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/*
* Copyright 2007 ZXing authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
// package com.google.zxing.common;
use std::ops::Mul;
use crate::{common::Result, point_f, Exceptions, Point};
use super::Quadrilateral;
/**
* <p>This class implements a perspective transform in two dimensions. Given four source and four
* destination points, it will compute the transformation implied between them. The code is based
* directly upon section 3.4.2 of George Wolberg's "Digital Image Warping"; see pages 54-56.</p>
*
* @author Sean Owen
*/
#[derive(Debug, Copy, Clone, PartialEq)]
pub struct PerspectiveTransform {
a11: f32,
a12: f32,
a13: f32,
a21: f32,
a22: f32,
a23: f32,
a31: f32,
a32: f32,
a33: f32,
}
impl PerspectiveTransform {
#[allow(clippy::too_many_arguments)]
fn new(
a11: f32,
a21: f32,
a31: f32,
a12: f32,
a22: f32,
a32: f32,
a13: f32,
a23: f32,
a33: f32,
) -> Self {
Self {
a11,
a12,
a13,
a21,
a22,
a23,
a31,
a32,
a33,
}
}
#[allow(clippy::too_many_arguments)]
pub fn quadrilateralToQuadrilateral(dst: Quadrilateral, src: Quadrilateral) -> Result<Self> {
if !src.is_convex() || !dst.is_convex() {
return Err(Exceptions::ILLEGAL_STATE);
}
// let q_to_s = PerspectiveTransform::quadrilateralToSquare(x0, y0, x1, y1, x2, y2, x3, y3);
// let s_to_q =
// PerspectiveTransform::squareToQuadrilateral(x0p, y0p, x1p, y1p, x2p, y2p, x3p, y3p);
let q_to_s = PerspectiveTransform::quadrilateralToSquare(dst);
let s_to_q = PerspectiveTransform::squareToQuadrilateral(src);
Ok(s_to_q * q_to_s)
}
pub fn transform_point(&self, point: Point) -> Point {
let x = point.x;
let y = point.y;
let denominator = self.a13 * x + self.a23 * y + self.a33;
Point::new(
(self.a11 * x + self.a21 * y + self.a31) / denominator,
(self.a12 * x + self.a22 * y + self.a32) / denominator,
)
}
pub fn transform_points_single(&self, points: &mut [Point]) {
for point in points.iter_mut() {
*point = self.transform_point(Point::new(point.x, point.y));
}
// for point in points.iter_mut() {
// // for (int i = 0; i < maxI; i += 2) {
// let x = point.x;
// let y = point.y;
// let denominator = self.a13 * x + self.a23 * y + self.a33;
// point.x = (self.a11 * x + self.a21 * y + self.a31) / denominator;
// point.y = (self.a12 * x + self.a22 * y + self.a32) / denominator;
// }
}
pub fn transform_points_double(&self, x_values: &mut [f32], y_valuess: &mut [f32]) {
let n = x_values.len();
// for i in 0..n {
for (x, y) in x_values.iter_mut().zip(y_valuess.iter_mut()).take(n) {
// for (int i = 0; i < n; i++) {
let denominator = self.a13 * *x + self.a23 * *y + self.a33;
*x = (self.a11 * *x + self.a21 * *y + self.a31) / denominator;
*y = (self.a12 * *x + self.a22 * *y + self.a32) / denominator;
}
}
#[allow(clippy::too_many_arguments)]
pub fn squareToQuadrilateral(square: Quadrilateral) -> Self {
let [p0, p1, p2, p3] = square.0;
let d3 = p0 - p1 + p2 - p3;
if d3 == point_f(0.0, 0.0) {
// Affine
PerspectiveTransform::new(
p1.x - p0.x,
p2.x - p1.x,
p0.x,
p1.y - p0.y,
p2.y - p1.y,
p0.y,
0.0,
0.0,
1.0,
)
} else {
let d1 = p1 - p2;
let d2 = p3 - p2;
let denominator = d1.cross(d2);
let a13 = d3.cross(d2) / denominator;
let a23 = d1.cross(d3) / denominator;
PerspectiveTransform::new(
p1.x - p0.x + a13 * p1.x,
p3.x - p0.x + a23 * p3.x,
p0.x,
p1.y - p0.y + a13 * p1.y,
p3.y - p0.y + a23 * p3.y,
p0.y,
a13,
a23,
1.0,
)
}
}
#[allow(clippy::too_many_arguments)]
pub fn quadrilateralToSquare(quad: Quadrilateral) -> Self {
// Here, the adjoint serves as the inverse
PerspectiveTransform::squareToQuadrilateral(quad).buildAdjoint()
}
fn buildAdjoint(&self) -> Self {
// Adjoint is the transpose of the cofactor matrix:
PerspectiveTransform::new(
self.a22 * self.a33 - self.a23 * self.a32,
self.a23 * self.a31 - self.a21 * self.a33,
self.a21 * self.a32 - self.a22 * self.a31,
self.a13 * self.a32 - self.a12 * self.a33,
self.a11 * self.a33 - self.a13 * self.a31,
self.a12 * self.a31 - self.a11 * self.a32,
self.a12 * self.a23 - self.a13 * self.a22,
self.a13 * self.a21 - self.a11 * self.a23,
self.a11 * self.a22 - self.a12 * self.a21,
)
}
pub fn isValid(&self) -> bool {
!self.a33.is_nan()
}
}
impl Mul for PerspectiveTransform {
type Output = PerspectiveTransform;
fn mul(self, rhs: Self) -> Self::Output {
PerspectiveTransform::new(
self.a11 * rhs.a11 + self.a21 * rhs.a12 + self.a31 * rhs.a13,
self.a11 * rhs.a21 + self.a21 * rhs.a22 + self.a31 * rhs.a23,
self.a11 * rhs.a31 + self.a21 * rhs.a32 + self.a31 * rhs.a33,
self.a12 * rhs.a11 + self.a22 * rhs.a12 + self.a32 * rhs.a13,
self.a12 * rhs.a21 + self.a22 * rhs.a22 + self.a32 * rhs.a23,
self.a12 * rhs.a31 + self.a22 * rhs.a32 + self.a32 * rhs.a33,
self.a13 * rhs.a11 + self.a23 * rhs.a12 + self.a33 * rhs.a13,
self.a13 * rhs.a21 + self.a23 * rhs.a22 + self.a33 * rhs.a23,
self.a13 * rhs.a31 + self.a23 * rhs.a32 + self.a33 * rhs.a33,
)
}
}