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behaviortree.rs
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behaviortree.rs
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// SPDX-FileCopyrightText: 2023 German Aerospace Center (DLR)
// SPDX-License-Identifier: Apache-2.0
use crate::{stl::Stl, table::Table, Trace};
use std::{collections::HashMap, time::SystemTime};
type SubtreeIdx = usize;
pub type Segmentation<'a> = Vec<(&'a TbtNode, usize, usize, f32)>;
pub type ClonedSegmentation = (f32, Vec<(TbtNode, usize, usize, f32)>);
static mut NODECOUNT: SubtreeIdx = 0;
/// Gets formula count
fn gnc() -> SubtreeIdx {
unsafe {
NODECOUNT += 1;
NODECOUNT - 1
}
}
pub fn tbt_node_reset_count() {
unsafe { NODECOUNT = 0 }
}
/*******************************
* Tbt
*******************************/
#[derive(Clone)]
#[allow(dead_code)]
/// # Arguments
/// * `next_nodes` - Maps current nodes to its successor nodes
/// * `tree` - The main tbt tree
pub struct Tbt {
pub next_nodes: HashMap<usize, Vec<usize>>,
pub tree: TbtNode,
}
#[allow(dead_code)]
impl Tbt {
pub fn new(tree: TbtNode) -> Self {
let mut next_nodes = HashMap::new();
let mut stack = Vec::new();
Tbt::init_next_nodes_map(&tree, &mut stack, &mut next_nodes);
Tbt { next_nodes, tree }
}
/// Creates the initial mapping for the TBT.next_nodes ie for each node its successor node
fn init_next_nodes_map<'a>(
tbt_node: &'a TbtNode,
stack_sequence: &mut Vec<(&'a TbtNode, usize)>,
map: &mut HashMap<usize, Vec<usize>>,
) {
match tbt_node {
TbtNode::Fallback(_, children) | TbtNode::Parallel(_, _, children) => {
for (index, child) in children.iter().enumerate() {
stack_sequence.push((tbt_node, index));
Tbt::init_next_nodes_map(child, stack_sequence, map);
stack_sequence.pop();
}
}
TbtNode::Kleene(_, _, _, child) | TbtNode::Timeout(_, _, child) => {
stack_sequence.push((tbt_node, 0));
Tbt::init_next_nodes_map(child, stack_sequence, map)
}
TbtNode::Sequence(_, l_child, r_child) => {
stack_sequence.push((tbt_node, 0));
Tbt::init_next_nodes_map(l_child, stack_sequence, map);
stack_sequence.pop();
stack_sequence.push((tbt_node, 1));
Tbt::init_next_nodes_map(r_child, stack_sequence, map);
stack_sequence.pop();
}
TbtNode::Leaf(index, _, _) => {
let mut stack_copy = stack_sequence.clone();
while !stack_copy.is_empty() {
let (parent, last_idx) = stack_copy.pop().unwrap();
if let TbtNode::Sequence(_, _, r_child) = parent {
if last_idx == 0 {
let next_leaves = Tbt::get_first_leaf(r_child);
map.insert(*index, next_leaves);
break;
}
}
}
}
}
}
/// Returns the first leafe given a TBT, I.e given Fallback(Sequence(A,B),B,C)) it returns [A, B, C]
fn get_first_leaf(tbt_node: &TbtNode) -> Vec<usize> {
match tbt_node {
TbtNode::Leaf(index, _, _) => vec![*index],
TbtNode::Fallback(_, children) | TbtNode::Parallel(_, _, children) => {
let mut vec_next = Vec::new();
for child in children {
vec_next.append(&mut Tbt::get_first_leaf(child));
}
vec_next
}
TbtNode::Sequence(_, child, _)
| TbtNode::Timeout(_, _, child)
| TbtNode::Kleene(_, _, _, child) => Tbt::get_first_leaf(child),
}
}
pub fn get_number_nodes() -> usize {
unsafe { NODECOUNT }
}
}
/*******************************
* TbtNode Syntax
*******************************/
#[derive(Clone)]
#[allow(dead_code)]
pub enum TbtNode {
Leaf(SubtreeIdx, Stl, String),
Fallback(SubtreeIdx, Vec<TbtNode>),
Parallel(SubtreeIdx, usize, Vec<TbtNode>),
Sequence(SubtreeIdx, Box<TbtNode>, Box<TbtNode>),
Timeout(SubtreeIdx, usize, Box<TbtNode>),
Kleene(SubtreeIdx, usize, Option<Box<TbtNode>>, Box<TbtNode>),
}
#[allow(dead_code)]
impl TbtNode {
/// Returns the index of a TBT node
pub fn get_index(&self) -> SubtreeIdx {
match self {
TbtNode::Leaf(index, _, _)
| TbtNode::Fallback(index, _)
| TbtNode::Parallel(index, _, _)
| TbtNode::Sequence(index, _, _)
| TbtNode::Timeout(index, _, _)
| TbtNode::Kleene(index, _, _, _) => *index,
}
}
/// Recursive call until first leaf node it found
fn get_leaf(&self, leaf_index: usize) -> Option<&TbtNode> {
match self {
TbtNode::Leaf(index, _, _) => {
if leaf_index == *index {
Some(self)
} else {
None
}
}
TbtNode::Fallback(_, children) | TbtNode::Parallel(_, _, children) => {
for child in children {
let leaf = child.get_leaf(leaf_index);
if leaf.is_some() {
return leaf;
}
}
None
}
TbtNode::Sequence(_, l_child, r_child) => {
let leaf = l_child.get_leaf(leaf_index);
if leaf.is_some() {
return leaf;
}
let leaf = r_child.get_leaf(leaf_index);
if leaf.is_some() {
return leaf;
}
None
}
TbtNode::Timeout(_, _, child) | TbtNode::Kleene(_, _, _, child) => {
child.get_leaf(leaf_index)
}
}
}
/****************
* Constructors
****************/
pub fn leaf(formula: Stl, name: String) -> Self {
TbtNode::Leaf(gnc(), formula, name)
}
pub fn fallback(formulas: Vec<TbtNode>) -> Self {
TbtNode::Fallback(gnc(), formulas)
}
pub fn parallel(m: usize, formulas: Vec<TbtNode>) -> Self {
TbtNode::Parallel(gnc(), m, formulas)
}
pub fn sequence(left_child: TbtNode, right_child: TbtNode) -> Self {
TbtNode::Sequence(gnc(), Box::new(left_child), Box::new(right_child))
}
pub fn timeout(t: usize, child: TbtNode) -> Self {
TbtNode::Timeout(gnc(), t, Box::new(child))
}
pub fn kleene(n: usize, child: TbtNode) -> Self {
let index = gnc();
let kleene_next = if n > 0 {
Some(Box::new(TbtNode::kleene(n - 1, child.clone())))
} else {
None
};
TbtNode::Kleene(index, n, kleene_next, Box::new(child))
}
pub fn kleene_inf(child: TbtNode, trace_length: usize) -> Self {
let n = usize::max(1, trace_length);
let mut formulas = vec![];
let mut kleene = TbtNode::kleene(n, child);
formulas.push(kleene.clone());
while let TbtNode::Kleene(_, n, Some(kleene_minus_one), _) = kleene {
if n == 1 {
break;
}
kleene = *kleene_minus_one;
formulas.push(kleene.clone());
}
assert_eq!(n, formulas.len());
TbtNode::parallel(1, formulas)
}
}
/*******************************
* Progress and print functions
*******************************/
#[allow(dead_code)]
impl TbtNode {
/******************
* Helper functions
******************/
/// Returns a string representation given an TBT. If with_children is false, then only leaves are printed. Line_shift is used to format the output.
pub fn pretty_print(&self, with_children: bool, line_shift: usize) -> String {
let indent_num = line_shift + 2;
let indent = " ".repeat(line_shift);
match self {
TbtNode::Leaf(index, formula, name) => {
let print_name = if name.is_empty() {
name.clone()
} else {
format!(" {name}")
};
if with_children {
format!(
"{}Leaf({index}{print_name})[{}]",
indent,
formula.pretty_print()
)
} else {
format!("{}Leaf({index}{print_name})", indent)
}
}
TbtNode::Fallback(index, subtrees) => {
if with_children {
let mut string_children = String::from("\n");
for subtree in subtrees {
string_children.push_str(&subtree.pretty_print(with_children, indent_num));
string_children.push_str(",\n");
}
format!("{}Fallback({index})[{string_children}{}]", indent, indent)
} else {
format!("{}Fallback({index})", indent)
}
}
TbtNode::Parallel(index, m, subtrees) => {
if with_children {
let mut string_children = String::from("\n");
for subtree in subtrees {
string_children.push_str(&subtree.pretty_print(with_children, indent_num));
string_children.push_str(",\n");
}
format!(
"{}Parallel({index},m={m})[\n{string_children}{}]",
indent, indent
)
} else {
format!("{}Parallel({index},m={m})", indent)
}
}
TbtNode::Sequence(index, l_child, r_child) => {
if with_children {
let mut children_string = l_child.pretty_print(with_children, indent_num);
children_string.push_str(",\n");
children_string.push_str(&r_child.pretty_print(with_children, indent_num));
children_string.push_str(",\n");
format!("{}Sequence({index})[\n{children_string}{}]", indent, indent)
} else {
format!("{}Sequence({index})", indent)
}
}
TbtNode::Timeout(index, t, child) => {
if with_children {
let child_string = child.pretty_print(with_children, indent_num);
format!("{indent}Timeout({index}, t={t})[\n{child_string}{indent}]")
} else {
format!("{indent}Timeout({index}, t={t})")
}
}
TbtNode::Kleene(index, n, _, child) => {
if with_children {
let child_string = child.pretty_print(with_children, indent_num);
format!("{indent}Kleene({index}, n={n})[\n{child_string}{indent}]")
} else {
format!("{indent}Kleene({index}, n={n})")
}
}
}
}
/// Returns the first STL formula in the TBT tree
pub fn get_leaf_formula(&self, look_for_index: usize) -> Option<&Stl> {
match self {
TbtNode::Leaf(index, formula, _) => {
if look_for_index == *index {
Some(formula)
} else {
None
}
}
TbtNode::Fallback(_, children) | TbtNode::Parallel(_, _, children) => {
for child in children {
let found = child.get_leaf_formula(look_for_index);
if found.is_some() {
return found;
}
}
None
}
TbtNode::Sequence(_, l_child, r_child) => {
let found = l_child.get_leaf_formula(look_for_index);
if found.is_some() {
return found;
}
let found = r_child.get_leaf_formula(look_for_index);
found
}
TbtNode::Timeout(_, _, child) | TbtNode::Kleene(_, _, _, child) => {
child.get_leaf_formula(look_for_index)
}
}
}
/// Returns all the STL formulas in a TBT
pub fn get_atomics(&self) -> Vec<&Stl> {
match self {
TbtNode::Leaf(_, formula, _) => formula.get_atomics(),
TbtNode::Fallback(_, children) | TbtNode::Parallel(_, _, children) => {
let mut atomics = Vec::new();
for child in children {
atomics.append(&mut child.get_atomics());
}
atomics
}
TbtNode::Sequence(_, l_child, r_child) => {
let mut atomics = l_child.get_atomics();
atomics.append(&mut r_child.get_atomics());
atomics
}
TbtNode::Timeout(_, _, child) | TbtNode::Kleene(_, _, _, child) => child.get_atomics(),
}
}
/***********************
* Standard Evaluation
***********************/
/// Evaluates a provided trace given TBT semantics
/// # Arguments
/// * `depth_manager_tree` - Used for lazy evaluation to return where stopped early
/// * `tree_table` - TBT data structure for dynamic programming
/// * `formula_table` - STL data structure for dynamic programming
/// * `trace` - Provided Trace that is analyzed
/// * `lower` - Segment start
/// * `upper` - Segment end
/// * `system_time` - Used for profiling
/// * `debug` - Enables debugging messages
/// * `lazy_eval` - Enables / disables lazy evaluation
#[allow(clippy::too_many_arguments)]
pub fn evaluate(
&self,
depth_manager_tree: &mut HashMap<usize, (usize, usize, f32)>,
tree_table: &mut Table,
formula_table: &mut Table,
trace: &Trace,
lower: usize,
upper: usize,
system_time: &SystemTime,
debug: bool,
lazy_eval: bool,
) -> f32 {
// Display progress
if debug {
progress(tree_table, formula_table, system_time);
}
// Lookup table
let res = if lower <= upper {
match self {
TbtNode::Leaf(index, _, _)
| TbtNode::Fallback(index, _)
| TbtNode::Parallel(index, _, _)
| TbtNode::Sequence(index, _, _)
| TbtNode::Timeout(index, _, _)
| TbtNode::Kleene(index, _, _, _) => tree_table.lookup(*index, lower, upper),
}
} else {
None
};
// Return previous computed result or start computation otherwise
if let Some(value) = res {
value
} else {
let (v, index) = match self {
TbtNode::Leaf(index, formula, _) => {
let v = formula.evaluate(formula_table, trace, lower, upper, lazy_eval);
(v, *index)
}
TbtNode::Fallback(index, subtrees) => {
let (l, u, mut v) = if lazy_eval {
match depth_manager_tree.get(index) {
Some((last_l, last_u, last_v)) => (*last_l, *last_u, *last_v),
None => (lower, upper, f32::NEG_INFINITY),
}
} else {
(lower, upper, f32::NEG_INFINITY)
};
for i in l..(u + 1) {
for subtree in subtrees {
let s_v = subtree.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
i,
upper,
system_time,
debug,
lazy_eval,
);
v = f32::max(s_v, v);
if lazy_eval && v > 0.0 {
depth_manager_tree.insert(*index, (i + 1, u, v));
break;
}
}
}
(v, *index)
}
TbtNode::Parallel(index, m, subtrees) => {
let mut v_vec = vec![];
for subtree in subtrees {
v_vec.push(subtree.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
lower,
upper,
system_time,
debug,
lazy_eval,
));
}
v_vec.sort_by(|a, b| b.partial_cmp(a).unwrap());
let mth_v_value = v_vec[m - 1];
(mth_v_value, *index)
}
TbtNode::Sequence(index, left_child, right_child) => {
let (l, u, mut v) = if lazy_eval {
match depth_manager_tree.get(index) {
Some((last_l, last_u, last_v)) => (*last_l, *last_u, *last_v),
None => (lower, upper, f32::NEG_INFINITY),
}
} else {
(lower, upper, f32::NEG_INFINITY)
};
for i in l..(u + 1) {
let t1_v = left_child.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
lower,
i,
system_time,
debug,
lazy_eval,
);
let t2_v = right_child.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
i + 1,
upper,
system_time,
debug,
lazy_eval,
);
v = f32::max(v, f32::min(t1_v, t2_v));
if lazy_eval && v > 0.0 {
depth_manager_tree.insert(*index, (i + 1, u, v));
break;
}
}
(v, *index)
}
TbtNode::Timeout(index, t, subtree) => {
let v = subtree.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
lower,
usize::min(upper, lower + t - 1),
system_time,
debug,
lazy_eval,
);
(v, *index)
}
TbtNode::Kleene(index, n, kleene_next, subtree) => {
let (l, u, mut v) = if lazy_eval {
match depth_manager_tree.get(index) {
Some((last_l, last_u, last_v)) => (*last_l, *last_u, *last_v),
None => (lower, upper, f32::NEG_INFINITY),
}
} else {
(lower, upper, f32::NEG_INFINITY)
};
if l <= u && *n > 0 {
let kleene_n_minus_1 = kleene_next.as_ref().unwrap();
// Copy of Sequence start!
for i in l..(u + 1) {
let t1_v = subtree.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
lower,
i,
system_time,
debug,
lazy_eval,
);
let t2_v = kleene_n_minus_1.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
i + 1,
upper,
system_time,
debug,
lazy_eval,
);
v = f32::max(v, f32::min(t1_v, t2_v));
if lazy_eval && v > 0.0 {
depth_manager_tree.insert(*index, (i + 1, u, v));
break;
}
}
(v, *index)
// Copy of Sequence end!
} else if *n == 0 && l <= u {
let v = subtree.evaluate(
depth_manager_tree,
tree_table,
formula_table,
trace,
l,
u,
system_time,
debug,
lazy_eval,
);
(v, *index)
} else {
return f32::INFINITY;
}
}
};
// Store result in table for next access
if lower <= upper {
tree_table.set(index, lower, upper, v);
}
v
}
}
/*******************
* Segmentation
*******************/
/// Returns a segmentation by reading off the dynamic programming entries
/// # Arguments
/// * `tree_table` - TBT data structure for dynamic programming
/// * `formula_table` - STL data structure for dynamic programming
/// * `trace` - Provided Trace that is analyzed
/// * `lower` - Segment start
/// * `upper` - Segment end
/// * `is_lazy` - Enables / disables lazy evaluation
pub fn get_segmentation(
&self,
tree_table: &mut Table,
formula_table: &mut Table,
trace: &Trace,
lower: usize,
upper: usize,
is_lazy: bool,
) -> Segmentation {
match self {
TbtNode::Leaf(index, formula, _) => {
let v = if lower > upper {
formula.evaluate(formula_table, trace, lower, upper, is_lazy)
} else {
match tree_table.lookup(*index, lower, upper) {
Some(v) => v,
None => formula.evaluate(formula_table, trace, lower, upper, is_lazy),
}
};
vec![(self, lower, upper, v)]
}
TbtNode::Fallback(_, subtrees) => {
let (mut v, mut begin, mut end, mut st) = (f32::NEG_INFINITY, lower, upper, None);
for i in lower..(upper + 1) {
for subtree in subtrees {
let s_v = match tree_table.lookup_segmentation_tree(subtree, i, upper) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
panic!("unexpected")
}
}
};
if s_v > v {
v = s_v;
begin = i;
end = upper;
st = Some(subtree)
}
}
}
let mut self_segmentation = vec![(self, lower, upper, v)];
let mut child_segmentation = st.unwrap().get_segmentation(
tree_table,
formula_table,
trace,
begin,
end,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
self_segmentation
}
TbtNode::Parallel(_, m, subtrees) => {
let mut v_vec = vec![];
for subtree in subtrees {
let s_v = match tree_table.lookup_segmentation_tree(subtree, lower, upper) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
f32::NEG_INFINITY // is ignored
}
}
};
v_vec.push((s_v, subtree));
}
v_vec.sort_by(|(a, _), (b, _)| b.partial_cmp(a).unwrap());
let (mth_v_value, _) = v_vec[m - 1];
let mut self_segmentation = vec![(self, lower, upper, mth_v_value)];
for (_, st) in v_vec.iter().take(*m) {
let mut child_segmentation = st.get_segmentation(
tree_table,
formula_table,
trace,
lower,
upper,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
}
self_segmentation
}
TbtNode::Sequence(_, left_child, right_child) => {
let (mut v, mut begin, mut change) = (f32::NEG_INFINITY, lower, upper);
for u in lower..(upper + 1) {
let t1_v = match tree_table.lookup_segmentation_tree(left_child, lower, u) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
panic!("unexpected")
}
}
};
let t2_v = if u + 1 > upper {
f32::NEG_INFINITY
} else {
match tree_table.lookup_segmentation_tree(right_child, u + 1, upper) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
f32::NEG_INFINITY
}
}
}
};
if t1_v < t2_v {
if t1_v > v {
v = t1_v;
begin = lower;
change = u;
}
} else if t2_v > v {
v = t2_v;
begin = lower;
change = u;
}
}
let mut self_segmentation = vec![(self, lower, upper, v)];
let mut child_segmentation = left_child.get_segmentation(
tree_table,
formula_table,
trace,
begin,
change,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
let mut child_segmentation = right_child.get_segmentation(
tree_table,
formula_table,
trace,
change + 1,
upper,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
self_segmentation
}
TbtNode::Timeout(_, t, child) => {
let v = if lower > usize::min(upper, lower + t - 1) {
f32::NEG_INFINITY
} else {
tree_table
.lookup_segmentation_tree(child, lower, usize::min(upper, lower + t - 1))
.unwrap()
};
let mut self_segmentation = vec![(self, lower, upper, v)];
let mut child_segmentation = child.get_segmentation(
tree_table,
formula_table,
trace,
lower,
usize::min(upper, lower + t - 1),
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
self_segmentation
}
TbtNode::Kleene(_, n, kleene_next, child) => {
if lower <= upper && *n > 0 {
let kleene_n_minus_1 = kleene_next.as_ref().unwrap();
let left_child = child;
let right_child = kleene_n_minus_1;
// Copy of Sequence start!
let (mut v, mut begin, mut change) = (f32::NEG_INFINITY, lower, upper);
for u in lower..(upper + 1) {
let t1_v = match tree_table.lookup_segmentation_tree(left_child, lower, u) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
panic!("unexpected")
}
}
};
let t2_v = if u + 1 > upper {
f32::NEG_INFINITY
} else {
match tree_table.lookup_segmentation_tree(right_child, u + 1, upper) {
Some(v) => v,
None => {
if is_lazy {
continue;
} else {
f32::NEG_INFINITY
}
}
}
};
if t1_v < t2_v {
if t1_v > v {
v = t1_v;
begin = lower;
change = u;
}
} else if t2_v > v {
v = t2_v;
begin = lower;
change = u;
}
}
let mut self_segmentation = vec![(self, lower, upper, v)];
let mut child_segmentation = left_child.get_segmentation(
tree_table,
formula_table,
trace,
begin,
change,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
let mut child_segmentation = right_child.get_segmentation(
tree_table,
formula_table,
trace,
change + 1,
upper,
is_lazy,
);
self_segmentation.append(&mut child_segmentation);
self_segmentation
// Copy of Sequence end!
} else if *n == 0 && lower < upper {
let v = tree_table
.lookup_segmentation_tree(child, lower, upper)
.unwrap();
let mut self_segmentation = vec![(self, lower, upper, v)];
self_segmentation.append(&mut child.get_segmentation(
tree_table,
formula_table,
trace,
lower,
upper,
is_lazy,
));
self_segmentation
} else {
vec![(self, lower, upper, f32::INFINITY)]
}
}
}
}
/// Computes tau difference that is used to filter out alternative segmentations
/// # Arguments
/// * `lower` - Segment start
/// * `upper` - Segment end
/// * `segmentations` - Previously computed segmentations
fn get_tau_dif(
&self,
lower: usize,
upper: usize,
segmentations: &Vec<Segmentation>,
) -> Option<usize> {
let mut found = None;
for segmentation in segmentations {
for (st, l, u, _) in segmentation {
let res = match (self, st) {
(TbtNode::Leaf(si, _, _), TbtNode::Leaf(ss, _, _))
| (TbtNode::Fallback(si, _), TbtNode::Fallback(ss, _))
| (TbtNode::Parallel(si, _, _), TbtNode::Parallel(ss, _, _))
| (TbtNode::Sequence(si, _, _), TbtNode::Sequence(ss, _, _))
| (TbtNode::Timeout(si, _, _), TbtNode::Timeout(ss, _, _))
| (TbtNode::Kleene(si, _, _, _), TbtNode::Kleene(ss, _, _, _)) => {
if si == ss {
let lower_dif = if lower > *l { lower - l } else { l - lower };
let upper_dif = if upper > *u { upper - u } else { u - upper };
Some(lower_dif + upper_dif)
} else {
None
}
}
_ => None,
};
found = match (found, res) {
(None, None) => None,
(None, Some(v)) => Some(v),
(Some(v), None) => Some(v),
(Some(v), Some(w)) => {
if v < w {
Some(v)
} else {
Some(w)
}
}
}
}
}
found
}
#[allow(clippy::too_many_arguments)]
/// Is used to filter alternative segmentations
/// # Arguments
/// * `tree_table` - TBT data structure for dynamic programming
/// * `formula_table` - STL data structure for dynamic programming
/// * `trace` - Provided Trace that is analyzed
/// * `lower` - Segment start
/// * `upper` - Segment end
/// * `tau_dif` - Used to filter out alternatives based on where segments start and end
/// * `rho_dif` - Used to filter out alternatives based on their difference in robustness
/// * `segmentations` - Previously identified alternative segmentations
fn get_segmentation_under_restriction(
&self,
tree_table: &mut Table,
formula_table: &mut Table,
trace: &Trace,
lower: usize,
upper: usize,
tau_dif: usize,
rho_dif: f32,
segmentations: &Vec<Segmentation>,
) -> (usize, Segmentation) {
match self {
TbtNode::Leaf(index, formula, _) => {
let v = if lower > upper {
formula.evaluate(formula_table, trace, lower, upper, false)
} else {
match tree_table.lookup(*index, lower, upper) {
Some(v) => v,
None => formula.evaluate(formula_table, trace, lower, upper, false),
}
};
match self.get_tau_dif(lower, upper, segmentations) {
Some(actual_tau_dif) => (actual_tau_dif, vec![(self, lower, upper, v)]),
None => (usize::MAX, vec![(self, lower, upper, v)]),
}
}
TbtNode::Fallback(_, subtrees) => {
let mut candidates = Vec::<(f32, usize, usize, &TbtNode)>::new();
for i in lower..(upper + 1) {
for subtree in subtrees {
let s_v = tree_table
.lookup_segmentation_tree(subtree, i, upper)
.unwrap();
candidates.push((s_v, i, upper, subtree));
}
}
candidates
.sort_by(|(rho1, _, _, _), (rho2, _, _, _)| rho2.partial_cmp(rho1).unwrap());
candidates.retain(|&(rho, _, _, _)| rho > rho_dif);
let mut best_candidate: (usize, Segmentation, f32) =
(usize::MIN, Vec::new(), f32::MIN);
for (v, begin, end, subtree) in candidates {
let mut candidate = subtree.get_segmentation_under_restriction(
tree_table,
formula_table,
trace,
begin,
end,
tau_dif,
rho_dif,
segmentations,
);
if candidate.0 > tau_dif {
let mut self_segmentation = vec![(self, lower, upper, v)];
self_segmentation.append(&mut candidate.1);
return (candidate.0, self_segmentation);
} else if candidate.0 > best_candidate.0 {
best_candidate.0 = candidate.0;
best_candidate.1 = candidate.1;
best_candidate.2 = v;
}
}
let mut self_segmentation = vec![(self, lower, upper, best_candidate.2)];
self_segmentation.append(&mut best_candidate.1);
(best_candidate.0, self_segmentation)
}
TbtNode::Parallel(_, m, subtrees) => {
let mut candidates = vec![];
for subtree in subtrees {
let s_v = match tree_table.lookup_segmentation_tree(subtree, lower, upper) {
Some(v) => v,
None => f32::NEG_INFINITY, // is ignored,
};
candidates.push((s_v, subtree));
}
candidates.sort_by(|(a, _), (b, _)| b.partial_cmp(a).unwrap());
candidates.retain(|&(rho, _)| rho > rho_dif);
let (mth_v_value, _) = candidates[m - 1];
let mut self_segmentation = vec![(self, lower, upper, mth_v_value)];
let mut sum_tau_dif = 0;
for (_, st) in candidates.iter().take(*m) {
let mut child_segmentation = st.get_segmentation_under_restriction(
tree_table,
formula_table,
trace,
lower,
upper,
tau_dif,
rho_dif,
segmentations,
);