 411 vedo.logger.error(f"astype(): unknown type {dtype}") 412 raise ValueError() 413 return self 414 415 def component_weight(self, i: int, weight: float) -> Self: 416 """Set the scalar component weight in range [0,1].""" 417 self.properties.SetComponentWeight(i, weight) 418 return self 419 420 def xslice(self, i: int) -> Mesh: 421 """Extract the slice at index `i` of volume along x-axis.""" 422 vslice = vtki.new("ImageDataGeometryFilter") 423 vslice.SetInputData(self.dataset) 424 nx, ny, nz = self.dataset.GetDimensions() 425 if i > nx - 1: 426 i = nx - 1 427 vslice.SetExtent(i, i, 0, ny, 0, nz) 428 vslice.Update() 429 m = Mesh(vslice.GetOutput()) 430 m.pipeline = utils.OperationNode(f"xslice {i}", parents=[self], c="#4cc9f0:#e9c46a") 431 return m 432 433 def yslice(self, j: int) -> Mesh: 434 """Extract the slice at index `j` of volume along y-axis.""" 435 vslice = vtki.new("ImageDataGeometryFilter") 436 vslice.SetInputData(self.dataset) 437 nx, ny, nz = self.dataset.GetDimensions() 438 if j > ny - 1: 439 j = ny - 1 440 vslice.SetExtent(0, nx, j, j, 0, nz) 441 vslice.Update() 442 m = Mesh(vslice.GetOutput()) 443 m.pipeline = utils.OperationNode(f"yslice {j}", parents=[self], c="#4cc9f0:#e9c46a") 444 return m 445 446 def zslice(self, k: int) -> Mesh: 447 """Extract the slice at index `i` of volume along z-axis.""" 448 vslice = vtki.new("ImageDataGeometryFilter") 449 vslice.SetInputData(self.dataset) 450 nx, ny, nz = self.dataset.GetDimensions() 451 if k > nz - 1: 452 k = nz - 1 453 vslice.SetExtent(0, nx, 0, ny, k, k) 454 vslice.Update() 455 m = Mesh(vslice.GetOutput()) 456 m.pipeline = utils.OperationNode(f"zslice {k}", parents=[self], c="#4cc9f0:#e9c46a") 457 return m 458 459 def slice_plane(self, origin: List[float], normal: List[float], autocrop=False, border=0.5, mode="linear") -> Mesh: 460 """ 461 Extract the slice along a given plane position and normal. 462 463 Two metadata arrays are added to the output Mesh: 464 - "shape" : contains the shape of the slice 465 - "original_bounds" : contains the original bounds of the slice 466 One can access them with e.g. `myslice.metadata["shape"]`. 467 468 Arguments: 469 origin : (list) 470 position of the plane 471 normal : (list) 472 normal to the plane 473 autocrop : (bool) 474 crop the output to the minimal possible size 475 border : (float) 476 add a border to the output slice 477 mode : (str) 478 interpolation mode, one of the following: "linear", "nearest", "cubic" 479 480 Example: 481 - [slice_plane1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane1.py) 482 483  484 485 - [slice_plane2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane2.py) 486 487  488 489 - [slice_plane3.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane3.py) 490 491  492 """ 493 newaxis = utils.versor(normal) 494 pos = np.array(origin) 495 initaxis = (0, 0, 1) 496 crossvec = np.cross(initaxis, newaxis) 497 angle = np.arccos(np.dot(initaxis, newaxis)) 498 T = vtki.vtkTransform() 499 T.PostMultiply() 500 T.RotateWXYZ(np.rad2deg(angle), crossvec.tolist()) 501 T.Translate(pos.tolist()) 502 503 reslice = vtki.new("ImageReslice") 504 reslice.SetResliceAxes(T.GetMatrix()) 505 reslice.SetInputData(self.dataset) 506 reslice.SetOutputDimensionality(2) 507 reslice.SetTransformInputSampling(True) 508 reslice.SetGenerateStencilOutput(False) 509 if border: 510 reslice.SetBorder(True) 511 reslice.SetBorderThickness(border) 512 else: 513 reslice.SetBorder(False) 514 if mode == "linear": 515 reslice.SetInterpolationModeToLinear() 516 elif mode == "nearest": 517 reslice.SetInterpolationModeToNearestNeighbor() 518 elif mode == "cubic": 519 reslice.SetInterpolationModeToCubic() 520 else: 521 vedo.logger.error(f"in slice_plane(): unknown interpolation mode {mode}") 522 raise ValueError() 523 reslice.SetAutoCropOutput(not autocrop) 524 reslice.Update() 525 img = reslice.GetOutput() 526 527 vslice = vtki.new("ImageDataGeometryFilter") 528 vslice.SetInputData(img) 529 vslice.Update() 530 531 msh = Mesh(vslice.GetOutput()).apply_transform(T) 532 msh.properties.LightingOff() 533 534 d0, d1, _ = img.GetDimensions() 535 varr1 = utils.numpy2vtk([d1, d0], name="shape") 536 varr2 = utils.numpy2vtk(img.GetBounds(), name="original_bounds") 537 msh.dataset.GetFieldData().AddArray(varr1) 538 msh.dataset.GetFieldData().AddArray(varr2) 539 msh.pipeline = utils.OperationNode("slice_plane", parents=[self], c="#4cc9f0:#e9c46a") 540 return msh 541 542 def slab(self, slice_range=(), axis='z', operation="mean") -> Mesh: 543 """ 544 Extract a slab from a `Volume` by combining 545 all of the slices of an image to create a single slice. 546 547 Returns a `Mesh` containing metadata which 548 can be accessed with e.g. `mesh.metadata["slab_range"]`. 549 550 Metadata: 551 slab_range : (list) 552 contains the range of slices extracted 553 slab_axis : (str) 554 contains the axis along which the slab was extracted 555 slab_operation : (str) 556 contains the operation performed on the slab 557 slab_bounding_box : (list) 558 contains the bounding box of the slab 559 560 Arguments: 561 slice_range : (list) 562 range of slices to extract 563 axis : (str) 564 axis along which to extract the slab 565 operation : (str) 566 operation to perform on the slab, 567 allowed values are: "sum", "min", "max", "mean". 568 569 Example: 570 - [slab.py](https://github.com/marcomusy/vedo/blob/master/examples/volumetric/slab_vol.py) 571 572  573 """ 574 if len(slice_range) != 2: 575 vedo.logger.error("in slab(): slice_range is empty or invalid") 576 raise ValueError() 577 578 islab = vtki.new("ImageSlab") 579 islab.SetInputData(self.dataset) 580 581 if operation in ["+", "add", "sum"]: 582 islab.SetOperationToSum() 583 elif "min" in operation: 584 islab.SetOperationToMin() 585 elif "max" in operation: 586 islab.SetOperationToMax() 587 elif "mean" in operation: 588 islab.SetOperationToMean() 589 else: 590 vedo.logger.error(f"in slab(): unknown operation {operation}") 591 raise ValueError() 592 593 dims = self.dimensions() 594 if axis == 'x': 595 islab.SetOrientationToX() 596 if slice_range[0] > dims[0]-1: 597 slice_range[0] = dims[0]-1 598 if slice_range[1] > dims[0]-1: 599 slice_range[1] = dims[0]-1 600 elif axis == 'y': 601 islab.SetOrientationToY() 602 if slice_range[0] > dims[1]-1: 603 slice_range[0] = dims[1]-1 604 if slice_range[1] > dims[1]-1: 605 slice_range[1] = dims[1]-1 606 elif axis == 'z': 607 islab.SetOrientationToZ() 608 if slice_range[0] > dims[2]-1: 609 slice_range[0] = dims[2]-1 610 if slice_range[1] > dims[2]-1: 611 slice_range[1] = dims[2]-1 612 else: 613 vedo.logger.error(f"Error in slab(): unknown axis {axis}") 614 raise RuntimeError() 615 616 islab.SetSliceRange(slice_range) 617 islab.Update() 618 619 msh = Mesh(islab.GetOutput()).lighting('off') 620 msh.mapper.SetLookupTable(utils.ctf2lut(self, msh)) 621 msh.mapper.SetScalarRange(self.scalar_range()) 622 623 msh.metadata["slab_range"] = slice_range 624 msh.metadata["slab_axis"] = axis 625 msh.metadata["slab_operation"] = operation 626 627 # compute bounds of slab 628 origin = list(self.origin()) 629 spacing = list(self.spacing()) 630 if axis == 'x': 631 msh.metadata["slab_bounding_box"] = [ 632 origin[0] + slice_range[0]*spacing[0], 633 origin[0] + slice_range[1]*spacing[0], 634 origin[1], 635 origin[1] + dims[1]*spacing[1], 636 origin[2], 637 origin[2] + dims[2]*spacing[2], 638 ] 639 elif axis == 'y': 640 msh.metadata["slab_bounding_box"] = [ 641 origin[0], 642 origin[0] + dims[0]*spacing[0], 643 origin[1] + slice_range[0]*spacing[1], 644 origin[1] + slice_range[1]*spacing[1], 645 origin[2], 646 origin[2] + dims[2]*spacing[2], 647 ] 648 elif axis == 'z': 649 msh.metadata["slab_bounding_box"] = [ 650 origin[0], 651 origin[0] + dims[0]*spacing[0], 652 origin[1], 653 origin[1] + dims[1]*spacing[1], 654 origin[2] + slice_range[0]*spacing[2], 655 origin[2] + slice_range[1]*spacing[2], 656 ] 657 658 msh.pipeline = utils.OperationNode( 659 f"slab{slice_range}", 660 comment=f"axis={axis}, operation={operation}", 661 parents=[self], 662 c="#4cc9f0:#e9c46a", 663 ) 664 msh.name = "SlabMesh" 665 return msh 666 667 668 def warp( 669 self, 670 source: Union["vedo.Points", List], 671 target: Union["vedo.Points", List], 672 sigma=1, mode="3d", fit=True, 673 ) -> Self: 674 """ 675 Warp volume scalars within a Volume by specifying 676 source and target sets of points. 677 678 Arguments: 679 source : (Points, list) 680 the list of source points 681 target : (Points, list) 682 the list of target points 683 fit : (bool) 684 fit/adapt the old bounding box to the warped geometry 685 """ 686 if isinstance(source, vedo.Points): 687 source = source.vertices 688 if isinstance(target, vedo.Points): 689 target = target.vertices 690 691 NLT = transformations.NonLinearTransform() 692 NLT.source_points = source 693 NLT.target_points = target 694 NLT.sigma = sigma 695 NLT.mode = mode 696 697 self.apply_transform(NLT, fit=fit) 698 self.pipeline = utils.OperationNode("warp", parents=[self], c="#4cc9f0") 699 return self 700 701 def apply_transform( 702 self, 703 T: Union[transformations.LinearTransform, transformations.NonLinearTransform], 704 fit=True, interpolation="cubic", 705 ) -> Self: 706 """ 707 Apply a transform to the scalars in the volume. 708 709 Arguments: 710 T : (LinearTransform, NonLinearTransform) 711 The transformation to be applied 712 fit : (bool) 713 fit/adapt the old bounding box to the modified geometry 714 interpolation : (str) 715 one of the following: "nearest", "linear", "cubic" 716 """ 717 if utils.is_sequence(T): 718 T = transformations.LinearTransform(T) 719 720 TI = T.compute_inverse() 721 722 reslice = vtki.new("ImageReslice") 723 reslice.SetInputData(self.dataset) 724 reslice.SetResliceTransform(TI.T) 725 reslice.SetOutputDimensionality(3) 726 if "lin" in interpolation.lower(): 727 reslice.SetInterpolationModeToLinear() 728 elif "near" in interpolation.lower(): 729 reslice.SetInterpolationModeToNearestNeighbor() 730 elif "cubic" in interpolation.lower(): 731 reslice.SetInterpolationModeToCubic() 732 else: 733 vedo.logger.error( 734 f"in apply_transform: unknown interpolation mode {interpolation}") 735 raise ValueError() 736 reslice.SetAutoCropOutput(fit) 737 reslice.Update() 738 self._update(reslice.GetOutput()) 739 self.transform = T 740 self.pipeline = utils.OperationNode( 741 "apply_transform", parents=[self], c="#4cc9f0") 742 return self 743 744 def imagedata(self) -> vtki.vtkImageData: 745 """ 746 DEPRECATED: 747 Use `Volume.dataset` instead. 748 749 Return the underlying `vtkImagaData` object. 750 """ 751 print("Volume.imagedata() is deprecated, use Volume.dataset instead") 752 return self.dataset 753 754 def modified(self) -> Self: 755 """ 756 Mark the object as modified. 757 758 Example: 759 760 - [numpy2volume0.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume0.py) 761 """ 762 scals = self.dataset.GetPointData().GetScalars() 763 if scals: 764 scals.Modified() 765 return self 766 767 def tonumpy(self) -> np.ndarray: 768 """ 769 Get read-write access to voxels of a Volume object as a numpy array. 770 771 When you set values in the output image, you don't want numpy to reallocate the array 772 but instead set values in the existing array, so use the [:] operator. 773 774 Example: 775 `arr[:] = arr*2 + 15` 776 777 If the array is modified add a call to: 778 `volume.modified()` 779 when all your modifications are completed. 780 """ 781 narray_shape = tuple(reversed(self.dataset.GetDimensions())) 782 783 scals = self.dataset.GetPointData().GetScalars() 784 comps = scals.GetNumberOfComponents() 785 if comps == 1: 786 narray = utils.vtk2numpy(scals).reshape(narray_shape) 787 narray = np.transpose(narray, axes=[2, 1, 0]) 788 else: 789 narray = utils.vtk2numpy(scals).reshape(*narray_shape, comps) 790 narray = np.transpose(narray, axes=[2, 1, 0, 3]) 791 792 # narray = utils.vtk2numpy(self.dataset.GetPointData().GetScalars()).reshape(narray_shape) 793 # narray = np.transpose(narray, axes=[2, 1, 0]) 794 return narray 795 796 @property 797 def shape(self) -> np.ndarray: 798 """Return the nr. of voxels in the 3 dimensions.""" 799 return np.array(self.dataset.GetDimensions()) 800 801 def dimensions(self) -> np.ndarray: 802 """Return the nr. of voxels in the 3 dimensions.""" 803 return np.array(self.dataset.GetDimensions()) 804 805 def scalar_range(self) -> np.ndarray: 806 """Return the range of the scalar values.""" 807 return np.array(self.dataset.GetScalarRange()) 808 809 def spacing(self, s=None) -> Union[Self, Iterable[float]]: 810 """Set/get the voxels size in the 3 dimensions.""" 811 if s is not None: 812 self.dataset.SetSpacing(s) 813 return self 814 return np.array(self.dataset.GetSpacing()) 815 816 def origin(self, s=None) -> Union[Self, Iterable[float]]: 817 """ 818 Set/get the origin of the volumetric dataset. 819 820 The origin is the position in world coordinates of the point index (0,0,0). 821 This point does not have to be part of the dataset, in other words, 822 the dataset extent does not have to start at (0,0,0) and the origin 823 can be outside of the dataset bounding box. 824 The origin plus spacing determine the position in space of the points. 825 """ 826 if s is not None: 827 self.dataset.SetOrigin(s) 828 return self 829 return np.array(self.dataset.GetOrigin()) 830 831 def pos(self, p=None) -> Union[Self, Iterable[float]]: 832 """Set/get the position of the volumetric dataset.""" 833 if p is not None: 834 self.origin(p) 835 return self 836 return self.origin() 837 838 def center(self) -> np.ndarray: 839 """Get the center of the volumetric dataset.""" 840 # note that this does not have the set method like origin and spacing 841 return np.array(self.dataset.GetCenter()) 842 843 def shift(self, s: list) -> Self: 844 """Shift the volumetric dataset by a vector.""" 845 self.origin(self.origin() + np.array(s)) 846 return self 847 848 def rotate_x(self, angle: float, rad=False, around=None) -> Self: 849 """ 850 Rotate around x-axis. If angle is in radians set `rad=True`. 851 852 Use `around` to define a pivoting point. 853 """ 854 if angle == 0: 855 return self 856 LT = transformations.LinearTransform().rotate_x(angle, rad, around) 857 return self.apply_transform(LT, fit=True, interpolation="linear") 858 859 def rotate_y(self, angle: float, rad=False, around=None) -> Self: 860 """ 861 Rotate around y-axis. If angle is in radians set `rad=True`. 862 863 Use `around` to define a pivoting point. 864 """ 865 if angle == 0: 866 return self 867 LT = transformations.LinearTransform().rotate_y(angle, rad, around) 868 return self.apply_transform(LT, fit=True, interpolation="linear") 869 870 def rotate_z(self, angle: float, rad=False, around=None) -> Self: 871 """ 872 Rotate around z-axis. If angle is in radians set `rad=True`. 873 874 Use `around` to define a pivoting point. 875 """ 876 if angle == 0: 877 return self 878 LT = transformations.LinearTransform().rotate_z(angle, rad, around) 879 return self.apply_transform(LT, fit=True, interpolation="linear") 880 881 def get_cell_from_ijk(self, ijk: list) -> int: 882 """ 883 Get the voxel id number at the given ijk coordinates. 884 885 Arguments: 886 ijk : (list) 887 the ijk coordinates of the voxel 888 """ 889 return self.dataset.ComputeCellId(ijk) 890 891 def get_point_from_ijk(self, ijk: list) -> int: 892 """ 893 Get the point id number at the given ijk coordinates. 894 895 Arguments: 896 ijk : (list) 897 the ijk coordinates of the voxel 898 """ 899 return self.dataset.ComputePointId(ijk) 900 901 def permute_axes(self, x: int, y: int, z: int) -> Self: 902 """ 903 Reorder the axes of the Volume by specifying 904 the input axes which are supposed to become the new X, Y, and Z. 905 """ 906 imp = vtki.new("ImagePermute") 907 imp.SetFilteredAxes(x, y, z) 908 imp.SetInputData(self.dataset) 909 imp.Update() 910 self._update(imp.GetOutput()) 911 self.pipeline = utils.OperationNode( 912 f"permute_axes({(x,y,z)})", parents=[self], c="#4cc9f0" 913 ) 914 return self 915 916 def resample(self, new_spacing: List[float], interpolation=1) -> Self: 917 """ 918 Resamples a `Volume` to be larger or smaller. 919 920 This method modifies the spacing of the input. 921 Linear interpolation is used to resample the data. 922 923 Arguments: 924 new_spacing : (list) 925 a list of 3 new spacings for the 3 axes 926 interpolation : (int) 927 0=nearest_neighbor, 1=linear, 2=cubic 928 """ 929 rsp = vtki.new("ImageResample") 930 oldsp = self.spacing() 931 for i in range(3): 932 if oldsp[i] != new_spacing[i]: 933 rsp.SetAxisOutputSpacing(i, new_spacing[i]) 934 rsp.InterpolateOn() 935 rsp.SetInterpolationMode(interpolation) 936 rsp.OptimizationOn() 937 rsp.Update() 938 self._update(rsp.GetOutput()) 939 self.pipeline = utils.OperationNode( 940 "resample", comment=f"spacing: {tuple(new_spacing)}", parents=[self], c="#4cc9f0" 941 ) 942 return self 943 944 945 def threshold(self, above=None, below=None, replace=None, replace_value=None) -> Self: 946 """ 947 Binary or continuous volume thresholding. 948 Find the voxels that contain a value above/below the input values 949 and replace them with a new value (default is 0). 950 """ 951 th = vtki.new("ImageThreshold") 952 th.SetInputData(self.dataset) 953 954 # sanity checks 955 if above is not None and below is not None: 956 if above == below: 957 return self 958 if above > below: 959 vedo.logger.warning("in volume.threshold(), above > below, skip.") 960 return self 961 962 ## cases 963 if below is not None and above is not None: 964 th.ThresholdBetween(above, below) 965 966 elif above is not None: 967 th.ThresholdByUpper(above) 968 969 elif below is not None: 970 th.ThresholdByLower(below) 971 972 ## 973 if replace is not None: 974 th.SetReplaceIn(True) 975 th.SetInValue(replace) 976 else: 977 th.SetReplaceIn(False) 978 979 if replace_value is not None: 980 th.SetReplaceOut(True) 981 th.SetOutValue(replace_value) 982 else: 983 th.SetReplaceOut(False) 984 985 th.Update() 986 self._update(th.GetOutput()) 987 self.pipeline = utils.OperationNode("threshold", parents=[self], c="#4cc9f0") 988 return self 989 990 def crop(self, left=None, right=None, back=None, front=None, bottom=None, top=None, VOI=()) -> Self: 991 """ 992 Crop a `Volume` object. 993 994 Arguments: 995 left : (float) 996 fraction to crop from the left plane (negative x) 997 right : (float) 998 fraction to crop from the right plane (positive x) 999 back : (float) 1000 fraction to crop from the back plane (negative y) 1001 front : (float) 1002 fraction to crop from the front plane (positive y) 1003 bottom : (float) 1004 fraction to crop from the bottom plane (negative z) 1005 top : (float) 1006 fraction to crop from the top plane (positive z) 1007 VOI : (list) 1008 extract Volume Of Interest expressed in voxel numbers 1009 1010 Example: 1011 `vol.crop(VOI=(xmin, xmax, ymin, ymax, zmin, zmax)) # all integers nrs` 1012 """ 1013 extractVOI = vtki.new("ExtractVOI") 1014 extractVOI.SetInputData(self.dataset) 1015 1016 if VOI: 1017 extractVOI.SetVOI(VOI) 1018 else: 1019 d = self.dataset.GetDimensions() 1020 bx0, bx1, by0, by1, bz0, bz1 = 0, d[0]-1, 0, d[1]-1, 0, d[2]-1 1021 if left is not None: bx0 = int((d[0]-1)*left) 1022 if right is not None: bx1 = int((d[0]-1)*(1-right)) 1023 if back is not None: by0 = int((d[1]-1)*back) 1024 if front is not None: by1 = int((d[1]-1)*(1-front)) 1025 if bottom is not None: bz0 = int((d[2]-1)*bottom) 1026 if top is not None: bz1 = int((d[2]-1)*(1-top)) 1027 extractVOI.SetVOI(bx0, bx1, by0, by1, bz0, bz1) 1028 extractVOI.Update() 1029 self._update(extractVOI.GetOutput()) 1030 1031 self.pipeline = utils.OperationNode( 1032 "crop", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1033 ) 1034 return self 1035 1036 def append(self, *volumes, axis="z", preserve_extents=False) -> Self: 1037 """ 1038 Take the components from multiple inputs and merges them into one output. 1039 Except for the append axis, all inputs must have the same extent. 1040 All inputs must have the same number of scalar components. 1041 The output has the same origin and spacing as the first input. 1042 The origin and spacing of all other inputs are ignored. 1043 All inputs must have the same scalar type. 1044 1045 Arguments: 1046 axis : (int, str) 1047 axis expanded to hold the multiple images 1048 preserve_extents : (bool) 1049 if True, the extent of the inputs is used to place 1050 the image in the output. The whole extent of the output is the union of the input 1051 whole extents. Any portion of the output not covered by the inputs is set to zero. 1052 The origin and spacing is taken from the first input. 1053 1054 Example: 1055 ```python 1056 from vedo import Volume, dataurl 1057 vol = Volume(dataurl+'embryo.tif') 1058 vol.append(vol, axis='x').show().close() 1059 ``` 1060  1061 """ 1062 ima = vtki.new("ImageAppend") 1063 ima.SetInputData(self.dataset) 1064 # if not utils.is_sequence(volumes): 1065 # volumes = [volumes] 1066 for volume in volumes: 1067 if isinstance(volume, vtki.vtkImageData): 1068 ima.AddInputData(volume) 1069 else: 1070 ima.AddInputData(volume.dataset) 1071 ima.SetPreserveExtents(preserve_extents) 1072 if axis == "x": 1073 axis = 0 1074 elif axis == "y": 1075 axis = 1 1076 elif axis == "z": 1077 axis = 2 1078 ima.SetAppendAxis(axis) 1079 ima.Update() 1080 self._update(ima.GetOutput()) 1081 1082 self.pipeline = utils.OperationNode( 1083 "append", 1084 parents=[self, *volumes], 1085 c="#4cc9f0", 1086 comment=f"dims={tuple(self.dimensions())}", 1087 ) 1088 return self 1089 1090 def pad(self, voxels=10, value=0) -> Self: 1091 """ 1092 Add the specified number of voxels at the `Volume` borders. 1093 Voxels can be a list formatted as `[nx0, nx1, ny0, ny1, nz0, nz1]`. 1094 1095 Arguments: 1096 voxels : (int, list) 1097 number of voxels to be added (or a list of length 4) 1098 value : (int) 1099 intensity value (gray-scale color) of the padding 1100 1101 Example: 1102 ```python 1103 from vedo import Volume, dataurl, show 1104 iso = Volume(dataurl+'embryo.tif').isosurface() 1105 vol = iso.binarize(spacing=(100, 100, 100)).pad(10) 1106 vol.dilate([15,15,15]) 1107 show(iso, vol.isosurface(), N=2, axes=1) 1108 ``` 1109  1110 """ 1111 x0, x1, y0, y1, z0, z1 = self.dataset.GetExtent() 1112 pf = vtki.new("ImageConstantPad") 1113 pf.SetInputData(self.dataset) 1114 pf.SetConstant(value) 1115 if utils.is_sequence(voxels): 1116 pf.SetOutputWholeExtent( 1117 x0 - voxels[0], x1 + voxels[1], 1118 y0 - voxels[2], y1 + voxels[3], 1119 z0 - voxels[4], z1 + voxels[5], 1120 ) 1121 else: 1122 pf.SetOutputWholeExtent( 1123 x0 - voxels, x1 + voxels, 1124 y0 - voxels, y1 + voxels, 1125 z0 - voxels, z1 + voxels, 1126 ) 1127 pf.Update() 1128 self._update(pf.GetOutput()) 1129 self.pipeline = utils.OperationNode( 1130 "pad", comment=f"{voxels} voxels", parents=[self], c="#f28482" 1131 ) 1132 return self 1133 1134 def resize(self, newdims: List[int]) -> Self: 1135 """Increase or reduce the number of voxels of a Volume with interpolation.""" 1136 rsz = vtki.new("ImageResize") 1137 rsz.SetResizeMethodToOutputDimensions() 1138 rsz.SetInputData(self.dataset) 1139 rsz.SetOutputDimensions(newdims) 1140 rsz.Update() 1141 self.dataset = rsz.GetOutput() 1142 self._update(self.dataset) 1143 self.pipeline = utils.OperationNode( 1144 "resize", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1145 ) 1146 return self 1147 1148 def normalize(self) -> Self: 1149 """Normalize that scalar components for each point.""" 1150 norm = vtki.new("ImageNormalize") 1151 norm.SetInputData(self.dataset) 1152 norm.Update() 1153 self._update(norm.GetOutput()) 1154 self.pipeline = utils.OperationNode("normalize", parents=[self], c="#4cc9f0") 1155 return self 1156 1157 def mirror(self, axis="x") -> Self: 1158 """ 1159 Mirror flip along one of the cartesian axes. 1160 """ 1161 img = self.dataset 1162 1163 ff = vtki.new("ImageFlip") 1164 ff.SetInputData(img) 1165 if axis.lower() == "x": 1166 ff.SetFilteredAxis(0) 1167 elif axis.lower() == "y": 1168 ff.SetFilteredAxis(1) 1169 elif axis.lower() == "z": 1170 ff.SetFilteredAxis(2) 1171 else: 1172 vedo.logger.error("mirror must be set to either x, y, z or n") 1173 raise RuntimeError() 1174 ff.Update() 1175 self._update(ff.GetOutput()) 1176 self.pipeline = utils.OperationNode(f"mirror {axis}", parents=[self], c="#4cc9f0") 1177 return self 1178 1179 def operation(self, operation: str, volume2=None) -> "Volume": 1180 """ 1181 Perform operations with `Volume` objects. 1182 Keyword `volume2` can be a constant `float`. 1183 1184 Possible operations are: 1185 ``` 1186 and, or, xor, nand, nor, not, 1187 +, -, /, 1/x, sin, cos, exp, log, 1188 abs, **2, sqrt, min, max, atan, atan2, median, 1189 mag, dot, gradient, divergence, laplacian. 1190 ``` 1191 1192 Example: 1193 ```py 1194 from vedo import Box, show 1195 vol1 = Box(size=(35,10, 5)).binarize() 1196 vol2 = Box(size=( 5,10,35)).binarize() 1197 vol = vol1.operation("xor", vol2) 1198 show([[vol1, vol2], 1199 ["vol1 xor vol2", vol]], 1200 N=2, axes=1, viewup="z", 1201 ).close() 1202 ``` 1203 1204 Note: 1205 For logic operations, the two volumes must have the same bounds. 1206 If they do not, a larger image is created to contain both and the 1207 volumes are resampled onto the larger image before the operation is 1208 performed. This can be slow and memory intensive. 1209 1210 See also: 1211 - [volume_operations.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/volume_operations.py) 1212 """ 1213 op = operation.lower() 1214 image1 = self.dataset 1215 1216 if op in ["and", "or", "xor", "nand", "nor"]: 1217 1218 if not np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()): 1219 # create a larger image to contain both 1220 b1 = image1.GetBounds() 1221 b2 = volume2.dataset.GetBounds() 1222 b = [ 1223 min(b1[0], b2[0]), 1224 max(b1[1], b2[1]), 1225 min(b1[2], b2[2]), 1226 max(b1[3], b2[3]), 1227 min(b1[4], b2[4]), 1228 max(b1[5], b2[5]), 1229 ] 1230 dims1 = image1.GetDimensions() 1231 dims2 = volume2.dataset.GetDimensions() 1232 dims = [max(dims1[0], dims2[0]), max(dims1[1], dims2[1]), max(dims1[2], dims2[2])] 1233 1234 image = vtki.vtkImageData() 1235 image.SetDimensions(dims) 1236 spacing = ( 1237 (b[1] - b[0]) / dims[0], 1238 (b[3] - b[2]) / dims[1], 1239 (b[5] - b[4]) / dims[2], 1240 ) 1241 image.SetSpacing(spacing) 1242 image.SetOrigin((b[0], b[2], b[4])) 1243 image.AllocateScalars(vtki.VTK_UNSIGNED_CHAR, 1) 1244 image.GetPointData().GetScalars().FillComponent(0, 0) 1245 1246 interp1 = vtki.new("ImageReslice") 1247 interp1.SetInputData(image1) 1248 interp1.SetOutputExtent(image.GetExtent()) 1249 interp1.SetOutputOrigin(image.GetOrigin()) 1250 interp1.SetOutputSpacing(image.GetSpacing()) 1251 interp1.SetInterpolationModeToNearestNeighbor() 1252 interp1.Update() 1253 imageA = interp1.GetOutput() 1254 1255 interp2 = vtki.new("ImageReslice") 1256 interp2.SetInputData(volume2.dataset) 1257 interp2.SetOutputExtent(image.GetExtent()) 1258 interp2.SetOutputOrigin(image.GetOrigin()) 1259 interp2.SetOutputSpacing(image.GetSpacing()) 1260 interp2.SetInterpolationModeToNearestNeighbor() 1261 interp2.Update() 1262 imageB = interp2.GetOutput() 1263 1264 else: 1265 imageA = image1 1266 imageB = volume2.dataset 1267 1268 img_logic = vtki.new("ImageLogic") 1269 img_logic.SetInput1Data(imageA) 1270 img_logic.SetInput2Data(imageB) 1271 img_logic.SetOperation(["and", "or", "xor", "nand", "nor"].index(op)) 1272 img_logic.Update() 1273 1274 out_vol = Volume(img_logic.GetOutput()) 1275 out_vol.pipeline = utils.OperationNode( 1276 "operation", comment=f"{op}", parents=[self, volume2], c="#4cc9f0", shape="cylinder" 1277 ) 1278 return out_vol ###################################################### 1279 1280 if volume2 and isinstance(volume2, Volume): 1281 # assert image1.GetScalarType() == volume2.dataset.GetScalarType(), "volumes have different scalar types" 1282 # make sure they have the same bounds: 1283 assert np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()), "volumes have different bounds" 1284 # make sure they have the same spacing: 1285 assert np.allclose(image1.GetSpacing(), volume2.dataset.GetSpacing()), "volumes have different spacing" 1286 # make sure they have the same origin: 1287 assert np.allclose(image1.GetOrigin(), volume2.dataset.GetOrigin()), "volumes have different origin" 1288 1289 mf = None 1290 if op in ["median"]: 1291 mf = vtki.new("ImageMedian3D") 1292 mf.SetInputData(image1) 1293 elif op in ["mag"]: 1294 mf = vtki.new("ImageMagnitude") 1295 mf.SetInputData(image1) 1296 elif op in ["dot"]: 1297 mf = vtki.new("ImageDotProduct") 1298 mf.SetInput1Data(image1) 1299 mf.SetInput2Data(volume2.dataset) 1300 elif op in ["grad", "gradient"]: 1301 mf = vtki.new("ImageGradient") 1302 mf.SetDimensionality(3) 1303 mf.SetInputData(image1) 1304 elif op in ["div", "divergence"]: 1305 mf = vtki.new("ImageDivergence") 1306 mf.SetInputData(image1) 1307 elif op in ["laplacian"]: 1308 mf = vtki.new("ImageLaplacian") 1309 mf.SetDimensionality(3) 1310 mf.SetInputData(image1) 1311 elif op in ["not"]: 1312 mf = vtki.new("ImageLogic") 1313 mf.SetInput1Data(image1) 1314 mf.SetOperation(4) 1315 1316 if mf is not None: 1317 mf.Update() 1318 vol = Volume(mf.GetOutput()) 1319 vol.pipeline = utils.OperationNode( 1320 "operation", comment=f"{op}", parents=[self], c="#4cc9f0", shape="cylinder" 1321 ) 1322 return vol ###################################################### 1323 1324 mat = vtki.new("ImageMathematics") 1325 mat.SetInput1Data(image1) 1326 1327 K = None 1328 1329 if utils.is_number(volume2): 1330 K = volume2 1331 mat.SetConstantK(K) 1332 mat.SetConstantC(K) 1333 1334 elif volume2 is not None: # assume image2 is a constant value 1335 mat.SetInput2Data(volume2.dataset) 1336 1337 # ########################### 1338 if op in ["+", "add", "plus"]: 1339 if K: 1340 mat.SetOperationToAddConstant() 1341 else: 1342 mat.SetOperationToAdd() 1343 1344 elif op in ["-", "subtract", "minus"]: 1345 if K: 1346 mat.SetConstantC(-float(K)) 1347 mat.SetOperationToAddConstant() 1348 else: 1349 mat.SetOperationToSubtract() 1350 1351 elif op in ["*", "multiply", "times"]: 1352 if K: 1353 mat.SetOperationToMultiplyByK() 1354 else: 1355 mat.SetOperationToMultiply() 1356 1357 elif op in ["/", "divide"]: 1358 if K: 1359 mat.SetConstantK(1.0 / K) 1360 mat.SetOperationToMultiplyByK() 1361 else: 1362 mat.SetOperationToDivide() 1363 1364 elif op in ["1/x", "invert"]: 1365 mat.SetOperationToInvert() 1366 elif op in ["sin"]: 1367 mat.SetOperationToSin() 1368 elif op in ["cos"]: 1369 mat.SetOperationToCos() 1370 elif op in ["exp"]: 1371 mat.SetOperationToExp() 1372 elif op in ["log"]: 1373 mat.SetOperationToLog() 1374 elif op in ["abs"]: 1375 mat.SetOperationToAbsoluteValue() 1376 elif op in ["**2", "square"]: 1377 mat.SetOperationToSquare() 1378 elif op in ["sqrt", "sqr"]: 1379 mat.SetOperationToSquareRoot() 1380 elif op in ["min"]: 1381 mat.SetOperationToMin() 1382 elif op in ["max"]: 1383 mat.SetOperationToMax() 1384 elif op in ["atan"]: 1385 mat.SetOperationToATAN() 1386 elif op in ["atan2"]: 1387 mat.SetOperationToATAN2() 1388 else: 1389 vedo.logger.error(f"unknown operation {operation}") 1390 raise RuntimeError() 1391 mat.Update() 1392 1393 self._update(mat.GetOutput()) 1394 1395 self.pipeline = utils.OperationNode( 1396 "operation", comment=f"{op}", parents=[self, volume2], shape="cylinder", c="#4cc9f0" 1397 ) 1398 return self 1399 1400 def frequency_pass_filter(self, low_cutoff=None, high_cutoff=None, order=1) -> Self: 1401 """ 1402 Low-pass and high-pass filtering become trivial in the frequency domain. 1403 A portion of the pixels/voxels are simply masked or attenuated. 1404 This function applies a high pass Butterworth filter that attenuates the 1405 frequency domain image. 1406 1407 The gradual attenuation of the filter is important. 1408 A simple high-pass filter would simply mask a set of pixels in the frequency domain, 1409 but the abrupt transition would cause a ringing effect in the spatial domain. 1410 1411 Arguments: 1412 low_cutoff : (list) 1413 the cutoff frequencies for x, y and z 1414 high_cutoff : (list) 1415 the cutoff frequencies for x, y and z 1416 order : (int) 1417 order determines sharpness of the cutoff curve 1418 """ 1419 # https://lorensen.github.io/VTKExamples/site/Cxx/ImageProcessing/IdealHighPass 1420 fft = vtki.new("ImageFFT") 1421 fft.SetInputData(self.dataset) 1422 fft.Update() 1423 out = fft.GetOutput() 1424 1425 if high_cutoff: 1426 blp = vtki.new("ImageButterworthLowPass") 1427 blp.SetInputData(out) 1428 blp.SetCutOff(high_cutoff) 1429 blp.SetOrder(order) 1430 blp.Update() 1431 out = blp.GetOutput() 1432 1433 if low_cutoff: 1434 bhp = vtki.new("ImageButterworthHighPass") 1435 bhp.SetInputData(out) 1436 bhp.SetCutOff(low_cutoff) 1437 bhp.SetOrder(order) 1438 bhp.Update() 1439 out = bhp.GetOutput() 1440 1441 rfft = vtki.new("ImageRFFT") 1442 rfft.SetInputData(out) 1443 rfft.Update() 1444 1445 ecomp = vtki.new("ImageExtractComponents") 1446 ecomp.SetInputData(rfft.GetOutput()) 1447 ecomp.SetComponents(0) 1448 ecomp.Update() 1449 self._update(ecomp.GetOutput()) 1450 self.pipeline = utils.OperationNode("frequency_pass_filter", parents=[self], c="#4cc9f0") 1451 return self 1452 1453 def smooth_gaussian(self, sigma=(2, 2, 2), radius=None) -> Self: 1454 """ 1455 Performs a convolution of the input Volume with a gaussian. 1456 1457 Arguments: 1458 sigma : (float, list) 1459 standard deviation(s) in voxel units. 1460 A list can be given to smooth in the three direction differently. 1461 radius : (float, list) 1462 radius factor(s) determine how far out the gaussian 1463 kernel will go before being clamped to zero. A list can be given too. 1464 """ 1465 gsf = vtki.new("ImageGaussianSmooth") 1466 gsf.SetDimensionality(3) 1467 gsf.SetInputData(self.dataset) 1468 if utils.is_sequence(sigma): 1469 gsf.SetStandardDeviations(sigma) 1470 else: 1471 gsf.SetStandardDeviation(sigma) 1472 if radius is not None: 1473 if utils.is_sequence(radius): 1474 gsf.SetRadiusFactors(radius) 1475 else: 1476 gsf.SetRadiusFactor(radius) 1477 gsf.Update() 1478 self._update(gsf.GetOutput()) 1479 self.pipeline = utils.OperationNode("smooth_gaussian", parents=[self], c="#4cc9f0") 1480 return self 1481 1482 def smooth_median(self, neighbours=(2, 2, 2)) -> Self: 1483 """ 1484 Median filter that replaces each pixel with the median value 1485 from a rectangular neighborhood around that pixel. 1486 """ 1487 imgm = vtki.new("ImageMedian3D") 1488 imgm.SetInputData(self.dataset) 1489 if utils.is_sequence(neighbours): 1490 imgm.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1491 else: 1492 imgm.SetKernelSize(neighbours, neighbours, neighbours) 1493 imgm.Update() 1494 self._update(imgm.GetOutput()) 1495 self.pipeline = utils.OperationNode("smooth_median", parents=[self], c="#4cc9f0") 1496 return self 1497 1498 def erode(self, neighbours=(2, 2, 2)) -> Self: 1499 """ 1500 Replace a voxel with the minimum over an ellipsoidal neighborhood of voxels. 1501 If `neighbours` of an axis is 1, no processing is done on that axis. 1502 1503 Examples: 1504 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1505 1506  1507 """ 1508 ver = vtki.new("ImageContinuousErode3D") 1509 ver.SetInputData(self.dataset) 1510 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1511 ver.Update() 1512 self._update(ver.GetOutput()) 1513 self.pipeline = utils.OperationNode("erode", parents=[self], c="#4cc9f0") 1514 return self 1515 1516 def dilate(self, neighbours=(2, 2, 2)) -> Self: 1517 """ 1518 Replace a voxel with the maximum over an ellipsoidal neighborhood of voxels. 1519 If `neighbours` of an axis is 1, no processing is done on that axis. 1520 1521 Check also `erode()` and `pad()`. 1522 1523 Examples: 1524 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1525 """ 1526 ver = vtki.new("ImageContinuousDilate3D") 1527 ver.SetInputData(self.dataset) 1528 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1529 ver.Update() 1530 self._update(ver.GetOutput()) 1531 self.pipeline = utils.OperationNode("dilate", parents=[self], c="#4cc9f0") 1532 return self 1533 1534 def magnitude(self) -> Self: 1535 """Colapses components with magnitude function.""" 1536 imgm = vtki.new("ImageMagnitude") 1537 imgm.SetInputData(self.dataset) 1538 imgm.Update() 1539 self._update(imgm.GetOutput()) 1540 self.pipeline = utils.OperationNode("magnitude", parents=[self], c="#4cc9f0") 1541 return self 1542 1543 def topoints(self) -> "vedo.Points": 1544 """ 1545 Extract all image voxels as points. 1546 This function takes an input `Volume` and creates an `Mesh` 1547 that contains the points and the point attributes. 1548 1549 Examples: 1550 - [vol2points.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/vol2points.py) 1551 """ 1552 v2p = vtki.new("ImageToPoints") 1553 v2p.SetInputData(self.dataset) 1554 v2p.Update() 1555 mpts = vedo.Points(v2p.GetOutput()) 1556 mpts.pipeline = utils.OperationNode("topoints", parents=[self], c="#4cc9f0:#e9c46a") 1557 return mpts 1558 1559 def euclidean_distance(self, anisotropy=False, max_distance=None) -> "Volume": 1560 """ 1561 Implementation of the Euclidean DT (Distance Transform) using Saito's algorithm. 1562 The distance map produced contains the square of the Euclidean distance values. 1563 The algorithm has a O(n^(D+1)) complexity over n x n x...x n images in D dimensions. 1564 1565 Check out also: https://en.wikipedia.org/wiki/Distance_transform 1566 1567 Arguments: 1568 anisotropy : bool 1569 used to define whether Spacing should be used in the 1570 computation of the distances. 1571 max_distance : bool 1572 any distance bigger than max_distance will not be 1573 computed but set to this specified value instead. 1574 1575 Examples: 1576 - [euclidian_dist.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/euclidian_dist.py) 1577 """ 1578 euv = vtki.new("ImageEuclideanDistance") 1579 euv.SetInputData(self.dataset) 1580 euv.SetConsiderAnisotropy(anisotropy) 1581 if max_distance is not None: 1582 euv.InitializeOn() 1583 euv.SetMaximumDistance(max_distance) 1584 euv.SetAlgorithmToSaito() 1585 euv.Update() 1586 vol = Volume(euv.GetOutput()) 1587 vol.pipeline = utils.OperationNode("euclidean_distance", parents=[self], c="#4cc9f0") 1588 return vol 1589 1590 def correlation_with(self, vol2: "Volume", dim=2) -> "Volume": 1591 """ 1592 Find the correlation between two volumetric data sets. 1593 Keyword `dim` determines whether the correlation will be 3D, 2D or 1D. 1594 The default is a 2D Correlation. 1595 1596 The output size will match the size of the first input. 1597 The second input is considered the correlation kernel. 1598 """ 1599 imc = vtki.new("ImageCorrelation") 1600 imc.SetInput1Data(self.dataset) 1601 imc.SetInput2Data(vol2.dataset) 1602 imc.SetDimensionality(dim) 1603 imc.Update() 1604 vol = Volume(imc.GetOutput()) 1605 1606 vol.pipeline = utils.OperationNode("correlation_with", parents=[self, vol2], c="#4cc9f0") 1607 return vol 1608 1609 def scale_voxels(self, scale=1) -> Self: 1610 """Scale the voxel content by factor `scale`.""" 1611 rsl = vtki.new("ImageReslice") 1612 rsl.SetInputData(self.dataset) 1613 rsl.SetScalarScale(scale) 1614 rsl.Update() 1615 self._update(rsl.GetOutput()) 1616 self.pipeline = utils.OperationNode( 1617 "scale_voxels", comment=f"scale={scale}", parents=[self], c="#4cc9f0" 1618 ) 1619 return self
Class to describe dataset that are defined on "voxels", the 3D equivalent of 2D pixels.
Volume(inputobj=None, dims=None, origin=None, spacing=None)
37 def __init__( 38 self, 39 inputobj=None, 40 dims=None, 41 origin=None, 42 spacing=None, 43 ) -> None: 44 """ 45 This class can be initialized with a numpy object, 46 a `vtkImageData` or a list of 2D bmp files. 47 48 Arguments: 49 origin : (list) 50 set volume origin coordinates 51 spacing : (list) 52 voxel dimensions in x, y and z. 53 dims : (list) 54 specify the dimensions of the volume. 55 56 Example: 57 ```python 58 from vedo import Volume 59 vol = Volume("path/to/mydata/rec*.bmp") 60 vol.show() 61 ``` 62 63 Examples: 64 - [numpy2volume1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume1.py) 65 66  67 68 - [read_volume2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/read_volume2.py) 69 70  71 72 .. note:: 73 if a `list` of values is used for `alphas` this is interpreted 74 as a transfer function along the range of the scalar. 75 """ 76 super().__init__() 77 78 self.name = "Volume" 79 self.filename = "" 80 self.file_size = "" 81 82 self.info = {} 83 self.time = time.time() 84 85 self.actor = vtki.vtkVolume() 86 self.actor.retrieve_object = weak_ref_to(self) 87 self.properties = self.actor.GetProperty() 88 89 self.transform = None 90 self.point_locator = None 91 self.cell_locator = None 92 self.line_locator = None 93 94 ################### 95 if isinstance(inputobj, str): 96 if "https://" in inputobj: 97 inputobj = vedo.file_io.download(inputobj, verbose=False) # fpath 98 elif os.path.isfile(inputobj): 99 self.filename = inputobj 100 else: 101 inputobj = sorted(glob.glob(inputobj)) 102 103 ################### 104 inputtype = str(type(inputobj)) 105 106 # print('Volume inputtype', inputtype, c='b') 107 108 if inputobj is None: 109 img = vtki.vtkImageData() 110 111 elif utils.is_sequence(inputobj): 112 113 if isinstance(inputobj[0], str) and ".bmp" in inputobj[0].lower(): 114 # scan sequence of BMP files 115 ima = vtki.new("ImageAppend") 116 ima.SetAppendAxis(2) 117 pb = utils.ProgressBar(0, len(inputobj)) 118 for i in pb.range(): 119 f = inputobj[i] 120 if "_rec_spr" in f: # OPT specific 121 continue 122 picr = vtki.new("BMPReader") 123 picr.SetFileName(f) 124 picr.Update() 125 mgf = vtki.new("ImageMagnitude") 126 mgf.SetInputData(picr.GetOutput()) 127 mgf.Update() 128 ima.AddInputData(mgf.GetOutput()) 129 pb.print("loading...") 130 ima.Update() 131 img = ima.GetOutput() 132 133 else: 134 135 if len(inputobj.shape) == 1: 136 varr = utils.numpy2vtk(inputobj) 137 else: 138 varr = utils.numpy2vtk(inputobj.ravel(order="F")) 139 varr.SetName("input_scalars") 140 141 img = vtki.vtkImageData() 142 if dims is not None: 143 img.SetDimensions(dims[2], dims[1], dims[0]) 144 else: 145 if len(inputobj.shape) == 1: 146 vedo.logger.error("must set dimensions (dims keyword) in Volume") 147 raise RuntimeError() 148 img.SetDimensions(inputobj.shape) 149 img.GetPointData().AddArray(varr) 150 img.GetPointData().SetActiveScalars(varr.GetName()) 151 152 elif isinstance(inputobj, vtki.vtkImageData): 153 img = inputobj 154 155 elif isinstance(inputobj, str): 156 if "https://" in inputobj: 157 inputobj = vedo.file_io.download(inputobj, verbose=False) 158 img = vedo.file_io.loadImageData(inputobj) 159 self.filename = inputobj 160 161 else: 162 vedo.logger.error(f"cannot understand input type {inputtype}") 163 return 164 165 if dims is not None: 166 img.SetDimensions(dims) 167 168 if origin is not None: 169 img.SetOrigin(origin) 170 171 if spacing is not None: 172 img.SetSpacing(spacing) 173 174 self.dataset = img 175 self.transform = None 176 177 ##################################### 178 mapper = vtki.new("SmartVolumeMapper") 179 mapper.SetInputData(img) 180 self.actor.SetMapper(mapper) 181 182 if img.GetPointData().GetScalars(): 183 if img.GetPointData().GetScalars().GetNumberOfComponents() == 1: 184 self.properties.SetShade(True) 185 self.properties.SetInterpolationType(1) 186 self.cmap("RdBu_r") 187 self.alpha([0.0, 0.0, 0.2, 0.4, 0.8, 1.0]) 188 self.alpha_gradient(None) 189 self.properties.SetScalarOpacityUnitDistance(1.0) 190 191 self.pipeline = utils.OperationNode( 192 "Volume", comment=f"dims={tuple(self.dimensions())}", c="#4cc9f0" 193 ) 194 #######################################################################
This class can be initialized with a numpy object,
a vtkImageData or a list of 2D bmp files.
Arguments:
- origin : (list) set volume origin coordinates
- spacing : (list) voxel dimensions in x, y and z.
- dims : (list) specify the dimensions of the volume.
Example:
from vedo import Volume vol = Volume("path/to/mydata/rec*.bmp") vol.show()
Examples:
if a list of values is used for alphas this is interpreted
as a transfer function along the range of the scalar.
mapper
196 @property 197 def mapper(self): 198 """Return the underlying `vtkMapper` object.""" 199 return self.actor.GetMapper()
Return the underlying vtkMapper object.
def
c(self, *args, **kwargs) -> Self:
229 def c(self, *args, **kwargs) -> Self: 230 """Deprecated. Use `Volume.cmap()` instead.""" 231 vedo.logger.warning("Volume.c() is deprecated, use Volume.cmap() instead") 232 return self.cmap(*args, **kwargs)
Deprecated. Use Volume.cmap() instead.
371 def copy(self, deep=True) -> "Volume": 372 """Return a copy of the Volume. Alias of `clone()`.""" 373 return self.clone(deep=deep)
Return a copy of the Volume. Alias of clone().
375 def clone(self, deep=True) -> "Volume": 376 """Return a clone copy of the Volume. Alias of `copy()`.""" 377 if deep: 378 newimg = vtki.vtkImageData() 379 newimg.CopyStructure(self.dataset) 380 newimg.CopyAttributes(self.dataset) 381 newvol = Volume(newimg) 382 else: 383 newvol = Volume(self.dataset) 384 385 prop = vtki.vtkVolumeProperty() 386 prop.DeepCopy(self.properties) 387 newvol.actor.SetProperty(prop) 388 newvol.properties = prop 389 390 newvol.pipeline = utils.OperationNode("clone", parents=[self], c="#bbd0ff", shape="diamond") 391 return newvol
Return a clone copy of the Volume. Alias of copy().
def
astype(self, dtype: Union[str, int]) -> Self:
393 def astype(self, dtype: Union[str, int]) -> Self: 394 """ 395 Reset the type of the scalars array. 396 397 Arguments: 398 dtype : (str) 399 the type of the scalars array in 400 ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"] 401 """ 402 if dtype in ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"]: 403 caster = vtki.new("ImageCast") 404 caster.SetInputData(self.dataset) 405 caster.SetOutputScalarType(int(vtki.array_types[dtype])) 406 caster.ClampOverflowOn() 407 caster.Update() 408 self._update(caster.GetOutput()) 409 self.pipeline = utils.OperationNode(f"astype({dtype})", parents=[self], c="#4cc9f0") 410 else: 411 vedo.logger.error(f"astype(): unknown type {dtype}") 412 raise ValueError() 413 return self
Reset the type of the scalars array.
Arguments:
- dtype : (str) the type of the scalars array in ["int8", "uint8", "int16", "uint16", "int32", "uint32", "float32", "float64"]
def
component_weight(self, i: int, weight: float) -> Self:
415 def component_weight(self, i: int, weight: float) -> Self: 416 """Set the scalar component weight in range [0,1].""" 417 self.properties.SetComponentWeight(i, weight) 418 return self
Set the scalar component weight in range [0,1].
420 def xslice(self, i: int) -> Mesh: 421 """Extract the slice at index `i` of volume along x-axis.""" 422 vslice = vtki.new("ImageDataGeometryFilter") 423 vslice.SetInputData(self.dataset) 424 nx, ny, nz = self.dataset.GetDimensions() 425 if i > nx - 1: 426 i = nx - 1 427 vslice.SetExtent(i, i, 0, ny, 0, nz) 428 vslice.Update() 429 m = Mesh(vslice.GetOutput()) 430 m.pipeline = utils.OperationNode(f"xslice {i}", parents=[self], c="#4cc9f0:#e9c46a") 431 return m
Extract the slice at index i of volume along x-axis.
433 def yslice(self, j: int) -> Mesh: 434 """Extract the slice at index `j` of volume along y-axis.""" 435 vslice = vtki.new("ImageDataGeometryFilter") 436 vslice.SetInputData(self.dataset) 437 nx, ny, nz = self.dataset.GetDimensions() 438 if j > ny - 1: 439 j = ny - 1 440 vslice.SetExtent(0, nx, j, j, 0, nz) 441 vslice.Update() 442 m = Mesh(vslice.GetOutput()) 443 m.pipeline = utils.OperationNode(f"yslice {j}", parents=[self], c="#4cc9f0:#e9c46a") 444 return m
Extract the slice at index j of volume along y-axis.
446 def zslice(self, k: int) -> Mesh: 447 """Extract the slice at index `i` of volume along z-axis.""" 448 vslice = vtki.new("ImageDataGeometryFilter") 449 vslice.SetInputData(self.dataset) 450 nx, ny, nz = self.dataset.GetDimensions() 451 if k > nz - 1: 452 k = nz - 1 453 vslice.SetExtent(0, nx, 0, ny, k, k) 454 vslice.Update() 455 m = Mesh(vslice.GetOutput()) 456 m.pipeline = utils.OperationNode(f"zslice {k}", parents=[self], c="#4cc9f0:#e9c46a") 457 return m
Extract the slice at index i of volume along z-axis.
def
slice_plane( self, origin: List[float], normal: List[float], autocrop=False, border=0.5, mode='linear') -> vedo.mesh.Mesh:
459 def slice_plane(self, origin: List[float], normal: List[float], autocrop=False, border=0.5, mode="linear") -> Mesh: 460 """ 461 Extract the slice along a given plane position and normal. 462 463 Two metadata arrays are added to the output Mesh: 464 - "shape" : contains the shape of the slice 465 - "original_bounds" : contains the original bounds of the slice 466 One can access them with e.g. `myslice.metadata["shape"]`. 467 468 Arguments: 469 origin : (list) 470 position of the plane 471 normal : (list) 472 normal to the plane 473 autocrop : (bool) 474 crop the output to the minimal possible size 475 border : (float) 476 add a border to the output slice 477 mode : (str) 478 interpolation mode, one of the following: "linear", "nearest", "cubic" 479 480 Example: 481 - [slice_plane1.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane1.py) 482 483  484 485 - [slice_plane2.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane2.py) 486 487  488 489 - [slice_plane3.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/slice_plane3.py) 490 491  492 """ 493 newaxis = utils.versor(normal) 494 pos = np.array(origin) 495 initaxis = (0, 0, 1) 496 crossvec = np.cross(initaxis, newaxis) 497 angle = np.arccos(np.dot(initaxis, newaxis)) 498 T = vtki.vtkTransform() 499 T.PostMultiply() 500 T.RotateWXYZ(np.rad2deg(angle), crossvec.tolist()) 501 T.Translate(pos.tolist()) 502 503 reslice = vtki.new("ImageReslice") 504 reslice.SetResliceAxes(T.GetMatrix()) 505 reslice.SetInputData(self.dataset) 506 reslice.SetOutputDimensionality(2) 507 reslice.SetTransformInputSampling(True) 508 reslice.SetGenerateStencilOutput(False) 509 if border: 510 reslice.SetBorder(True) 511 reslice.SetBorderThickness(border) 512 else: 513 reslice.SetBorder(False) 514 if mode == "linear": 515 reslice.SetInterpolationModeToLinear() 516 elif mode == "nearest": 517 reslice.SetInterpolationModeToNearestNeighbor() 518 elif mode == "cubic": 519 reslice.SetInterpolationModeToCubic() 520 else: 521 vedo.logger.error(f"in slice_plane(): unknown interpolation mode {mode}") 522 raise ValueError() 523 reslice.SetAutoCropOutput(not autocrop) 524 reslice.Update() 525 img = reslice.GetOutput() 526 527 vslice = vtki.new("ImageDataGeometryFilter") 528 vslice.SetInputData(img) 529 vslice.Update() 530 531 msh = Mesh(vslice.GetOutput()).apply_transform(T) 532 msh.properties.LightingOff() 533 534 d0, d1, _ = img.GetDimensions() 535 varr1 = utils.numpy2vtk([d1, d0], name="shape") 536 varr2 = utils.numpy2vtk(img.GetBounds(), name="original_bounds") 537 msh.dataset.GetFieldData().AddArray(varr1) 538 msh.dataset.GetFieldData().AddArray(varr2) 539 msh.pipeline = utils.OperationNode("slice_plane", parents=[self], c="#4cc9f0:#e9c46a") 540 return msh
Extract the slice along a given plane position and normal.
Two metadata arrays are added to the output Mesh:
- "shape" : contains the shape of the slice
- "original_bounds" : contains the original bounds of the slice
One can access them with e.g. myslice.metadata["shape"].
Arguments:
- origin : (list) position of the plane
- normal : (list) normal to the plane
- autocrop : (bool) crop the output to the minimal possible size
- border : (float) add a border to the output slice
- mode : (str) interpolation mode, one of the following: "linear", "nearest", "cubic"
Example:
542 def slab(self, slice_range=(), axis='z', operation="mean") -> Mesh: 543 """ 544 Extract a slab from a `Volume` by combining 545 all of the slices of an image to create a single slice. 546 547 Returns a `Mesh` containing metadata which 548 can be accessed with e.g. `mesh.metadata["slab_range"]`. 549 550 Metadata: 551 slab_range : (list) 552 contains the range of slices extracted 553 slab_axis : (str) 554 contains the axis along which the slab was extracted 555 slab_operation : (str) 556 contains the operation performed on the slab 557 slab_bounding_box : (list) 558 contains the bounding box of the slab 559 560 Arguments: 561 slice_range : (list) 562 range of slices to extract 563 axis : (str) 564 axis along which to extract the slab 565 operation : (str) 566 operation to perform on the slab, 567 allowed values are: "sum", "min", "max", "mean". 568 569 Example: 570 - [slab.py](https://github.com/marcomusy/vedo/blob/master/examples/volumetric/slab_vol.py) 571 572  573 """ 574 if len(slice_range) != 2: 575 vedo.logger.error("in slab(): slice_range is empty or invalid") 576 raise ValueError() 577 578 islab = vtki.new("ImageSlab") 579 islab.SetInputData(self.dataset) 580 581 if operation in ["+", "add", "sum"]: 582 islab.SetOperationToSum() 583 elif "min" in operation: 584 islab.SetOperationToMin() 585 elif "max" in operation: 586 islab.SetOperationToMax() 587 elif "mean" in operation: 588 islab.SetOperationToMean() 589 else: 590 vedo.logger.error(f"in slab(): unknown operation {operation}") 591 raise ValueError() 592 593 dims = self.dimensions() 594 if axis == 'x': 595 islab.SetOrientationToX() 596 if slice_range[0] > dims[0]-1: 597 slice_range[0] = dims[0]-1 598 if slice_range[1] > dims[0]-1: 599 slice_range[1] = dims[0]-1 600 elif axis == 'y': 601 islab.SetOrientationToY() 602 if slice_range[0] > dims[1]-1: 603 slice_range[0] = dims[1]-1 604 if slice_range[1] > dims[1]-1: 605 slice_range[1] = dims[1]-1 606 elif axis == 'z': 607 islab.SetOrientationToZ() 608 if slice_range[0] > dims[2]-1: 609 slice_range[0] = dims[2]-1 610 if slice_range[1] > dims[2]-1: 611 slice_range[1] = dims[2]-1 612 else: 613 vedo.logger.error(f"Error in slab(): unknown axis {axis}") 614 raise RuntimeError() 615 616 islab.SetSliceRange(slice_range) 617 islab.Update() 618 619 msh = Mesh(islab.GetOutput()).lighting('off') 620 msh.mapper.SetLookupTable(utils.ctf2lut(self, msh)) 621 msh.mapper.SetScalarRange(self.scalar_range()) 622 623 msh.metadata["slab_range"] = slice_range 624 msh.metadata["slab_axis"] = axis 625 msh.metadata["slab_operation"] = operation 626 627 # compute bounds of slab 628 origin = list(self.origin()) 629 spacing = list(self.spacing()) 630 if axis == 'x': 631 msh.metadata["slab_bounding_box"] = [ 632 origin[0] + slice_range[0]*spacing[0], 633 origin[0] + slice_range[1]*spacing[0], 634 origin[1], 635 origin[1] + dims[1]*spacing[1], 636 origin[2], 637 origin[2] + dims[2]*spacing[2], 638 ] 639 elif axis == 'y': 640 msh.metadata["slab_bounding_box"] = [ 641 origin[0], 642 origin[0] + dims[0]*spacing[0], 643 origin[1] + slice_range[0]*spacing[1], 644 origin[1] + slice_range[1]*spacing[1], 645 origin[2], 646 origin[2] + dims[2]*spacing[2], 647 ] 648 elif axis == 'z': 649 msh.metadata["slab_bounding_box"] = [ 650 origin[0], 651 origin[0] + dims[0]*spacing[0], 652 origin[1], 653 origin[1] + dims[1]*spacing[1], 654 origin[2] + slice_range[0]*spacing[2], 655 origin[2] + slice_range[1]*spacing[2], 656 ] 657 658 msh.pipeline = utils.OperationNode( 659 f"slab{slice_range}", 660 comment=f"axis={axis}, operation={operation}", 661 parents=[self], 662 c="#4cc9f0:#e9c46a", 663 ) 664 msh.name = "SlabMesh" 665 return msh
Extract a slab from a Volume by combining
all of the slices of an image to create a single slice.
Returns a Mesh containing metadata which
can be accessed with e.g. mesh.metadata["slab_range"].
Metadata:
slab_range : (list) contains the range of slices extracted slab_axis : (str) contains the axis along which the slab was extracted slab_operation : (str) contains the operation performed on the slab slab_bounding_box : (list) contains the bounding box of the slab
Arguments:
- slice_range : (list) range of slices to extract
- axis : (str) axis along which to extract the slab
- operation : (str) operation to perform on the slab, allowed values are: "sum", "min", "max", "mean".
Example:
def
warp( self, source: Union[vedo.pointcloud.Points, List], target: Union[vedo.pointcloud.Points, List], sigma=1, mode='3d', fit=True) -> Self:
668 def warp( 669 self, 670 source: Union["vedo.Points", List], 671 target: Union["vedo.Points", List], 672 sigma=1, mode="3d", fit=True, 673 ) -> Self: 674 """ 675 Warp volume scalars within a Volume by specifying 676 source and target sets of points. 677 678 Arguments: 679 source : (Points, list) 680 the list of source points 681 target : (Points, list) 682 the list of target points 683 fit : (bool) 684 fit/adapt the old bounding box to the warped geometry 685 """ 686 if isinstance(source, vedo.Points): 687 source = source.vertices 688 if isinstance(target, vedo.Points): 689 target = target.vertices 690 691 NLT = transformations.NonLinearTransform() 692 NLT.source_points = source 693 NLT.target_points = target 694 NLT.sigma = sigma 695 NLT.mode = mode 696 697 self.apply_transform(NLT, fit=fit) 698 self.pipeline = utils.OperationNode("warp", parents=[self], c="#4cc9f0") 699 return self
Warp volume scalars within a Volume by specifying source and target sets of points.
Arguments:
- source : (Points, list) the list of source points
- target : (Points, list) the list of target points
- fit : (bool) fit/adapt the old bounding box to the warped geometry
def
apply_transform( self, T: Union[vedo.transformations.LinearTransform, vedo.transformations.NonLinearTransform], fit=True, interpolation='cubic') -> Self:
701 def apply_transform( 702 self, 703 T: Union[transformations.LinearTransform, transformations.NonLinearTransform], 704 fit=True, interpolation="cubic", 705 ) -> Self: 706 """ 707 Apply a transform to the scalars in the volume. 708 709 Arguments: 710 T : (LinearTransform, NonLinearTransform) 711 The transformation to be applied 712 fit : (bool) 713 fit/adapt the old bounding box to the modified geometry 714 interpolation : (str) 715 one of the following: "nearest", "linear", "cubic" 716 """ 717 if utils.is_sequence(T): 718 T = transformations.LinearTransform(T) 719 720 TI = T.compute_inverse() 721 722 reslice = vtki.new("ImageReslice") 723 reslice.SetInputData(self.dataset) 724 reslice.SetResliceTransform(TI.T) 725 reslice.SetOutputDimensionality(3) 726 if "lin" in interpolation.lower(): 727 reslice.SetInterpolationModeToLinear() 728 elif "near" in interpolation.lower(): 729 reslice.SetInterpolationModeToNearestNeighbor() 730 elif "cubic" in interpolation.lower(): 731 reslice.SetInterpolationModeToCubic() 732 else: 733 vedo.logger.error( 734 f"in apply_transform: unknown interpolation mode {interpolation}") 735 raise ValueError() 736 reslice.SetAutoCropOutput(fit) 737 reslice.Update() 738 self._update(reslice.GetOutput()) 739 self.transform = T 740 self.pipeline = utils.OperationNode( 741 "apply_transform", parents=[self], c="#4cc9f0") 742 return self
Apply a transform to the scalars in the volume.
Arguments:
- T : (LinearTransform, NonLinearTransform) The transformation to be applied
- fit : (bool) fit/adapt the old bounding box to the modified geometry
- interpolation : (str) one of the following: "nearest", "linear", "cubic"
def
imagedata(self) -> vtkmodules.vtkCommonDataModel.vtkImageData:
744 def imagedata(self) -> vtki.vtkImageData: 745 """ 746 DEPRECATED: 747 Use `Volume.dataset` instead. 748 749 Return the underlying `vtkImagaData` object. 750 """ 751 print("Volume.imagedata() is deprecated, use Volume.dataset instead") 752 return self.dataset
DEPRECATED:
Use Volume.dataset instead.
Return the underlying vtkImagaData object.
def
modified(self) -> Self:
754 def modified(self) -> Self: 755 """ 756 Mark the object as modified. 757 758 Example: 759 760 - [numpy2volume0.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/numpy2volume0.py) 761 """ 762 scals = self.dataset.GetPointData().GetScalars() 763 if scals: 764 scals.Modified() 765 return self
def
tonumpy(self) -> numpy.ndarray:
767 def tonumpy(self) -> np.ndarray: 768 """ 769 Get read-write access to voxels of a Volume object as a numpy array. 770 771 When you set values in the output image, you don't want numpy to reallocate the array 772 but instead set values in the existing array, so use the [:] operator. 773 774 Example: 775 `arr[:] = arr*2 + 15` 776 777 If the array is modified add a call to: 778 `volume.modified()` 779 when all your modifications are completed. 780 """ 781 narray_shape = tuple(reversed(self.dataset.GetDimensions())) 782 783 scals = self.dataset.GetPointData().GetScalars() 784 comps = scals.GetNumberOfComponents() 785 if comps == 1: 786 narray = utils.vtk2numpy(scals).reshape(narray_shape) 787 narray = np.transpose(narray, axes=[2, 1, 0]) 788 else: 789 narray = utils.vtk2numpy(scals).reshape(*narray_shape, comps) 790 narray = np.transpose(narray, axes=[2, 1, 0, 3]) 791 792 # narray = utils.vtk2numpy(self.dataset.GetPointData().GetScalars()).reshape(narray_shape) 793 # narray = np.transpose(narray, axes=[2, 1, 0]) 794 return narray
Get read-write access to voxels of a Volume object as a numpy array.
When you set values in the output image, you don't want numpy to reallocate the array but instead set values in the existing array, so use the [:] operator.
Example:
arr[:] = arr*2 + 15
If the array is modified add a call to:
volume.modified()
when all your modifications are completed.
shape: numpy.ndarray
796 @property 797 def shape(self) -> np.ndarray: 798 """Return the nr. of voxels in the 3 dimensions.""" 799 return np.array(self.dataset.GetDimensions())
Return the nr. of voxels in the 3 dimensions.
def
dimensions(self) -> numpy.ndarray:
801 def dimensions(self) -> np.ndarray: 802 """Return the nr. of voxels in the 3 dimensions.""" 803 return np.array(self.dataset.GetDimensions())
Return the nr. of voxels in the 3 dimensions.
def
scalar_range(self) -> numpy.ndarray:
805 def scalar_range(self) -> np.ndarray: 806 """Return the range of the scalar values.""" 807 return np.array(self.dataset.GetScalarRange())
Return the range of the scalar values.
def
spacing(self, s=None) -> Union[Self, Iterable[float]]:
809 def spacing(self, s=None) -> Union[Self, Iterable[float]]: 810 """Set/get the voxels size in the 3 dimensions.""" 811 if s is not None: 812 self.dataset.SetSpacing(s) 813 return self 814 return np.array(self.dataset.GetSpacing())
Set/get the voxels size in the 3 dimensions.
def
origin(self, s=None) -> Union[Self, Iterable[float]]:
816 def origin(self, s=None) -> Union[Self, Iterable[float]]: 817 """ 818 Set/get the origin of the volumetric dataset. 819 820 The origin is the position in world coordinates of the point index (0,0,0). 821 This point does not have to be part of the dataset, in other words, 822 the dataset extent does not have to start at (0,0,0) and the origin 823 can be outside of the dataset bounding box. 824 The origin plus spacing determine the position in space of the points. 825 """ 826 if s is not None: 827 self.dataset.SetOrigin(s) 828 return self 829 return np.array(self.dataset.GetOrigin())
Set/get the origin of the volumetric dataset.
The origin is the position in world coordinates of the point index (0,0,0). This point does not have to be part of the dataset, in other words, the dataset extent does not have to start at (0,0,0) and the origin can be outside of the dataset bounding box. The origin plus spacing determine the position in space of the points.
def
pos(self, p=None) -> Union[Self, Iterable[float]]:
831 def pos(self, p=None) -> Union[Self, Iterable[float]]: 832 """Set/get the position of the volumetric dataset.""" 833 if p is not None: 834 self.origin(p) 835 return self 836 return self.origin()
Set/get the position of the volumetric dataset.
def
center(self) -> numpy.ndarray:
838 def center(self) -> np.ndarray: 839 """Get the center of the volumetric dataset.""" 840 # note that this does not have the set method like origin and spacing 841 return np.array(self.dataset.GetCenter())
Get the center of the volumetric dataset.
def
shift(self, s: list) -> Self:
843 def shift(self, s: list) -> Self: 844 """Shift the volumetric dataset by a vector.""" 845 self.origin(self.origin() + np.array(s)) 846 return self
Shift the volumetric dataset by a vector.
def
rotate_x(self, angle: float, rad=False, around=None) -> Self:
848 def rotate_x(self, angle: float, rad=False, around=None) -> Self: 849 """ 850 Rotate around x-axis. If angle is in radians set `rad=True`. 851 852 Use `around` to define a pivoting point. 853 """ 854 if angle == 0: 855 return self 856 LT = transformations.LinearTransform().rotate_x(angle, rad, around) 857 return self.apply_transform(LT, fit=True, interpolation="linear")
Rotate around x-axis. If angle is in radians set rad=True.
Use around to define a pivoting point.
def
rotate_y(self, angle: float, rad=False, around=None) -> Self:
859 def rotate_y(self, angle: float, rad=False, around=None) -> Self: 860 """ 861 Rotate around y-axis. If angle is in radians set `rad=True`. 862 863 Use `around` to define a pivoting point. 864 """ 865 if angle == 0: 866 return self 867 LT = transformations.LinearTransform().rotate_y(angle, rad, around) 868 return self.apply_transform(LT, fit=True, interpolation="linear")
Rotate around y-axis. If angle is in radians set rad=True.
Use around to define a pivoting point.
def
rotate_z(self, angle: float, rad=False, around=None) -> Self:
870 def rotate_z(self, angle: float, rad=False, around=None) -> Self: 871 """ 872 Rotate around z-axis. If angle is in radians set `rad=True`. 873 874 Use `around` to define a pivoting point. 875 """ 876 if angle == 0: 877 return self 878 LT = transformations.LinearTransform().rotate_z(angle, rad, around) 879 return self.apply_transform(LT, fit=True, interpolation="linear")
Rotate around z-axis. If angle is in radians set rad=True.
Use around to define a pivoting point.
def
get_cell_from_ijk(self, ijk: list) -> int:
881 def get_cell_from_ijk(self, ijk: list) -> int: 882 """ 883 Get the voxel id number at the given ijk coordinates. 884 885 Arguments: 886 ijk : (list) 887 the ijk coordinates of the voxel 888 """ 889 return self.dataset.ComputeCellId(ijk)
Get the voxel id number at the given ijk coordinates.
Arguments:
- ijk : (list) the ijk coordinates of the voxel
def
get_point_from_ijk(self, ijk: list) -> int:
891 def get_point_from_ijk(self, ijk: list) -> int: 892 """ 893 Get the point id number at the given ijk coordinates. 894 895 Arguments: 896 ijk : (list) 897 the ijk coordinates of the voxel 898 """ 899 return self.dataset.ComputePointId(ijk)
Get the point id number at the given ijk coordinates.
Arguments:
- ijk : (list) the ijk coordinates of the voxel
def
permute_axes(self, x: int, y: int, z: int) -> Self:
901 def permute_axes(self, x: int, y: int, z: int) -> Self: 902 """ 903 Reorder the axes of the Volume by specifying 904 the input axes which are supposed to become the new X, Y, and Z. 905 """ 906 imp = vtki.new("ImagePermute") 907 imp.SetFilteredAxes(x, y, z) 908 imp.SetInputData(self.dataset) 909 imp.Update() 910 self._update(imp.GetOutput()) 911 self.pipeline = utils.OperationNode( 912 f"permute_axes({(x,y,z)})", parents=[self], c="#4cc9f0" 913 ) 914 return self
Reorder the axes of the Volume by specifying the input axes which are supposed to become the new X, Y, and Z.
def
resample(self, new_spacing: List[float], interpolation=1) -> Self:
916 def resample(self, new_spacing: List[float], interpolation=1) -> Self: 917 """ 918 Resamples a `Volume` to be larger or smaller. 919 920 This method modifies the spacing of the input. 921 Linear interpolation is used to resample the data. 922 923 Arguments: 924 new_spacing : (list) 925 a list of 3 new spacings for the 3 axes 926 interpolation : (int) 927 0=nearest_neighbor, 1=linear, 2=cubic 928 """ 929 rsp = vtki.new("ImageResample") 930 oldsp = self.spacing() 931 for i in range(3): 932 if oldsp[i] != new_spacing[i]: 933 rsp.SetAxisOutputSpacing(i, new_spacing[i]) 934 rsp.InterpolateOn() 935 rsp.SetInterpolationMode(interpolation) 936 rsp.OptimizationOn() 937 rsp.Update() 938 self._update(rsp.GetOutput()) 939 self.pipeline = utils.OperationNode( 940 "resample", comment=f"spacing: {tuple(new_spacing)}", parents=[self], c="#4cc9f0" 941 ) 942 return self
Resamples a Volume to be larger or smaller.
This method modifies the spacing of the input. Linear interpolation is used to resample the data.
Arguments:
- new_spacing : (list) a list of 3 new spacings for the 3 axes
- interpolation : (int) 0=nearest_neighbor, 1=linear, 2=cubic
def
threshold(self, above=None, below=None, replace=None, replace_value=None) -> Self:
945 def threshold(self, above=None, below=None, replace=None, replace_value=None) -> Self: 946 """ 947 Binary or continuous volume thresholding. 948 Find the voxels that contain a value above/below the input values 949 and replace them with a new value (default is 0). 950 """ 951 th = vtki.new("ImageThreshold") 952 th.SetInputData(self.dataset) 953 954 # sanity checks 955 if above is not None and below is not None: 956 if above == below: 957 return self 958 if above > below: 959 vedo.logger.warning("in volume.threshold(), above > below, skip.") 960 return self 961 962 ## cases 963 if below is not None and above is not None: 964 th.ThresholdBetween(above, below) 965 966 elif above is not None: 967 th.ThresholdByUpper(above) 968 969 elif below is not None: 970 th.ThresholdByLower(below) 971 972 ## 973 if replace is not None: 974 th.SetReplaceIn(True) 975 th.SetInValue(replace) 976 else: 977 th.SetReplaceIn(False) 978 979 if replace_value is not None: 980 th.SetReplaceOut(True) 981 th.SetOutValue(replace_value) 982 else: 983 th.SetReplaceOut(False) 984 985 th.Update() 986 self._update(th.GetOutput()) 987 self.pipeline = utils.OperationNode("threshold", parents=[self], c="#4cc9f0") 988 return self
Binary or continuous volume thresholding. Find the voxels that contain a value above/below the input values and replace them with a new value (default is 0).
def
crop( self, left=None, right=None, back=None, front=None, bottom=None, top=None, VOI=()) -> Self:
990 def crop(self, left=None, right=None, back=None, front=None, bottom=None, top=None, VOI=()) -> Self: 991 """ 992 Crop a `Volume` object. 993 994 Arguments: 995 left : (float) 996 fraction to crop from the left plane (negative x) 997 right : (float) 998 fraction to crop from the right plane (positive x) 999 back : (float) 1000 fraction to crop from the back plane (negative y) 1001 front : (float) 1002 fraction to crop from the front plane (positive y) 1003 bottom : (float) 1004 fraction to crop from the bottom plane (negative z) 1005 top : (float) 1006 fraction to crop from the top plane (positive z) 1007 VOI : (list) 1008 extract Volume Of Interest expressed in voxel numbers 1009 1010 Example: 1011 `vol.crop(VOI=(xmin, xmax, ymin, ymax, zmin, zmax)) # all integers nrs` 1012 """ 1013 extractVOI = vtki.new("ExtractVOI") 1014 extractVOI.SetInputData(self.dataset) 1015 1016 if VOI: 1017 extractVOI.SetVOI(VOI) 1018 else: 1019 d = self.dataset.GetDimensions() 1020 bx0, bx1, by0, by1, bz0, bz1 = 0, d[0]-1, 0, d[1]-1, 0, d[2]-1 1021 if left is not None: bx0 = int((d[0]-1)*left) 1022 if right is not None: bx1 = int((d[0]-1)*(1-right)) 1023 if back is not None: by0 = int((d[1]-1)*back) 1024 if front is not None: by1 = int((d[1]-1)*(1-front)) 1025 if bottom is not None: bz0 = int((d[2]-1)*bottom) 1026 if top is not None: bz1 = int((d[2]-1)*(1-top)) 1027 extractVOI.SetVOI(bx0, bx1, by0, by1, bz0, bz1) 1028 extractVOI.Update() 1029 self._update(extractVOI.GetOutput()) 1030 1031 self.pipeline = utils.OperationNode( 1032 "crop", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1033 ) 1034 return self
Crop a Volume object.
Arguments:
- left : (float) fraction to crop from the left plane (negative x)
- right : (float) fraction to crop from the right plane (positive x)
- back : (float) fraction to crop from the back plane (negative y)
- front : (float) fraction to crop from the front plane (positive y)
- bottom : (float) fraction to crop from the bottom plane (negative z)
- top : (float) fraction to crop from the top plane (positive z)
- VOI : (list) extract Volume Of Interest expressed in voxel numbers
Example:
vol.crop(VOI=(xmin, xmax, ymin, ymax, zmin, zmax)) # all integers nrs
def
append(self, *volumes, axis='z', preserve_extents=False) -> Self:
1036 def append(self, *volumes, axis="z", preserve_extents=False) -> Self: 1037 """ 1038 Take the components from multiple inputs and merges them into one output. 1039 Except for the append axis, all inputs must have the same extent. 1040 All inputs must have the same number of scalar components. 1041 The output has the same origin and spacing as the first input. 1042 The origin and spacing of all other inputs are ignored. 1043 All inputs must have the same scalar type. 1044 1045 Arguments: 1046 axis : (int, str) 1047 axis expanded to hold the multiple images 1048 preserve_extents : (bool) 1049 if True, the extent of the inputs is used to place 1050 the image in the output. The whole extent of the output is the union of the input 1051 whole extents. Any portion of the output not covered by the inputs is set to zero. 1052 The origin and spacing is taken from the first input. 1053 1054 Example: 1055 ```python 1056 from vedo import Volume, dataurl 1057 vol = Volume(dataurl+'embryo.tif') 1058 vol.append(vol, axis='x').show().close() 1059 ``` 1060  1061 """ 1062 ima = vtki.new("ImageAppend") 1063 ima.SetInputData(self.dataset) 1064 # if not utils.is_sequence(volumes): 1065 # volumes = [volumes] 1066 for volume in volumes: 1067 if isinstance(volume, vtki.vtkImageData): 1068 ima.AddInputData(volume) 1069 else: 1070 ima.AddInputData(volume.dataset) 1071 ima.SetPreserveExtents(preserve_extents) 1072 if axis == "x": 1073 axis = 0 1074 elif axis == "y": 1075 axis = 1 1076 elif axis == "z": 1077 axis = 2 1078 ima.SetAppendAxis(axis) 1079 ima.Update() 1080 self._update(ima.GetOutput()) 1081 1082 self.pipeline = utils.OperationNode( 1083 "append", 1084 parents=[self, *volumes], 1085 c="#4cc9f0", 1086 comment=f"dims={tuple(self.dimensions())}", 1087 ) 1088 return self
Take the components from multiple inputs and merges them into one output. Except for the append axis, all inputs must have the same extent. All inputs must have the same number of scalar components. The output has the same origin and spacing as the first input. The origin and spacing of all other inputs are ignored. All inputs must have the same scalar type.
Arguments:
- axis : (int, str) axis expanded to hold the multiple images
- preserve_extents : (bool) if True, the extent of the inputs is used to place the image in the output. The whole extent of the output is the union of the input whole extents. Any portion of the output not covered by the inputs is set to zero. The origin and spacing is taken from the first input.
Example:
from vedo import Volume, dataurl vol = Volume(dataurl+'embryo.tif') vol.append(vol, axis='x').show().close()
def
pad(self, voxels=10, value=0) -> Self:
1090 def pad(self, voxels=10, value=0) -> Self: 1091 """ 1092 Add the specified number of voxels at the `Volume` borders. 1093 Voxels can be a list formatted as `[nx0, nx1, ny0, ny1, nz0, nz1]`. 1094 1095 Arguments: 1096 voxels : (int, list) 1097 number of voxels to be added (or a list of length 4) 1098 value : (int) 1099 intensity value (gray-scale color) of the padding 1100 1101 Example: 1102 ```python 1103 from vedo import Volume, dataurl, show 1104 iso = Volume(dataurl+'embryo.tif').isosurface() 1105 vol = iso.binarize(spacing=(100, 100, 100)).pad(10) 1106 vol.dilate([15,15,15]) 1107 show(iso, vol.isosurface(), N=2, axes=1) 1108 ``` 1109  1110 """ 1111 x0, x1, y0, y1, z0, z1 = self.dataset.GetExtent() 1112 pf = vtki.new("ImageConstantPad") 1113 pf.SetInputData(self.dataset) 1114 pf.SetConstant(value) 1115 if utils.is_sequence(voxels): 1116 pf.SetOutputWholeExtent( 1117 x0 - voxels[0], x1 + voxels[1], 1118 y0 - voxels[2], y1 + voxels[3], 1119 z0 - voxels[4], z1 + voxels[5], 1120 ) 1121 else: 1122 pf.SetOutputWholeExtent( 1123 x0 - voxels, x1 + voxels, 1124 y0 - voxels, y1 + voxels, 1125 z0 - voxels, z1 + voxels, 1126 ) 1127 pf.Update() 1128 self._update(pf.GetOutput()) 1129 self.pipeline = utils.OperationNode( 1130 "pad", comment=f"{voxels} voxels", parents=[self], c="#f28482" 1131 ) 1132 return self
Add the specified number of voxels at the Volume borders.
Voxels can be a list formatted as [nx0, nx1, ny0, ny1, nz0, nz1].
Arguments:
- voxels : (int, list) number of voxels to be added (or a list of length 4)
- value : (int) intensity value (gray-scale color) of the padding
Example:
from vedo import Volume, dataurl, show iso = Volume(dataurl+'embryo.tif').isosurface() vol = iso.binarize(spacing=(100, 100, 100)).pad(10) vol.dilate([15,15,15]) show(iso, vol.isosurface(), N=2, axes=1)
def
resize(self, newdims: List[int]) -> Self:
1134 def resize(self, newdims: List[int]) -> Self: 1135 """Increase or reduce the number of voxels of a Volume with interpolation.""" 1136 rsz = vtki.new("ImageResize") 1137 rsz.SetResizeMethodToOutputDimensions() 1138 rsz.SetInputData(self.dataset) 1139 rsz.SetOutputDimensions(newdims) 1140 rsz.Update() 1141 self.dataset = rsz.GetOutput() 1142 self._update(self.dataset) 1143 self.pipeline = utils.OperationNode( 1144 "resize", parents=[self], c="#4cc9f0", comment=f"dims={tuple(self.dimensions())}" 1145 ) 1146 return self
Increase or reduce the number of voxels of a Volume with interpolation.
def
normalize(self) -> Self:
1148 def normalize(self) -> Self: 1149 """Normalize that scalar components for each point.""" 1150 norm = vtki.new("ImageNormalize") 1151 norm.SetInputData(self.dataset) 1152 norm.Update() 1153 self._update(norm.GetOutput()) 1154 self.pipeline = utils.OperationNode("normalize", parents=[self], c="#4cc9f0") 1155 return self
Normalize that scalar components for each point.
def
mirror(self, axis='x') -> Self:
1157 def mirror(self, axis="x") -> Self: 1158 """ 1159 Mirror flip along one of the cartesian axes. 1160 """ 1161 img = self.dataset 1162 1163 ff = vtki.new("ImageFlip") 1164 ff.SetInputData(img) 1165 if axis.lower() == "x": 1166 ff.SetFilteredAxis(0) 1167 elif axis.lower() == "y": 1168 ff.SetFilteredAxis(1) 1169 elif axis.lower() == "z": 1170 ff.SetFilteredAxis(2) 1171 else: 1172 vedo.logger.error("mirror must be set to either x, y, z or n") 1173 raise RuntimeError() 1174 ff.Update() 1175 self._update(ff.GetOutput()) 1176 self.pipeline = utils.OperationNode(f"mirror {axis}", parents=[self], c="#4cc9f0") 1177 return self
Mirror flip along one of the cartesian axes.
1179 def operation(self, operation: str, volume2=None) -> "Volume": 1180 """ 1181 Perform operations with `Volume` objects. 1182 Keyword `volume2` can be a constant `float`. 1183 1184 Possible operations are: 1185 ``` 1186 and, or, xor, nand, nor, not, 1187 +, -, /, 1/x, sin, cos, exp, log, 1188 abs, **2, sqrt, min, max, atan, atan2, median, 1189 mag, dot, gradient, divergence, laplacian. 1190 ``` 1191 1192 Example: 1193 ```py 1194 from vedo import Box, show 1195 vol1 = Box(size=(35,10, 5)).binarize() 1196 vol2 = Box(size=( 5,10,35)).binarize() 1197 vol = vol1.operation("xor", vol2) 1198 show([[vol1, vol2], 1199 ["vol1 xor vol2", vol]], 1200 N=2, axes=1, viewup="z", 1201 ).close() 1202 ``` 1203 1204 Note: 1205 For logic operations, the two volumes must have the same bounds. 1206 If they do not, a larger image is created to contain both and the 1207 volumes are resampled onto the larger image before the operation is 1208 performed. This can be slow and memory intensive. 1209 1210 See also: 1211 - [volume_operations.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/volume_operations.py) 1212 """ 1213 op = operation.lower() 1214 image1 = self.dataset 1215 1216 if op in ["and", "or", "xor", "nand", "nor"]: 1217 1218 if not np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()): 1219 # create a larger image to contain both 1220 b1 = image1.GetBounds() 1221 b2 = volume2.dataset.GetBounds() 1222 b = [ 1223 min(b1[0], b2[0]), 1224 max(b1[1], b2[1]), 1225 min(b1[2], b2[2]), 1226 max(b1[3], b2[3]), 1227 min(b1[4], b2[4]), 1228 max(b1[5], b2[5]), 1229 ] 1230 dims1 = image1.GetDimensions() 1231 dims2 = volume2.dataset.GetDimensions() 1232 dims = [max(dims1[0], dims2[0]), max(dims1[1], dims2[1]), max(dims1[2], dims2[2])] 1233 1234 image = vtki.vtkImageData() 1235 image.SetDimensions(dims) 1236 spacing = ( 1237 (b[1] - b[0]) / dims[0], 1238 (b[3] - b[2]) / dims[1], 1239 (b[5] - b[4]) / dims[2], 1240 ) 1241 image.SetSpacing(spacing) 1242 image.SetOrigin((b[0], b[2], b[4])) 1243 image.AllocateScalars(vtki.VTK_UNSIGNED_CHAR, 1) 1244 image.GetPointData().GetScalars().FillComponent(0, 0) 1245 1246 interp1 = vtki.new("ImageReslice") 1247 interp1.SetInputData(image1) 1248 interp1.SetOutputExtent(image.GetExtent()) 1249 interp1.SetOutputOrigin(image.GetOrigin()) 1250 interp1.SetOutputSpacing(image.GetSpacing()) 1251 interp1.SetInterpolationModeToNearestNeighbor() 1252 interp1.Update() 1253 imageA = interp1.GetOutput() 1254 1255 interp2 = vtki.new("ImageReslice") 1256 interp2.SetInputData(volume2.dataset) 1257 interp2.SetOutputExtent(image.GetExtent()) 1258 interp2.SetOutputOrigin(image.GetOrigin()) 1259 interp2.SetOutputSpacing(image.GetSpacing()) 1260 interp2.SetInterpolationModeToNearestNeighbor() 1261 interp2.Update() 1262 imageB = interp2.GetOutput() 1263 1264 else: 1265 imageA = image1 1266 imageB = volume2.dataset 1267 1268 img_logic = vtki.new("ImageLogic") 1269 img_logic.SetInput1Data(imageA) 1270 img_logic.SetInput2Data(imageB) 1271 img_logic.SetOperation(["and", "or", "xor", "nand", "nor"].index(op)) 1272 img_logic.Update() 1273 1274 out_vol = Volume(img_logic.GetOutput()) 1275 out_vol.pipeline = utils.OperationNode( 1276 "operation", comment=f"{op}", parents=[self, volume2], c="#4cc9f0", shape="cylinder" 1277 ) 1278 return out_vol ###################################################### 1279 1280 if volume2 and isinstance(volume2, Volume): 1281 # assert image1.GetScalarType() == volume2.dataset.GetScalarType(), "volumes have different scalar types" 1282 # make sure they have the same bounds: 1283 assert np.allclose(image1.GetBounds(), volume2.dataset.GetBounds()), "volumes have different bounds" 1284 # make sure they have the same spacing: 1285 assert np.allclose(image1.GetSpacing(), volume2.dataset.GetSpacing()), "volumes have different spacing" 1286 # make sure they have the same origin: 1287 assert np.allclose(image1.GetOrigin(), volume2.dataset.GetOrigin()), "volumes have different origin" 1288 1289 mf = None 1290 if op in ["median"]: 1291 mf = vtki.new("ImageMedian3D") 1292 mf.SetInputData(image1) 1293 elif op in ["mag"]: 1294 mf = vtki.new("ImageMagnitude") 1295 mf.SetInputData(image1) 1296 elif op in ["dot"]: 1297 mf = vtki.new("ImageDotProduct") 1298 mf.SetInput1Data(image1) 1299 mf.SetInput2Data(volume2.dataset) 1300 elif op in ["grad", "gradient"]: 1301 mf = vtki.new("ImageGradient") 1302 mf.SetDimensionality(3) 1303 mf.SetInputData(image1) 1304 elif op in ["div", "divergence"]: 1305 mf = vtki.new("ImageDivergence") 1306 mf.SetInputData(image1) 1307 elif op in ["laplacian"]: 1308 mf = vtki.new("ImageLaplacian") 1309 mf.SetDimensionality(3) 1310 mf.SetInputData(image1) 1311 elif op in ["not"]: 1312 mf = vtki.new("ImageLogic") 1313 mf.SetInput1Data(image1) 1314 mf.SetOperation(4) 1315 1316 if mf is not None: 1317 mf.Update() 1318 vol = Volume(mf.GetOutput()) 1319 vol.pipeline = utils.OperationNode( 1320 "operation", comment=f"{op}", parents=[self], c="#4cc9f0", shape="cylinder" 1321 ) 1322 return vol ###################################################### 1323 1324 mat = vtki.new("ImageMathematics") 1325 mat.SetInput1Data(image1) 1326 1327 K = None 1328 1329 if utils.is_number(volume2): 1330 K = volume2 1331 mat.SetConstantK(K) 1332 mat.SetConstantC(K) 1333 1334 elif volume2 is not None: # assume image2 is a constant value 1335 mat.SetInput2Data(volume2.dataset) 1336 1337 # ########################### 1338 if op in ["+", "add", "plus"]: 1339 if K: 1340 mat.SetOperationToAddConstant() 1341 else: 1342 mat.SetOperationToAdd() 1343 1344 elif op in ["-", "subtract", "minus"]: 1345 if K: 1346 mat.SetConstantC(-float(K)) 1347 mat.SetOperationToAddConstant() 1348 else: 1349 mat.SetOperationToSubtract() 1350 1351 elif op in ["*", "multiply", "times"]: 1352 if K: 1353 mat.SetOperationToMultiplyByK() 1354 else: 1355 mat.SetOperationToMultiply() 1356 1357 elif op in ["/", "divide"]: 1358 if K: 1359 mat.SetConstantK(1.0 / K) 1360 mat.SetOperationToMultiplyByK() 1361 else: 1362 mat.SetOperationToDivide() 1363 1364 elif op in ["1/x", "invert"]: 1365 mat.SetOperationToInvert() 1366 elif op in ["sin"]: 1367 mat.SetOperationToSin() 1368 elif op in ["cos"]: 1369 mat.SetOperationToCos() 1370 elif op in ["exp"]: 1371 mat.SetOperationToExp() 1372 elif op in ["log"]: 1373 mat.SetOperationToLog() 1374 elif op in ["abs"]: 1375 mat.SetOperationToAbsoluteValue() 1376 elif op in ["**2", "square"]: 1377 mat.SetOperationToSquare() 1378 elif op in ["sqrt", "sqr"]: 1379 mat.SetOperationToSquareRoot() 1380 elif op in ["min"]: 1381 mat.SetOperationToMin() 1382 elif op in ["max"]: 1383 mat.SetOperationToMax() 1384 elif op in ["atan"]: 1385 mat.SetOperationToATAN() 1386 elif op in ["atan2"]: 1387 mat.SetOperationToATAN2() 1388 else: 1389 vedo.logger.error(f"unknown operation {operation}") 1390 raise RuntimeError() 1391 mat.Update() 1392 1393 self._update(mat.GetOutput()) 1394 1395 self.pipeline = utils.OperationNode( 1396 "operation", comment=f"{op}", parents=[self, volume2], shape="cylinder", c="#4cc9f0" 1397 ) 1398 return self
Perform operations with Volume objects.
Keyword volume2 can be a constant float.
Possible operations are:
and, or, xor, nand, nor, not,
+, -, /, 1/x, sin, cos, exp, log,
abs, **2, sqrt, min, max, atan, atan2, median,
mag, dot, gradient, divergence, laplacian.
Example:
from vedo import Box, show
vol1 = Box(size=(35,10, 5)).binarize()
vol2 = Box(size=( 5,10,35)).binarize()
vol = vol1.operation("xor", vol2)
show([[vol1, vol2],
["vol1 xor vol2", vol]],
N=2, axes=1, viewup="z",
).close()
Note:
For logic operations, the two volumes must have the same bounds. If they do not, a larger image is created to contain both and the volumes are resampled onto the larger image before the operation is performed. This can be slow and memory intensive.
See also:
def
frequency_pass_filter(self, low_cutoff=None, high_cutoff=None, order=1) -> Self:
1400 def frequency_pass_filter(self, low_cutoff=None, high_cutoff=None, order=1) -> Self: 1401 """ 1402 Low-pass and high-pass filtering become trivial in the frequency domain. 1403 A portion of the pixels/voxels are simply masked or attenuated. 1404 This function applies a high pass Butterworth filter that attenuates the 1405 frequency domain image. 1406 1407 The gradual attenuation of the filter is important. 1408 A simple high-pass filter would simply mask a set of pixels in the frequency domain, 1409 but the abrupt transition would cause a ringing effect in the spatial domain. 1410 1411 Arguments: 1412 low_cutoff : (list) 1413 the cutoff frequencies for x, y and z 1414 high_cutoff : (list) 1415 the cutoff frequencies for x, y and z 1416 order : (int) 1417 order determines sharpness of the cutoff curve 1418 """ 1419 # https://lorensen.github.io/VTKExamples/site/Cxx/ImageProcessing/IdealHighPass 1420 fft = vtki.new("ImageFFT") 1421 fft.SetInputData(self.dataset) 1422 fft.Update() 1423 out = fft.GetOutput() 1424 1425 if high_cutoff: 1426 blp = vtki.new("ImageButterworthLowPass") 1427 blp.SetInputData(out) 1428 blp.SetCutOff(high_cutoff) 1429 blp.SetOrder(order) 1430 blp.Update() 1431 out = blp.GetOutput() 1432 1433 if low_cutoff: 1434 bhp = vtki.new("ImageButterworthHighPass") 1435 bhp.SetInputData(out) 1436 bhp.SetCutOff(low_cutoff) 1437 bhp.SetOrder(order) 1438 bhp.Update() 1439 out = bhp.GetOutput() 1440 1441 rfft = vtki.new("ImageRFFT") 1442 rfft.SetInputData(out) 1443 rfft.Update() 1444 1445 ecomp = vtki.new("ImageExtractComponents") 1446 ecomp.SetInputData(rfft.GetOutput()) 1447 ecomp.SetComponents(0) 1448 ecomp.Update() 1449 self._update(ecomp.GetOutput()) 1450 self.pipeline = utils.OperationNode("frequency_pass_filter", parents=[self], c="#4cc9f0") 1451 return self
Low-pass and high-pass filtering become trivial in the frequency domain. A portion of the pixels/voxels are simply masked or attenuated. This function applies a high pass Butterworth filter that attenuates the frequency domain image.
The gradual attenuation of the filter is important. A simple high-pass filter would simply mask a set of pixels in the frequency domain, but the abrupt transition would cause a ringing effect in the spatial domain.
Arguments:
- low_cutoff : (list) the cutoff frequencies for x, y and z
- high_cutoff : (list) the cutoff frequencies for x, y and z
- order : (int) order determines sharpness of the cutoff curve
def
smooth_gaussian(self, sigma=(2, 2, 2), radius=None) -> Self:
1453 def smooth_gaussian(self, sigma=(2, 2, 2), radius=None) -> Self: 1454 """ 1455 Performs a convolution of the input Volume with a gaussian. 1456 1457 Arguments: 1458 sigma : (float, list) 1459 standard deviation(s) in voxel units. 1460 A list can be given to smooth in the three direction differently. 1461 radius : (float, list) 1462 radius factor(s) determine how far out the gaussian 1463 kernel will go before being clamped to zero. A list can be given too. 1464 """ 1465 gsf = vtki.new("ImageGaussianSmooth") 1466 gsf.SetDimensionality(3) 1467 gsf.SetInputData(self.dataset) 1468 if utils.is_sequence(sigma): 1469 gsf.SetStandardDeviations(sigma) 1470 else: 1471 gsf.SetStandardDeviation(sigma) 1472 if radius is not None: 1473 if utils.is_sequence(radius): 1474 gsf.SetRadiusFactors(radius) 1475 else: 1476 gsf.SetRadiusFactor(radius) 1477 gsf.Update() 1478 self._update(gsf.GetOutput()) 1479 self.pipeline = utils.OperationNode("smooth_gaussian", parents=[self], c="#4cc9f0") 1480 return self
Performs a convolution of the input Volume with a gaussian.
Arguments:
- sigma : (float, list) standard deviation(s) in voxel units. A list can be given to smooth in the three direction differently.
- radius : (float, list) radius factor(s) determine how far out the gaussian kernel will go before being clamped to zero. A list can be given too.
def
smooth_median(self, neighbours=(2, 2, 2)) -> Self:
1482 def smooth_median(self, neighbours=(2, 2, 2)) -> Self: 1483 """ 1484 Median filter that replaces each pixel with the median value 1485 from a rectangular neighborhood around that pixel. 1486 """ 1487 imgm = vtki.new("ImageMedian3D") 1488 imgm.SetInputData(self.dataset) 1489 if utils.is_sequence(neighbours): 1490 imgm.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1491 else: 1492 imgm.SetKernelSize(neighbours, neighbours, neighbours) 1493 imgm.Update() 1494 self._update(imgm.GetOutput()) 1495 self.pipeline = utils.OperationNode("smooth_median", parents=[self], c="#4cc9f0") 1496 return self
Median filter that replaces each pixel with the median value from a rectangular neighborhood around that pixel.
def
erode(self, neighbours=(2, 2, 2)) -> Self:
1498 def erode(self, neighbours=(2, 2, 2)) -> Self: 1499 """ 1500 Replace a voxel with the minimum over an ellipsoidal neighborhood of voxels. 1501 If `neighbours` of an axis is 1, no processing is done on that axis. 1502 1503 Examples: 1504 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1505 1506  1507 """ 1508 ver = vtki.new("ImageContinuousErode3D") 1509 ver.SetInputData(self.dataset) 1510 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1511 ver.Update() 1512 self._update(ver.GetOutput()) 1513 self.pipeline = utils.OperationNode("erode", parents=[self], c="#4cc9f0") 1514 return self
Replace a voxel with the minimum over an ellipsoidal neighborhood of voxels.
If neighbours of an axis is 1, no processing is done on that axis.
Examples:
def
dilate(self, neighbours=(2, 2, 2)) -> Self:
1516 def dilate(self, neighbours=(2, 2, 2)) -> Self: 1517 """ 1518 Replace a voxel with the maximum over an ellipsoidal neighborhood of voxels. 1519 If `neighbours` of an axis is 1, no processing is done on that axis. 1520 1521 Check also `erode()` and `pad()`. 1522 1523 Examples: 1524 - [erode_dilate.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/erode_dilate.py) 1525 """ 1526 ver = vtki.new("ImageContinuousDilate3D") 1527 ver.SetInputData(self.dataset) 1528 ver.SetKernelSize(neighbours[0], neighbours[1], neighbours[2]) 1529 ver.Update() 1530 self._update(ver.GetOutput()) 1531 self.pipeline = utils.OperationNode("dilate", parents=[self], c="#4cc9f0") 1532 return self
Replace a voxel with the maximum over an ellipsoidal neighborhood of voxels.
If neighbours of an axis is 1, no processing is done on that axis.
Examples:
def
magnitude(self) -> Self:
1534 def magnitude(self) -> Self: 1535 """Colapses components with magnitude function.""" 1536 imgm = vtki.new("ImageMagnitude") 1537 imgm.SetInputData(self.dataset) 1538 imgm.Update() 1539 self._update(imgm.GetOutput()) 1540 self.pipeline = utils.OperationNode("magnitude", parents=[self], c="#4cc9f0") 1541 return self
Colapses components with magnitude function.
1543 def topoints(self) -> "vedo.Points": 1544 """ 1545 Extract all image voxels as points. 1546 This function takes an input `Volume` and creates an `Mesh` 1547 that contains the points and the point attributes. 1548 1549 Examples: 1550 - [vol2points.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/vol2points.py) 1551 """ 1552 v2p = vtki.new("ImageToPoints") 1553 v2p.SetInputData(self.dataset) 1554 v2p.Update() 1555 mpts = vedo.Points(v2p.GetOutput()) 1556 mpts.pipeline = utils.OperationNode("topoints", parents=[self], c="#4cc9f0:#e9c46a") 1557 return mpts
Extract all image voxels as points.
This function takes an input Volume and creates an Mesh
that contains the points and the point attributes.
Examples:
1559 def euclidean_distance(self, anisotropy=False, max_distance=None) -> "Volume": 1560 """ 1561 Implementation of the Euclidean DT (Distance Transform) using Saito's algorithm. 1562 The distance map produced contains the square of the Euclidean distance values. 1563 The algorithm has a O(n^(D+1)) complexity over n x n x...x n images in D dimensions. 1564 1565 Check out also: https://en.wikipedia.org/wiki/Distance_transform 1566 1567 Arguments: 1568 anisotropy : bool 1569 used to define whether Spacing should be used in the 1570 computation of the distances. 1571 max_distance : bool 1572 any distance bigger than max_distance will not be 1573 computed but set to this specified value instead. 1574 1575 Examples: 1576 - [euclidian_dist.py](https://github.com/marcomusy/vedo/tree/master/examples/volumetric/euclidian_dist.py) 1577 """ 1578 euv = vtki.new("ImageEuclideanDistance") 1579 euv.SetInputData(self.dataset) 1580 euv.SetConsiderAnisotropy(anisotropy) 1581 if max_distance is not None: 1582 euv.InitializeOn() 1583 euv.SetMaximumDistance(max_distance) 1584 euv.SetAlgorithmToSaito() 1585 euv.Update() 1586 vol = Volume(euv.GetOutput()) 1587 vol.pipeline = utils.OperationNode("euclidean_distance", parents=[self], c="#4cc9f0") 1588 return vol
Implementation of the Euclidean DT (Distance Transform) using Saito's algorithm. The distance map produced contains the square of the Euclidean distance values. The algorithm has a O(n^(D+1)) complexity over n x n x...x n images in D dimensions.
Check out also: https://en.wikipedia.org/wiki/Distance_transform
Arguments:
- anisotropy : bool used to define whether Spacing should be used in the computation of the distances.
- max_distance : bool any distance bigger than max_distance will not be computed but set to this specified value instead.
Examples:
1590 def correlation_with(self, vol2: "Volume", dim=2) -> "Volume": 1591 """ 1592 Find the correlation between two volumetric data sets. 1593 Keyword `dim` determines whether the correlation will be 3D, 2D or 1D. 1594 The default is a 2D Correlation. 1595 1596 The output size will match the size of the first input. 1597 The second input is considered the correlation kernel. 1598 """ 1599 imc = vtki.new("ImageCorrelation") 1600 imc.SetInput1Data(self.dataset) 1601 imc.SetInput2Data(vol2.dataset) 1602 imc.SetDimensionality(dim) 1603 imc.Update() 1604 vol = Volume(imc.GetOutput()) 1605 1606 vol.pipeline = utils.OperationNode("correlation_with", parents=[self, vol2], c="#4cc9f0") 1607 return vol
Find the correlation between two volumetric data sets.
Keyword dim determines whether the correlation will be 3D, 2D or 1D.
The default is a 2D Correlation.
The output size will match the size of the first input. The second input is considered the correlation kernel.
def
scale_voxels(self, scale=1) -> Self:
1609 def scale_voxels(self, scale=1) -> Self: 1610 """Scale the voxel content by factor `scale`.""" 1611 rsl = vtki.new("ImageReslice") 1612 rsl.SetInputData(self.dataset) 1613 rsl.SetScalarScale(scale) 1614 rsl.Update() 1615 self._update(rsl.GetOutput()) 1616 self.pipeline = utils.OperationNode( 1617 "scale_voxels", comment=f"scale={scale}", parents=[self], c="#4cc9f0" 1618 ) 1619 return self
Scale the voxel content by factor scale.
Inherited Members
- vedo.core.CommonAlgorithms
- pointdata
- celldata
- metadata
- memory_address
- memory_size
- box
- update_dataset
- xbounds
- ybounds
- zbounds
- diagonal_size
- average_size
- center_of_mass
- copy_data_from
- inputdata
- npoints
- nvertices
- ncells
- points
- cell_centers
- lines
- lines_as_flat_array
- mark_boundaries
- find_cells_in_bounds
- find_cells_along_line
- find_cells_along_plane
- keep_cell_types
- map_cells_to_points
- vertices
- coordinates
- cells_as_flat_array
- cells
- map_points_to_cells
- resample_data_from
- interpolate_data_from
- add_ids
- gradient
- divergence
- vorticity
- probe
- compute_cell_size
- generate_random_data
- integrate_data
- write
- signed_distance
- unsigned_distance
- smooth_data
- compute_streamlines