projektAI/venv/Lib/site-packages/sklearn/tree/_reingold_tilford.py

# Authors: William Mill (bill@billmill.org)
# License: BSD 3 clause

import numpy as np


class DrawTree:
    def __init__(self, tree, parent=None, depth=0, number=1):
        self.x = -1.
        self.y = depth
        self.tree = tree
        self.children = [DrawTree(c, self, depth + 1, i + 1)
                         for i, c
                         in enumerate(tree.children)]
        self.parent = parent
        self.thread = None
        self.mod = 0
        self.ancestor = self
        self.change = self.shift = 0
        self._lmost_sibling = None
        # this is the number of the node in its group of siblings 1..n
        self.number = number

    def left(self):
        return self.thread or len(self.children) and self.children[0]

    def right(self):
        return self.thread or len(self.children) and self.children[-1]

    def lbrother(self):
        n = None
        if self.parent:
            for node in self.parent.children:
                if node == self:
                    return n
                else:
                    n = node
        return n

    def get_lmost_sibling(self):
        if not self._lmost_sibling and self.parent and self != \
                self.parent.children[0]:
            self._lmost_sibling = self.parent.children[0]
        return self._lmost_sibling
    lmost_sibling = property(get_lmost_sibling)

    def __str__(self):
        return "%s: x=%s mod=%s" % (self.tree, self.x, self.mod)

    def __repr__(self):
        return self.__str__()

    def max_extents(self):
        extents = [c.max_extents() for c in self. children]
        extents.append((self.x, self.y))
        return np.max(extents, axis=0)


def buchheim(tree):
    dt = first_walk(DrawTree(tree))
    min = second_walk(dt)
    if min < 0:
        third_walk(dt, -min)
    return dt


def third_walk(tree, n):
    tree.x += n
    for c in tree.children:
        third_walk(c, n)


def first_walk(v, distance=1.):
    if len(v.children) == 0:
        if v.lmost_sibling:
            v.x = v.lbrother().x + distance
        else:
            v.x = 0.
    else:
        default_ancestor = v.children[0]
        for w in v.children:
            first_walk(w)
            default_ancestor = apportion(w, default_ancestor, distance)
        # print("finished v =", v.tree, "children")
        execute_shifts(v)

        midpoint = (v.children[0].x + v.children[-1].x) / 2

        w = v.lbrother()
        if w:
            v.x = w.x + distance
            v.mod = v.x - midpoint
        else:
            v.x = midpoint
    return v


def apportion(v, default_ancestor, distance):
    w = v.lbrother()
    if w is not None:
        # in buchheim notation:
        # i == inner; o == outer; r == right; l == left; r = +; l = -
        vir = vor = v
        vil = w
        vol = v.lmost_sibling
        sir = sor = v.mod
        sil = vil.mod
        sol = vol.mod
        while vil.right() and vir.left():
            vil = vil.right()
            vir = vir.left()
            vol = vol.left()
            vor = vor.right()
            vor.ancestor = v
            shift = (vil.x + sil) - (vir.x + sir) + distance
            if shift > 0:
                move_subtree(ancestor(vil, v, default_ancestor), v, shift)
                sir = sir + shift
                sor = sor + shift
            sil += vil.mod
            sir += vir.mod
            sol += vol.mod
            sor += vor.mod
        if vil.right() and not vor.right():
            vor.thread = vil.right()
            vor.mod += sil - sor
        else:
            if vir.left() and not vol.left():
                vol.thread = vir.left()
                vol.mod += sir - sol
            default_ancestor = v
    return default_ancestor


def move_subtree(wl, wr, shift):
    subtrees = wr.number - wl.number
    # print(wl.tree, "is conflicted with", wr.tree, 'moving', subtrees,
    # 'shift', shift)
    # print wl, wr, wr.number, wl.number, shift, subtrees, shift/subtrees
    wr.change -= shift / subtrees
    wr.shift += shift
    wl.change += shift / subtrees
    wr.x += shift
    wr.mod += shift


def execute_shifts(v):
    shift = change = 0
    for w in v.children[::-1]:
        # print("shift:", w, shift, w.change)
        w.x += shift
        w.mod += shift
        change += w.change
        shift += w.shift + change


def ancestor(vil, v, default_ancestor):
    # the relevant text is at the bottom of page 7 of
    # "Improving Walker's Algorithm to Run in Linear Time" by Buchheim et al,
    # (2002)
    # http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.16.8757&rep=rep1&type=pdf
    if vil.ancestor in v.parent.children:
        return vil.ancestor
    else:
        return default_ancestor


def second_walk(v, m=0, depth=0, min=None):
    v.x += m
    v.y = depth

    if min is None or v.x < min:
        min = v.x

    for w in v.children:
        min = second_walk(w, m + v.mod, depth + 1, min)

    return min


class Tree:
    def __init__(self, label="", node_id=-1, *children):
        self.label = label
        self.node_id = node_id
        if children:
            self.children = children
        else:
            self.children = []
Działa 2021-06-06 22:13:05 +02:00			`# Authors: William Mill (bill@billmill.org)`
			`# License: BSD 3 clause`

			`import numpy as np`


			`class DrawTree:`
			`def __init__(self, tree, parent=None, depth=0, number=1):`
			`self.x = -1.`
			`self.y = depth`
			`self.tree = tree`
			`self.children = [DrawTree(c, self, depth + 1, i + 1)`
			`for i, c`
			`in enumerate(tree.children)]`
			`self.parent = parent`
			`self.thread = None`
			`self.mod = 0`
			`self.ancestor = self`
			`self.change = self.shift = 0`
			`self._lmost_sibling = None`
			`# this is the number of the node in its group of siblings 1..n`
			`self.number = number`

			`def left(self):`
			`return self.thread or len(self.children) and self.children[0]`

			`def right(self):`
			`return self.thread or len(self.children) and self.children[-1]`

			`def lbrother(self):`
			`n = None`
			`if self.parent:`
			`for node in self.parent.children:`
			`if node == self:`
			`return n`
			`else:`
			`n = node`
			`return n`

			`def get_lmost_sibling(self):`
			`if not self._lmost_sibling and self.parent and self != \`
			`self.parent.children[0]:`
			`self._lmost_sibling = self.parent.children[0]`
			`return self._lmost_sibling`
			`lmost_sibling = property(get_lmost_sibling)`

			`def __str__(self):`
			`return "%s: x=%s mod=%s" % (self.tree, self.x, self.mod)`

			`def __repr__(self):`
			`return self.__str__()`

			`def max_extents(self):`
			`extents = [c.max_extents() for c in self. children]`
			`extents.append((self.x, self.y))`
			`return np.max(extents, axis=0)`


			`def buchheim(tree):`
			`dt = first_walk(DrawTree(tree))`
			`min = second_walk(dt)`
			`if min < 0:`
			`third_walk(dt, -min)`
			`return dt`


			`def third_walk(tree, n):`
			`tree.x += n`
			`for c in tree.children:`
			`third_walk(c, n)`


			`def first_walk(v, distance=1.):`
			`if len(v.children) == 0:`
			`if v.lmost_sibling:`
			`v.x = v.lbrother().x + distance`
			`else:`
			`v.x = 0.`
			`else:`
			`default_ancestor = v.children[0]`
			`for w in v.children:`
			`first_walk(w)`
			`default_ancestor = apportion(w, default_ancestor, distance)`
			`# print("finished v =", v.tree, "children")`
			`execute_shifts(v)`

			`midpoint = (v.children[0].x + v.children[-1].x) / 2`

			`w = v.lbrother()`
			`if w:`
			`v.x = w.x + distance`
			`v.mod = v.x - midpoint`
			`else:`
			`v.x = midpoint`
			`return v`


			`def apportion(v, default_ancestor, distance):`
			`w = v.lbrother()`
			`if w is not None:`
			`# in buchheim notation:`
			`# i == inner; o == outer; r == right; l == left; r = +; l = -`
			`vir = vor = v`
			`vil = w`
			`vol = v.lmost_sibling`
			`sir = sor = v.mod`
			`sil = vil.mod`
			`sol = vol.mod`
			`while vil.right() and vir.left():`
			`vil = vil.right()`
			`vir = vir.left()`
			`vol = vol.left()`
			`vor = vor.right()`
			`vor.ancestor = v`
			`shift = (vil.x + sil) - (vir.x + sir) + distance`
			`if shift > 0:`
			`move_subtree(ancestor(vil, v, default_ancestor), v, shift)`
			`sir = sir + shift`
			`sor = sor + shift`
			`sil += vil.mod`
			`sir += vir.mod`
			`sol += vol.mod`
			`sor += vor.mod`
			`if vil.right() and not vor.right():`
			`vor.thread = vil.right()`
			`vor.mod += sil - sor`
			`else:`
			`if vir.left() and not vol.left():`
			`vol.thread = vir.left()`
			`vol.mod += sir - sol`
			`default_ancestor = v`
			`return default_ancestor`


			`def move_subtree(wl, wr, shift):`
			`subtrees = wr.number - wl.number`
			`# print(wl.tree, "is conflicted with", wr.tree, 'moving', subtrees,`
			`# 'shift', shift)`
			`# print wl, wr, wr.number, wl.number, shift, subtrees, shift/subtrees`
			`wr.change -= shift / subtrees`
			`wr.shift += shift`
			`wl.change += shift / subtrees`
			`wr.x += shift`
			`wr.mod += shift`


			`def execute_shifts(v):`
			`shift = change = 0`
			`for w in v.children[::-1]:`
			`# print("shift:", w, shift, w.change)`
			`w.x += shift`
			`w.mod += shift`
			`change += w.change`
			`shift += w.shift + change`


			`def ancestor(vil, v, default_ancestor):`
			`# the relevant text is at the bottom of page 7 of`
			`# "Improving Walker's Algorithm to Run in Linear Time" by Buchheim et al,`
			`# (2002)`
			`# http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.16.8757&rep=rep1&type=pdf`
			`if vil.ancestor in v.parent.children:`
			`return vil.ancestor`
			`else:`
			`return default_ancestor`


			`def second_walk(v, m=0, depth=0, min=None):`
			`v.x += m`
			`v.y = depth`

			`if min is None or v.x < min:`
			`min = v.x`

			`for w in v.children:`
			`min = second_walk(w, m + v.mod, depth + 1, min)`

			`return min`


			`class Tree:`
			`def __init__(self, label="", node_id=-1, *children):`
			`self.label = label`
			`self.node_id = node_id`
			`if children:`
			`self.children = children`
			`else:`
			`self.children = []`