def mouseReleaseEvent(self, event):
     button = event.button()
     self.setCursor(Qt.arrowCursor)
     if button == Qt.LeftButton:
         try:
             dx = event.x() - self.click1x
             dy = event.y() - self.click1y
         except AttributeError:
             return
         if dx != 0 or dy != 0:
             normal = Vector(self.axis)
             move = Vector(-dx*self.plane[:,0]+dy*self.plane[:,1])
             axis = normal.cross(move) / \
                    N.minimum.reduce(N.fabs(self.plotbox_size))
             rot = Rotation(axis.normal(), axis.length())
             self.axis = rot(normal).array
             self.plane[:,0] = rot(Vector(self.plane[:,0])).array
             self.plane[:,1] = rot(Vector(self.plane[:,1])).array
     elif button == Qt.MidButton:
         try:
             dx = event.x() - self.click2x
             dy = event.y() - self.click2y
         except AttributeError:
             return
         if dx != 0 or dy != 0:
             self.translate = self.translate + N.array([dx, dy])
     else:
         try:
             dy = event.y() - self.click3y
         except AttributeError:
             return
         if dy != 0:
             ratio = -dy/self.plotbox_size[1]
             self.scale = self.scale * (1.+ratio)
     self.update()
Esempio n. 2
0
def randomRotation(max_angle=N.pi):
    """
    :param max_angle: the upper limit for the rotation angle
    :type max_angle: float
    :returns: a random rotation with a uniform axis distribution
              and angles drawn from a uniform distribution between
              -max_angle and max_angle.
    :rtype: Scientific.Geometry.Transformations.Rotation
    """
    return Rotation(randomDirection(), uniform(-max_angle, max_angle))
Esempio n. 3
0
def cartesianCoordinateSymmetryTransformations(cell, space_group):
    """
    :param cell: a unit cell
    :type cell: CDTK.Crystal.UnitCell or MMTK.Universe
    :param space_group: a space group
    :type space_group: CDTK.SpaceGroups.SpaceGroup
    :returns: a list of transformation objects representing the symmetry
        operations of the space group in the Cartesian coordinates of
        the unit cell
    :rtype: list of Scientific.Geometry.Transformation.Transformation
    """
    transformations = []
    to_fract = Shear(cell.cartesianToFractionalMatrix())
    from_fract = Shear(cell.fractionalToCartesianMatrix())
    for rot, trans_num, trans_den in space_group.transformations:
        trans = Vector((1. * trans_num) / trans_den)
        tr_fract = Translation(trans) * Rotation(rot)
        transformations.append(from_fract * tr_fract * to_fract)
    return transformations
Esempio n. 4
0
    def releasehandler1(self, event):
	self.configure(cursor='top_left_arrow')
	self.update_idletasks()
        try:
            dx = event.x - self.click1x
            dy = event.y - self.click1y
        except AttributeError:
            return
        if dx != 0 or dy != 0:
            normal = Vector(self.axis)
            move = Vector(-dx*self.plane[:,0]+dy*self.plane[:,1])
            axis = normal.cross(move) / \
                   Numeric.minimum.reduce(Numeric.fabs(self.plotbox_size))
            rot = Rotation(axis.normal(), axis.length())
            self.axis = rot(normal).array
            self.plane[:,0] = rot(Vector(self.plane[:,0])).array
            self.plane[:,1] = rot(Vector(self.plane[:,1])).array
            self.clear(1)
            self.redraw()
 def test_projections(self):
     universe = MMTK.InfiniteUniverse()
     universe.m1 = MMTK.Molecule('water', position=MMTK.Vector(0., 0., 0.))
     universe.m2 = MMTK.Molecule('water', position=MMTK.Vector(1., 0., 0.))
     rbs = [universe.m1, MMTK.Collection([universe.m2.H1, universe.m2.H2])]
     s = RigidMotionSubspace(universe, rbs)
     self.checkOrthonormality(s)
     self.assertEqual(len(s), 11)
     basis = s.getBasis()
     self.assertEqual(len(basis), 11)
     complement = s.complement()
     complement_basis = complement.getBasis()
     self.assertEqual(len(complement_basis),
                      universe.degreesOfFreedom() - 11)
     for rb in rbs:
         for t in [
                 Translation(MMTK.Vector(0.1, -0.2, 1.5)),
                 Rotation(MMTK.Vector(0.3, 1.2, -2.3), 0.001)
         ]:
             d = rb.displacementUnderTransformation(t)
             self.assert_((s.projectionOf(d) - d).norm() < 1.e-7)
             self.assert_(s.projectionComplementOf(d).norm() < 1.e-7)
Esempio n. 6
0
def main():
    usage = "SA:MP Art generator v0.3 by DialUp\nUsage: %prog [options]"
    parser = OptionParser(usage=usage)
    parser.add_option(
        "-i",
        default=None,
        action="store",
        type="string",
        dest="input_image",
        help="input image for conversion, for example, C:\\test\\1.png")
    parser.add_option(
        "-o",
        default=None,
        action="store",
        type="string",
        dest="output_file",
        help="output file with PAWN code, for example, output.inc")

    # do a full report generation by default:
    parser.set_defaults(mode=0)

    # partial generation is done if some flags are specified:

    parser.add_option(
        "-m",
        default=0,
        action="store",
        type="int",
        dest="mode",
        help="result size: 0 = very big, 1 = big, 2 = medium, 3 = small")

    parser.add_option(
        "-s",
        default="-760.0 1900.0 60.0",
        action="store",
        type="string",
        dest="position",
        help="picture centre position, for example, \"-760.0 1900.0 60.0\"")

    parser.add_option(
        "-r",
        default="0 0 0",
        action="store",
        type="string",
        dest="rotation",
        help="rotation of the result picture, for example, \"0.0 0.0 90.0\"")

    parser.add_option(
        "-c",
        default=1,
        action="store",
        type="int",
        dest="crop",
        help=
        "0 = don't modify picture, 1 = crop, 2 = resize (to prevent half-filled objects)"
    )

    parser.add_option("-t",
                      default=0,
                      action="store",
                      type="int",
                      dest="type",
                      help="0 = CreateObject, 1 = CreateDynamicObject")

    parser.add_option("-d",
                      default=300,
                      action="store",
                      type="int",
                      dest="distance",
                      help="draw distance")

    (options, args) = parser.parse_args()

    if options.input_image == None or options.output_file == None:
        parser.error("input picture file and output file should be specified")
    global M_WP, M_HP, M_WS, M_HS, M_OID, TYPE, DISTANCE
    if options.distance != None:
        DISTANCE = options.distance
    if options.mode == 1:
        M_WS = M_WS_1
        M_HS = M_HS_1
        M_OID = M_OID_1
        print "mode 1"
    if options.mode == 2:
        M_WS = M_WS_2
        M_HS = M_HS_2
        M_OID = M_OID_2
        print "mode 2"
    if options.mode == 3:
        M_WS = M_WS_3
        M_HS = M_HS_3
        M_OID = M_OID_3
        print "mode 3"
    if options.type == 1:
        TYPE = 1
    pos_vec = [float(x) for x in options.position.split()]
    pos_rot = [float(x) for x in options.rotation.split()]
    if (len(pos_vec) != 3 or len(pos_rot) != 3):
        parser.error("bad position or rotation parameters! use -help")
    global angle, start_pos
    if options.crop >= 0 and options.crop < 3:
        global CROP
        CROP = options.crop
    angle = Vector(pos_rot[0], pos_rot[1], pos_rot[2])
    start_pos = Vector(pos_vec[0], pos_vec[1], pos_vec[2])
    dash = LoadImageFromFile(options.input_image)
    dash = Resize15(dash)
    xsize, ysize = dash.size
    blockx = int(float(xsize) / M_WP + 0.999)
    blocky = int(float(ysize) / M_HP + 0.999)
    dash_blocks = []
    for x in xrange(0, blockx):
        for y in xrange(0, blocky):
            curblock = GetCrop15(dash, x, y)
            dash_blocks.append(curblock)

    Rot_z = Rotation(Vector(0, 0, 1), angle[2] * pi / 180.0)
    Rot_y = Rotation(Vector(0, 1, 0), angle[1] * pi / 180.0)
    Rot_x = Rotation(Vector(1, 0, 0), angle[0] * pi / 180.0)

    up_vector = Rot_z(Rot_y(Rot_x(Vector(0, 0, 1)))).normal()
    right_vector = Rot_z(Rot_y(Rot_x(Vector(0, 1, 0)))).normal()

    start_x = blockx / 2
    start_y = blocky / 2
    res_blocks = []

    for block in dash_blocks:
        cur_x = block[1][0]
        cur_y = block[1][1]
        temp = (block[0], ((cur_x - start_x) * M_WS * right_vector +
                           (cur_y - start_y) * (-M_HS) * up_vector, angle))
        res_blocks.append(temp)
    out = open(options.output_file, 'w')
    out.write("//This art was made with DialUp's SAMP art tool\n")
    out.write("//Send your suggestions or questions to [email protected]\n")
    out.write("#if defined __SART__\n")
    out.write("#else\n")
    out.write("new __oid__;\nnew __temp_string__[2048];\n")
    out.write("new Float:__sX__, Float:__sY__,Float:__sZ__;\n")
    out.write("#endif\n")
    out.write("#define __SART__\n")
    out.write("__oid__ = 0;\n__sX__ = %02f; __sY__ = %02f; __sZ__ = %02f;\n" %
              (start_pos[0], start_pos[1], start_pos[2]))
    for block in res_blocks:
        ParseObject(out, block)
    out.close()
    print "Done! Now add the result include file into your gamemode!"
Esempio n. 7
0
def randomRotationMatrix():
    axis = Vector(randomArray((3, )))
    angle = 2. * N.pi * random.random()
    return Rotation(axis, angle).tensor.array
Esempio n. 8
0
    from Scientific.Geometry import Vector ##.Transformation import *
    from Scientific.Geometry.Transformation import Rotation
    from random import random
    #
    Q = mat3(0.36, 0.48, -0.8, -0.8, 0.6, 0, 0.48, 0.64, 0.60)
    axis_q, angle_q = axis_and_angle(Q)
    print "Axis_q:  %9.6f%9.6f%9.6f" % tuple(axis_q),
    print "Angle_q: %10.5f" % (angle_q*R2D)
    #
    for iii in range(1e6):
        axis_i = list(vec3([random(), random(), random()]).normalize())
        angle_i = 3*random()
        rme = mat3().rotation(angle_i, vec3(axis_i))
        axis_1, angle_1 = axis_and_angle(rme)

        v = Vector(axis_i)
        r = Rotation(v, angle_i)
        axis_2, angle_2 = r.axisAndAngle()
        axis_d = (axis_1 - vec3(tuple(axis_2))).length()
        angle_d = abs(angle_1 - angle_2)
        if (angle_d  > 1e-13) or (axis_d > 1e-13):
            print "Angle_d:  %.3e" % (angle_d*R2D),
            print "  Axis_length_diff:  %.3e" % axis_d 
            print "Axis_i:  %9.6f%9.6f%9.6f" % tuple(axis_i),
            print "Angle_i: %10.5f" % (angle_i*R2D)
            print "Axis_1:  %9.6f%9.6f%9.6f" % tuple(axis_1),
            print "Angle_1: %10.5f" % (angle_1*R2D)
            print "Axis_2:  %9.6f%9.6f%9.6f" % tuple(axis_2),
            print "Angle_2: %10.5f" % (angle_2*R2D)

def randomRotation(max_angle=N.pi):
    """Returns a Rotation object describing a random rotation
    with a uniform axis distribution and angles drawn from
    a uniform distribution between -|max_angle| and |max_angle|."""
    return Rotation(randomDirection(), uniform(-max_angle, max_angle))
Esempio n. 10
0
    from Scientific.Geometry import Vector  ##.Transformation import *
    from Scientific.Geometry.Transformation import Rotation
    from random import random
    #
    Q = mat3(0.36, 0.48, -0.8, -0.8, 0.6, 0, 0.48, 0.64, 0.60)
    axis_q, angle_q = axis_and_angle(Q)
    print "Axis_q:  %9.6f%9.6f%9.6f" % tuple(axis_q),
    print "Angle_q: %10.5f" % (angle_q * R2D)
    #
    for iii in range(1e6):
        axis_i = list(vec3([random(), random(), random()]).normalize())
        angle_i = 3 * random()
        rme = mat3().rotation(angle_i, vec3(axis_i))
        axis_1, angle_1 = axis_and_angle(rme)

        v = Vector(axis_i)
        r = Rotation(v, angle_i)
        axis_2, angle_2 = r.axisAndAngle()
        axis_d = (axis_1 - vec3(tuple(axis_2))).length()
        angle_d = abs(angle_1 - angle_2)
        if (angle_d > 1e-13) or (axis_d > 1e-13):
            print "Angle_d:  %.3e" % (angle_d * R2D),
            print "  Axis_length_diff:  %.3e" % axis_d
            print "Axis_i:  %9.6f%9.6f%9.6f" % tuple(axis_i),
            print "Angle_i: %10.5f" % (angle_i * R2D)
            print "Axis_1:  %9.6f%9.6f%9.6f" % tuple(axis_1),
            print "Angle_1: %10.5f" % (angle_1 * R2D)
            print "Axis_2:  %9.6f%9.6f%9.6f" % tuple(axis_2),
            print "Angle_2: %10.5f" % (angle_2 * R2D)