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Diffstat (limited to 'gfx/wr/webrender/src/image_tiling.rs')
| -rw-r--r-- | gfx/wr/webrender/src/image_tiling.rs | 823 |
1 files changed, 823 insertions, 0 deletions
diff --git a/gfx/wr/webrender/src/image_tiling.rs b/gfx/wr/webrender/src/image_tiling.rs new file mode 100644 index 0000000000..e2fb3b05b9 --- /dev/null +++ b/gfx/wr/webrender/src/image_tiling.rs @@ -0,0 +1,823 @@ +/* This Source Code Form is subject to the terms of the Mozilla Public + * License, v. 2.0. If a copy of the MPL was not distributed with this + * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ + +use crate::api::TileSize; +use crate::api::units::*; +use crate::segment::EdgeAaSegmentMask; +use euclid::{point2, size2}; +use std::i32; +use std::ops::Range; + +/// If repetitions are far enough apart that only one is within +/// the primitive rect, then we can simplify the parameters and +/// treat the primitive as not repeated. +/// This can let us avoid unnecessary work later to handle some +/// of the parameters. +pub fn simplify_repeated_primitive( + stretch_size: &LayoutSize, + tile_spacing: &mut LayoutSize, + prim_rect: &mut LayoutRect, +) { + let stride = *stretch_size + *tile_spacing; + + if stride.width >= prim_rect.width() { + tile_spacing.width = 0.0; + prim_rect.max.x = f32::min(prim_rect.min.x + stretch_size.width, prim_rect.max.x); + } + if stride.height >= prim_rect.height() { + tile_spacing.height = 0.0; + prim_rect.max.y = f32::min(prim_rect.min.y + stretch_size.height, prim_rect.max.y); + } +} + +pub struct Repetition { + pub origin: LayoutPoint, + pub edge_flags: EdgeAaSegmentMask, +} + +pub struct RepetitionIterator { + current_x: i32, + x_count: i32, + current_y: i32, + y_count: i32, + row_flags: EdgeAaSegmentMask, + current_origin: LayoutPoint, + initial_origin: LayoutPoint, + stride: LayoutSize, +} + +impl RepetitionIterator { + pub fn num_repetitions(&self) -> usize { + (self.y_count * self.x_count) as usize + } +} + +impl Iterator for RepetitionIterator { + type Item = Repetition; + + fn next(&mut self) -> Option<Self::Item> { + if self.current_x == self.x_count { + self.current_y += 1; + if self.current_y >= self.y_count { + return None; + } + self.current_x = 0; + + self.row_flags = EdgeAaSegmentMask::empty(); + if self.current_y == self.y_count - 1 { + self.row_flags |= EdgeAaSegmentMask::BOTTOM; + } + + self.current_origin.x = self.initial_origin.x; + self.current_origin.y += self.stride.height; + } + + let mut edge_flags = self.row_flags; + if self.current_x == 0 { + edge_flags |= EdgeAaSegmentMask::LEFT; + } + + if self.current_x == self.x_count - 1 { + edge_flags |= EdgeAaSegmentMask::RIGHT; + } + + let repetition = Repetition { + origin: self.current_origin, + edge_flags, + }; + + self.current_origin.x += self.stride.width; + self.current_x += 1; + + Some(repetition) + } +} + +pub fn repetitions( + prim_rect: &LayoutRect, + visible_rect: &LayoutRect, + stride: LayoutSize, +) -> RepetitionIterator { + let visible_rect = match prim_rect.intersection(&visible_rect) { + Some(rect) => rect, + None => { + return RepetitionIterator { + current_origin: LayoutPoint::zero(), + initial_origin: LayoutPoint::zero(), + current_x: 0, + current_y: 0, + x_count: 0, + y_count: 0, + stride, + row_flags: EdgeAaSegmentMask::empty(), + } + } + }; + + assert!(stride.width > 0.0); + assert!(stride.height > 0.0); + + let nx = if visible_rect.min.x > prim_rect.min.x { + f32::floor((visible_rect.min.x - prim_rect.min.x) / stride.width) + } else { + 0.0 + }; + + let ny = if visible_rect.min.y > prim_rect.min.y { + f32::floor((visible_rect.min.y - prim_rect.min.y) / stride.height) + } else { + 0.0 + }; + + let x0 = prim_rect.min.x + nx * stride.width; + let y0 = prim_rect.min.y + ny * stride.height; + + let x_most = visible_rect.max.x; + let y_most = visible_rect.max.y; + + let x_count = f32::ceil((x_most - x0) / stride.width) as i32; + let y_count = f32::ceil((y_most - y0) / stride.height) as i32; + + let mut row_flags = EdgeAaSegmentMask::TOP; + if y_count == 1 { + row_flags |= EdgeAaSegmentMask::BOTTOM; + } + + RepetitionIterator { + current_origin: LayoutPoint::new(x0, y0), + initial_origin: LayoutPoint::new(x0, y0), + current_x: 0, + current_y: 0, + x_count, + y_count, + row_flags, + stride, + } +} + +#[derive(Debug)] +pub struct Tile { + pub rect: LayoutRect, + pub offset: TileOffset, + pub edge_flags: EdgeAaSegmentMask, +} + +#[derive(Debug)] +pub struct TileIteratorExtent { + /// Range of visible tiles to iterate over in number of tiles. + tile_range: Range<i32>, + /// Range of tiles of the full image including tiles that are culled out. + image_tiles: Range<i32>, + /// Size of the first tile in layout space. + first_tile_layout_size: f32, + /// Size of the last tile in layout space. + last_tile_layout_size: f32, + /// Position of blob point (0, 0) in layout space. + layout_tiling_origin: f32, + /// Position of the top-left corner of the primitive rect in layout space. + layout_prim_start: f32, +} + +#[derive(Debug)] +pub struct TileIterator { + current_tile: TileOffset, + x: TileIteratorExtent, + y: TileIteratorExtent, + regular_tile_size: LayoutSize, +} + +impl Iterator for TileIterator { + type Item = Tile; + + fn next(&mut self) -> Option<Self::Item> { + // If we reach the end of a row, reset to the beginning of the next row. + if self.current_tile.x >= self.x.tile_range.end { + self.current_tile.y += 1; + self.current_tile.x = self.x.tile_range.start; + } + + // Stop iterating if we reach the last tile. We may start here if there + // were no tiles to iterate over. + if self.current_tile.x >= self.x.tile_range.end || self.current_tile.y >= self.y.tile_range.end { + return None; + } + + let tile_offset = self.current_tile; + + let mut segment_rect = LayoutRect::from_origin_and_size( + LayoutPoint::new( + self.x.layout_tiling_origin + tile_offset.x as f32 * self.regular_tile_size.width, + self.y.layout_tiling_origin + tile_offset.y as f32 * self.regular_tile_size.height, + ), + self.regular_tile_size, + ); + + let mut edge_flags = EdgeAaSegmentMask::empty(); + + if tile_offset.x == self.x.image_tiles.start { + edge_flags |= EdgeAaSegmentMask::LEFT; + segment_rect.min.x = self.x.layout_prim_start; + // TODO(nical) we may not need to do this. + segment_rect.max.x = segment_rect.min.x + self.x.first_tile_layout_size; + } + if tile_offset.x == self.x.image_tiles.end - 1 { + edge_flags |= EdgeAaSegmentMask::RIGHT; + segment_rect.max.x = segment_rect.min.x + self.x.last_tile_layout_size; + } + + if tile_offset.y == self.y.image_tiles.start { + segment_rect.min.y = self.y.layout_prim_start; + segment_rect.max.y = segment_rect.min.y + self.y.first_tile_layout_size; + edge_flags |= EdgeAaSegmentMask::TOP; + } + if tile_offset.y == self.y.image_tiles.end - 1 { + segment_rect.max.y = segment_rect.min.y + self.y.last_tile_layout_size; + edge_flags |= EdgeAaSegmentMask::BOTTOM; + } + + assert!(tile_offset.y < self.y.tile_range.end); + let tile = Tile { + rect: segment_rect, + offset: tile_offset, + edge_flags, + }; + + self.current_tile.x += 1; + + Some(tile) + } +} + +pub fn tiles( + prim_rect: &LayoutRect, + visible_rect: &LayoutRect, + image_rect: &DeviceIntRect, + device_tile_size: i32, +) -> TileIterator { + // The image resource is tiled. We have to generate an image primitive + // for each tile. + // We need to do this because the image is broken up into smaller tiles in the texture + // cache and the image shader is not able to work with this type of sparse representation. + + // The tiling logic works as follows: + // + // +-#################-+ -+ + // | #//| | |//# | | image size + // | #//| | |//# | | + // +-#--+----+----+--#-+ | -+ + // | #//| | |//# | | | regular tile size + // | #//| | |//# | | | + // +-#--+----+----+--#-+ | -+-+ + // | #//|////|////|//# | | | "leftover" height + // | ################# | -+ ---+ + // +----+----+----+----+ + // + // In the ascii diagram above, a large image is split into tiles of almost regular size. + // The tiles on the edges (hatched in the diagram) can be smaller than the regular tiles + // and are handled separately in the code (we'll call them boundary tiles). + // + // Each generated segment corresponds to a tile in the texture cache, with the + // assumption that the boundary tiles are sized to fit their own irregular size in the + // texture cache. + // + // Because we can have very large virtual images we iterate over the visible portion of + // the image in layer space instead of iterating over all device tiles. + + let visible_rect = match prim_rect.intersection(&visible_rect) { + Some(rect) => rect, + None => { + return TileIterator { + current_tile: TileOffset::zero(), + x: TileIteratorExtent { + tile_range: 0..0, + image_tiles: 0..0, + first_tile_layout_size: 0.0, + last_tile_layout_size: 0.0, + layout_tiling_origin: 0.0, + layout_prim_start: prim_rect.min.x, + }, + y: TileIteratorExtent { + tile_range: 0..0, + image_tiles: 0..0, + first_tile_layout_size: 0.0, + last_tile_layout_size: 0.0, + layout_tiling_origin: 0.0, + layout_prim_start: prim_rect.min.y, + }, + regular_tile_size: LayoutSize::zero(), + } + } + }; + + // Size of regular tiles in layout space. + let layout_tile_size = LayoutSize::new( + device_tile_size as f32 / image_rect.width() as f32 * prim_rect.width(), + device_tile_size as f32 / image_rect.height() as f32 * prim_rect.height(), + ); + + // The decomposition logic is exactly the same on each axis so we reduce + // this to a 1-dimensional problem in an attempt to make the code simpler. + + let x_extent = tiles_1d( + layout_tile_size.width, + visible_rect.x_range(), + prim_rect.min.x, + image_rect.x_range(), + device_tile_size, + ); + + let y_extent = tiles_1d( + layout_tile_size.height, + visible_rect.y_range(), + prim_rect.min.y, + image_rect.y_range(), + device_tile_size, + ); + + TileIterator { + current_tile: point2( + x_extent.tile_range.start, + y_extent.tile_range.start, + ), + x: x_extent, + y: y_extent, + regular_tile_size: layout_tile_size, + } +} + +/// Decompose tiles along an arbitrary axis. +/// +/// This does most of the heavy lifting needed for `tiles` but in a single dimension for +/// the sake of simplicity since the problem is independent on the x and y axes. +fn tiles_1d( + layout_tile_size: f32, + layout_visible_range: Range<f32>, + layout_prim_start: f32, + device_image_range: Range<i32>, + device_tile_size: i32, +) -> TileIteratorExtent { + // A few sanity checks. + debug_assert!(layout_tile_size > 0.0); + debug_assert!(layout_visible_range.end >= layout_visible_range.start); + debug_assert!(device_image_range.end > device_image_range.start); + debug_assert!(device_tile_size > 0); + + // Sizes of the boundary tiles in pixels. + let first_tile_device_size = first_tile_size_1d(&device_image_range, device_tile_size); + let last_tile_device_size = last_tile_size_1d(&device_image_range, device_tile_size); + + // [start..end[ Range of tiles of this row/column (in number of tiles) without + // taking culling into account. + let image_tiles = tile_range_1d(&device_image_range, device_tile_size); + + // Layout offset of tile (0, 0) with respect to the top-left corner of the display item. + let layout_offset = device_image_range.start as f32 * layout_tile_size / device_tile_size as f32; + // Position in layout space of tile (0, 0). + let layout_tiling_origin = layout_prim_start - layout_offset; + + // [start..end[ Range of the visible tiles (because of culling). + let visible_tiles_start = f32::floor((layout_visible_range.start - layout_tiling_origin) / layout_tile_size) as i32; + let visible_tiles_end = f32::ceil((layout_visible_range.end - layout_tiling_origin) / layout_tile_size) as i32; + + // Combine the above two to get the tiles in the image that are visible this frame. + let mut tiles_start = i32::max(image_tiles.start, visible_tiles_start); + let tiles_end = i32::min(image_tiles.end, visible_tiles_end); + if tiles_start > tiles_end { + tiles_start = tiles_end; + } + + // The size in layout space of the boundary tiles. + let first_tile_layout_size = if tiles_start == image_tiles.start { + first_tile_device_size as f32 * layout_tile_size / device_tile_size as f32 + } else { + // boundary tile was culled out, so the new first tile is a regularly sized tile. + layout_tile_size + }; + + // Same here. + let last_tile_layout_size = if tiles_end == image_tiles.end { + last_tile_device_size as f32 * layout_tile_size / device_tile_size as f32 + } else { + layout_tile_size + }; + + TileIteratorExtent { + tile_range: tiles_start..tiles_end, + image_tiles, + first_tile_layout_size, + last_tile_layout_size, + layout_tiling_origin, + layout_prim_start, + } +} + +/// Compute the range of tiles (in number of tiles) that intersect the provided +/// image range (in pixels) in an arbitrary dimension. +/// +/// ```ignore +/// +/// 0 +/// : +/// #-+---+---+---+---+---+--# +/// # | | | | | | # +/// #-+---+---+---+---+---+--# +/// ^ : ^ +/// +/// +------------------------+ image_range +/// +---+ regular_tile_size +/// +/// ``` +fn tile_range_1d( + image_range: &Range<i32>, + regular_tile_size: i32, +) -> Range<i32> { + // Integer division truncates towards zero so with negative values if the first/last + // tile isn't a full tile we can get offset by one which we account for here. + + let mut start = image_range.start / regular_tile_size; + if image_range.start % regular_tile_size < 0 { + start -= 1; + } + + let mut end = image_range.end / regular_tile_size; + if image_range.end % regular_tile_size > 0 { + end += 1; + } + + start..end +} + +// Sizes of the first boundary tile in pixels. +// +// It can be smaller than the regular tile size if the image is not a multiple +// of the regular tile size. +fn first_tile_size_1d( + image_range: &Range<i32>, + regular_tile_size: i32, +) -> i32 { + // We have to account for how the % operation behaves for negative values. + let image_size = image_range.end - image_range.start; + i32::min( + match image_range.start % regular_tile_size { + // . #------+------+ . + // . #//////| | . + 0 => regular_tile_size, + // (zero) -> 0 . #--+------+ . + // . . #//| | . + // %(m): ~~> + m if m > 0 => regular_tile_size - m, + // . . #--+------+ 0 <- (zero) + // . . #//| | . + // %(m): <~~ + m => -m, + }, + image_size + ) +} + +// Sizes of the last boundary tile in pixels. +// +// It can be smaller than the regular tile size if the image is not a multiple +// of the regular tile size. +fn last_tile_size_1d( + image_range: &Range<i32>, + regular_tile_size: i32, +) -> i32 { + // We have to account for how the modulo operation behaves for negative values. + let image_size = image_range.end - image_range.start; + i32::min( + match image_range.end % regular_tile_size { + // +------+------# . + // tiles: . | |//////# . + 0 => regular_tile_size, + // . +------+--# . 0 <- (zero) + // . | |//# . . + // modulo (m): <~~ + m if m < 0 => regular_tile_size + m, + // (zero) -> 0 +------+--# . . + // . | |//# . . + // modulo (m): ~~> + m => m, + }, + image_size, + ) +} + +pub fn compute_tile_rect( + image_rect: &DeviceIntRect, + regular_tile_size: TileSize, + tile: TileOffset, +) -> DeviceIntRect { + let regular_tile_size = regular_tile_size as i32; + DeviceIntRect::from_origin_and_size( + point2( + compute_tile_origin_1d(image_rect.x_range(), regular_tile_size, tile.x as i32), + compute_tile_origin_1d(image_rect.y_range(), regular_tile_size, tile.y as i32), + ), + size2( + compute_tile_size_1d(image_rect.x_range(), regular_tile_size, tile.x as i32), + compute_tile_size_1d(image_rect.y_range(), regular_tile_size, tile.y as i32), + ), + ) +} + +fn compute_tile_origin_1d( + img_range: Range<i32>, + regular_tile_size: i32, + tile_offset: i32, +) -> i32 { + let tile_range = tile_range_1d(&img_range, regular_tile_size); + if tile_offset == tile_range.start { + img_range.start + } else { + tile_offset * regular_tile_size + } +} + +// Compute the width and height in pixels of a tile depending on its position in the image. +pub fn compute_tile_size( + image_rect: &DeviceIntRect, + regular_tile_size: TileSize, + tile: TileOffset, +) -> DeviceIntSize { + let regular_tile_size = regular_tile_size as i32; + size2( + compute_tile_size_1d(image_rect.x_range(), regular_tile_size, tile.x as i32), + compute_tile_size_1d(image_rect.y_range(), regular_tile_size, tile.y as i32), + ) +} + +fn compute_tile_size_1d( + img_range: Range<i32>, + regular_tile_size: i32, + tile_offset: i32, +) -> i32 { + let tile_range = tile_range_1d(&img_range, regular_tile_size); + + // Most tiles are going to have base_size as width and height, + // except for tiles around the edges that are shrunk to fit the image data. + let actual_size = if tile_offset == tile_range.start { + first_tile_size_1d(&img_range, regular_tile_size) + } else if tile_offset == tile_range.end - 1 { + last_tile_size_1d(&img_range, regular_tile_size) + } else { + regular_tile_size + }; + + assert!(actual_size > 0); + + actual_size +} + +pub fn compute_tile_range( + visible_area: &DeviceIntRect, + tile_size: u16, +) -> TileRange { + let tile_size = tile_size as i32; + let x_range = tile_range_1d(&visible_area.x_range(), tile_size); + let y_range = tile_range_1d(&visible_area.y_range(), tile_size); + + TileRange { + min: point2(x_range.start, y_range.start), + max: point2(x_range.end, y_range.end), + } +} + +pub fn for_each_tile_in_range( + range: &TileRange, + mut callback: impl FnMut(TileOffset), +) { + for y in range.y_range() { + for x in range.x_range() { + callback(point2(x, y)); + } + } +} + +pub fn compute_valid_tiles_if_bounds_change( + prev_rect: &DeviceIntRect, + new_rect: &DeviceIntRect, + tile_size: u16, +) -> Option<TileRange> { + let intersection = match prev_rect.intersection(new_rect) { + Some(rect) => rect, + None => { + return Some(TileRange::zero()); + } + }; + + let left = prev_rect.min.x != new_rect.min.x; + let right = prev_rect.max.x != new_rect.max.x; + let top = prev_rect.min.y != new_rect.min.y; + let bottom = prev_rect.max.y != new_rect.max.y; + + if !left && !right && !top && !bottom { + // Bounds have not changed. + return None; + } + + let tw = 1.0 / (tile_size as f32); + let th = 1.0 / (tile_size as f32); + + let tiles = intersection + .cast::<f32>() + .scale(tw, th); + + let min_x = if left { f32::ceil(tiles.min.x) } else { f32::floor(tiles.min.x) }; + let min_y = if top { f32::ceil(tiles.min.y) } else { f32::floor(tiles.min.y) }; + let max_x = if right { f32::floor(tiles.max.x) } else { f32::ceil(tiles.max.x) }; + let max_y = if bottom { f32::floor(tiles.max.y) } else { f32::ceil(tiles.max.y) }; + + Some(TileRange { + min: point2(min_x as i32, min_y as i32), + max: point2(max_x as i32, max_y as i32), + }) +} + +#[cfg(test)] +mod tests { + use super::*; + use std::collections::HashSet; + use euclid::rect; + + // this checks some additional invariants + fn checked_for_each_tile( + prim_rect: &LayoutRect, + visible_rect: &LayoutRect, + device_image_rect: &DeviceIntRect, + device_tile_size: i32, + callback: &mut dyn FnMut(&LayoutRect, TileOffset, EdgeAaSegmentMask), + ) { + let mut coverage = LayoutRect::zero(); + let mut seen_tiles = HashSet::new(); + for tile in tiles( + prim_rect, + visible_rect, + device_image_rect, + device_tile_size, + ) { + // make sure we don't get sent duplicate tiles + assert!(!seen_tiles.contains(&tile.offset)); + seen_tiles.insert(tile.offset); + coverage = coverage.union(&tile.rect); + assert!(prim_rect.contains_box(&tile.rect)); + callback(&tile.rect, tile.offset, tile.edge_flags); + } + assert!(prim_rect.contains_box(&coverage)); + assert!(coverage.contains_box(&visible_rect.intersection(&prim_rect).unwrap_or(LayoutRect::zero()))); + } + + #[test] + fn basic() { + let mut count = 0; + checked_for_each_tile(&rect(0., 0., 1000., 1000.).to_box2d(), + &rect(75., 75., 400., 400.).to_box2d(), + &rect(0, 0, 400, 400).to_box2d(), + 36, + &mut |_tile_rect, _tile_offset, _tile_flags| { + count += 1; + }, + ); + assert_eq!(count, 36); + } + + #[test] + fn empty() { + let mut count = 0; + checked_for_each_tile(&rect(0., 0., 74., 74.).to_box2d(), + &rect(75., 75., 400., 400.).to_box2d(), + &rect(0, 0, 400, 400).to_box2d(), + 36, + &mut |_tile_rect, _tile_offset, _tile_flags| { + count += 1; + }, + ); + assert_eq!(count, 0); + } + + #[test] + fn test_tiles_1d() { + // Exactly one full tile at positive offset. + let result = tiles_1d(64.0, -10000.0..10000.0, 0.0, 0..64, 64); + assert_eq!(result.tile_range.start, 0); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 64.0); + assert_eq!(result.last_tile_layout_size, 64.0); + + // Exactly one full tile at negative offset. + let result = tiles_1d(64.0, -10000.0..10000.0, -64.0, -64..0, 64); + assert_eq!(result.tile_range.start, -1); + assert_eq!(result.tile_range.end, 0); + assert_eq!(result.first_tile_layout_size, 64.0); + assert_eq!(result.last_tile_layout_size, 64.0); + + // Two full tiles at negative and positive offsets. + let result = tiles_1d(64.0, -10000.0..10000.0, -64.0, -64..64, 64); + assert_eq!(result.tile_range.start, -1); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 64.0); + assert_eq!(result.last_tile_layout_size, 64.0); + + // One partial tile at positive offset, non-zero origin, culled out. + let result = tiles_1d(64.0, -100.0..10.0, 64.0, 64..310, 64); + assert_eq!(result.tile_range.start, result.tile_range.end); + + // Two tiles at negative and positive offsets, one of which is culled out. + // The remaining tile is partially culled but it should still generate a full tile. + let result = tiles_1d(64.0, 10.0..10000.0, -64.0, -64..64, 64); + assert_eq!(result.tile_range.start, 0); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 64.0); + assert_eq!(result.last_tile_layout_size, 64.0); + let result = tiles_1d(64.0, -10000.0..-10.0, -64.0, -64..64, 64); + assert_eq!(result.tile_range.start, -1); + assert_eq!(result.tile_range.end, 0); + assert_eq!(result.first_tile_layout_size, 64.0); + assert_eq!(result.last_tile_layout_size, 64.0); + + // Stretched tile in layout space device tile size is 64 and layout tile size is 128. + // So the resulting tile sizes in layout space should be multiplied by two. + let result = tiles_1d(128.0, -10000.0..10000.0, -64.0, -64..32, 64); + assert_eq!(result.tile_range.start, -1); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 128.0); + assert_eq!(result.last_tile_layout_size, 64.0); + + // Two visible tiles (the rest is culled out). + let result = tiles_1d(10.0, 0.0..20.0, 0.0, 0..64, 64); + assert_eq!(result.tile_range.start, 0); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 10.0); + assert_eq!(result.last_tile_layout_size, 10.0); + + // Two visible tiles at negative layout offsets (the rest is culled out). + let result = tiles_1d(10.0, -20.0..0.0, -20.0, 0..64, 64); + assert_eq!(result.tile_range.start, 0); + assert_eq!(result.tile_range.end, 1); + assert_eq!(result.first_tile_layout_size, 10.0); + assert_eq!(result.last_tile_layout_size, 10.0); + } + + #[test] + fn test_tile_range_1d() { + assert_eq!(tile_range_1d(&(0..256), 256), 0..1); + assert_eq!(tile_range_1d(&(0..257), 256), 0..2); + assert_eq!(tile_range_1d(&(-1..257), 256), -1..2); + assert_eq!(tile_range_1d(&(-256..256), 256), -1..1); + assert_eq!(tile_range_1d(&(-20..-10), 6), -4..-1); + assert_eq!(tile_range_1d(&(20..100), 256), 0..1); + } + + #[test] + fn test_first_last_tile_size_1d() { + assert_eq!(first_tile_size_1d(&(0..10), 64), 10); + assert_eq!(first_tile_size_1d(&(-20..0), 64), 20); + + assert_eq!(last_tile_size_1d(&(0..10), 64), 10); + assert_eq!(last_tile_size_1d(&(-20..0), 64), 20); + } + + #[test] + fn doubly_partial_tiles() { + // In the following tests the image is a single tile and none of the sides of the tile + // align with the tile grid. + // This can only happen when we have a single non-aligned partial tile and no regular + // tiles. + assert_eq!(first_tile_size_1d(&(300..310), 64), 10); + assert_eq!(first_tile_size_1d(&(-20..-10), 64), 10); + + assert_eq!(last_tile_size_1d(&(300..310), 64), 10); + assert_eq!(last_tile_size_1d(&(-20..-10), 64), 10); + + + // One partial tile at positve offset, non-zero origin. + let result = tiles_1d(64.0, -10000.0..10000.0, 0.0, 300..310, 64); + assert_eq!(result.tile_range.start, 4); + assert_eq!(result.tile_range.end, 5); + assert_eq!(result.first_tile_layout_size, 10.0); + assert_eq!(result.last_tile_layout_size, 10.0); + } + + #[test] + fn smaller_than_tile_size_at_origin() { + let r = compute_tile_rect( + &rect(0, 0, 80, 80).to_box2d(), + 256, + point2(0, 0), + ); + + assert_eq!(r, rect(0, 0, 80, 80).to_box2d()); + } + + #[test] + fn smaller_than_tile_size_with_offset() { + let r = compute_tile_rect( + &rect(20, 20, 80, 80).to_box2d(), + 256, + point2(0, 0), + ); + + assert_eq!(r, rect(20, 20, 80, 80).to_box2d()); + } +} |