use std::{ cell::Cell, cmp, fs::File, io::{Seek, SeekFrom, Write}, mem, ptr, slice, }; use image::GenericImageView; use resize::Type; use starry_client::base::{ color::Color, renderer::{RenderMode, Renderer}, }; use crate::core::{SCREEN_HEIGHT, SCREEN_WIDTH}; use super::rect::Rect; /// Roi区域中的行数据 pub struct ImageRoiRows<'a> { /// Roi矩形区域(相对位置) rect: Rect, /// 矩形宽度 w: i32, /// 帧缓冲数据 data: &'a [Color], /// 当前行号 i: i32, } // 实现迭代器 impl<'a> Iterator for ImageRoiRows<'a> { type Item = &'a [Color]; fn next(&mut self) -> Option { if self.i < self.rect.height() { let start = (self.rect.top() + self.i) * self.w + self.rect.left(); let end = start + self.rect.width(); self.i += 1; Some(&self.data[start as usize..end as usize]) } else { None } } } /// Roi区域中的行数据 pub struct ImageRoiRowsMut<'a> { /// Roi矩形区域(相对位置) rect: Rect, /// 矩形宽度 w: i32, /// 帧缓冲数据 data: &'a mut [Color], /// 当前行号 i: i32, } // 实现迭代器 impl<'a> Iterator for ImageRoiRowsMut<'a> { type Item = &'a mut [Color]; fn next(&mut self) -> Option { if self.i < self.rect.height() { let mut data = mem::take(&mut self.data); // 剔除掉矩形以上的部分 if self.i == 0 { data = data .split_at_mut(self.rect.top() as usize * self.w as usize) .1 }; // 分离当前行和剩下的部分 let (row, tail) = data.split_at_mut(self.w as usize); self.data = tail; let start = self.rect.left() as usize; let end = self.rect.left() as usize + self.rect.width() as usize; self.i += 1; Some(&mut row[start..end]) } else { None } } } /// 图像中的ROI区域 pub struct ImageRoi<'a> { /// ROI矩形区域(相对位置) rect: Rect, /// 矩形区域宽度 w: i32, /// 帧缓冲数据 data: &'a mut [Color], } // 实现到迭代器的转换 impl<'a> IntoIterator for ImageRoi<'a> { type Item = &'a [Color]; type IntoIter = ImageRoiRows<'a>; fn into_iter(self) -> Self::IntoIter { let Self { rect, w, data } = self; // 两次切片操作 let data = &mut data[rect.top() as usize * w as usize..][..rect.height() as usize * w as usize]; ImageRoiRows { rect, w, data, i: 0, } } } impl<'a> ImageRoi<'a> { /// 获得Roi相应的行数据 pub fn rows(&'a self) -> ImageRoiRows<'a> { ImageRoiRows { rect: self.rect, w: self.w, data: self.data, i: 0, } } /// 获得Roi相应的行数据 pub fn rows_mut(&'a mut self) -> ImageRoiRowsMut<'a> { ImageRoiRowsMut { rect: self.rect, w: self.w, data: self.data, i: 0, } } /// Roi区域颜色混合 pub fn blend(&'a mut self, other: &ImageRoi) { for (self_row, other_row) in self.rows_mut().zip(other.rows()) { for (old, new) in self_row.iter_mut().zip(other_row.iter()) { let alpha = (new.data >> 24) & 0xFF; if alpha >= 255 { old.data = new.data; } else if alpha > 0 { let n_r = (((new.data >> 16) & 0xFF) * alpha) >> 8; let n_g = (((new.data >> 8) & 0xFF) * alpha) >> 8; let n_b = ((new.data & 0xFF) * alpha) >> 8; let n_alpha = 255 - alpha; let o_r = (((old.data >> 16) & 0xFF) * n_alpha) >> 8; let o_g = (((old.data >> 8) & 0xFF) * n_alpha) >> 8; let o_b = ((old.data & 0xFF) * n_alpha) >> 8; old.data = ((o_r << 16) | (o_g << 8) | o_b) + ((n_r << 16) | (n_g << 8) | n_b); } } } } /// Roi区域颜色覆盖 pub fn cover(&'a mut self, other: &ImageRoi) { for (self_row, other_row) in self.rows_mut().zip(other.rows()) { let len = cmp::min(self_row.len(), other_row.len()); unsafe { ptr::copy(other_row.as_ptr(), self_row.as_mut_ptr(), len); } } } } /// 包含帧缓冲区的图像 pub struct ImageRef<'a> { w: i32, h: i32, data: &'a mut [Color], mode: Cell, } impl<'a> ImageRef<'a> { /// 根据帧缓冲数据创建新图像 pub fn from_data(width: i32, height: i32, data: &'a mut [Color]) -> Self { ImageRef { w: width, h: height, data, mode: Cell::new(RenderMode::Blend), } } /// 获得图像宽度 pub fn width(&self) -> i32 { self.w } /// 获得图像高度 pub fn height(&self) -> i32 { self.h } /// 根据矩形区域返回相应的Roi pub fn roi(&mut self, rect: &Rect) -> ImageRoi { ImageRoi { rect: *rect, w: self.w, data: &mut self.data, } } } impl<'a> Renderer for ImageRef<'a> { fn width(&self) -> u32 { self.w as u32 } fn height(&self) -> u32 { self.h as u32 } fn data(&self) -> &[Color] { self.data } fn data_mut(&mut self) -> &mut [Color] { self.data } fn sync(&mut self) -> bool { true } fn mode(&self) -> &Cell { &self.mode } } /// 包含帧缓冲区的图像 #[derive(Clone)] pub struct Image { /// 宽度 w: i32, /// 高度 h: i32, /// 像素数据 data: Box<[Color]>, /// 渲染模式 mode: Cell, } impl Image { /// 创建默认图像 pub fn new(width: i32, height: i32) -> Self { Image::from_color(width, height, Color::rgb(0, 0, 0)) } /// 创建单一颜色的图像 pub fn from_color(width: i32, height: i32, color: Color) -> Self { Image::from_data( width, height, vec![color; (width * height) as usize].into_boxed_slice(), ) } /// 根据帧缓冲数据创建新图像 pub fn from_data(width: i32, height: i32, data: Box<[Color]>) -> Self { Image { w: width, h: height, data, mode: Cell::new(RenderMode::Blend), } } pub fn from_path(path: &[u8]) -> Option { if let Ok(mut img) = image::load_from_memory(path) { // let img = img.resize(20, 20, image::imageops::FilterType::Gaussian); let (mut img_width, mut img_heigh) = img.dimensions(); if img_width > SCREEN_WIDTH as u32 || img_heigh > SCREEN_HEIGHT as u32 { img = img.resize( SCREEN_WIDTH as u32, SCREEN_HEIGHT as u32, image::imageops::FilterType::Gaussian, ); (img_width, img_heigh) = img.dimensions(); } let mut image = Image::new(img_width as i32, img_heigh as i32); for y in 0..img_heigh { for x in 0..img_width as u32 { let pixel = img.get_pixel(x, y); let offset = y * img_width + x; // println!("Cursor pixel print x:{:?} y:{:?} rgba:{:?} {:?} {:?} {:?}", x, y, pixel[0], pixel[1], pixel[2], pixel[3]); image.data[offset as usize] = Color::rgba(pixel[0], pixel[1], pixel[2], pixel[3]); } } // println!( // "[Info] Image created from path successfully, width: {:?} height: {:?}", // img_width, img_heigh // ); return Some(image); } else { println!("[Error] Image created from path failed"); return None; } } /// 返回图像宽度 pub fn width(&self) -> i32 { self.w } /// 返回图像高度 pub fn height(&self) -> i32 { self.h } /// 返回图像宽度和高度 pub fn dimensions(&self) -> (i32, i32) { (self.w, self.h) } /// # 函数功能 /// 根据矩形区域返回相应的Roi /// /// ## 参数值 /// - rect: 矩形区域(相对位置) /// /// ## 返回值 /// Roi对象 pub fn roi(&mut self, rect: &Rect) -> ImageRoi { ImageRoi { rect: *rect, w: self.w, data: &mut self.data, } } /// 展示在桌面中央 pub fn show_on_desktop(&self) { let xoffset = (SCREEN_WIDTH as i32 - self.width()) / 2; let yoffset = (SCREEN_HEIGHT as i32 - self.height()) / 2; let mut fb = File::open("/dev/fb0").expect("[Error] Unable to open framebuffer"); for y in 0..self.height() { for x in 0..self.width() { let index: i32 = y * self.width() + x; let offset = ((y + yoffset) * SCREEN_WIDTH as i32 + x + xoffset) * 4; let color = &self.data[index as usize]; println!( "Image show print x:{:?} y:{:?} rgba:{:?} {:?} {:?} {:?}", x, y, color.r(), color.g(), color.b(), color.a() ); fb.seek(SeekFrom::Start(offset as u64)).expect("error"); fb.write(&self.data[index as usize].to_bgra_bytes()) .expect("error"); } } } /// 改变图像大小 pub fn resize(&self, w: u32, h: u32, resize_type: Type) -> Self { let mut dst_color = vec![Color { data: 0 }; w as usize * h as usize].into_boxed_slice(); let src = unsafe { slice::from_raw_parts(self.data.as_ptr() as *const u8, self.data.len() * 4) }; let mut dst = unsafe { slice::from_raw_parts_mut(dst_color.as_mut_ptr() as *mut u8, dst_color.len() * 4) }; let mut resizer = resize::new( self.w as usize, self.h as usize, w as usize, h as usize, resize::Pixel::RGBA, resize_type, ); resizer.resize(&src, &mut dst); Image::from_data(w as i32, h as i32, dst_color) } } impl Renderer for Image { fn width(&self) -> u32 { self.w as u32 } fn height(&self) -> u32 { self.h as u32 } fn data(&self) -> &[Color] { &self.data } fn data_mut(&mut self) -> &mut [Color] { &mut self.data } fn mode(&self) -> &Cell { &self.mode } fn sync(&mut self) -> bool { true } }