use std::collections::hash_map::DefaultHasher;
use std::fmt::Write;
use std::hash::Hasher;
use geom::{PolyLine, Polygon};
use crate::assets::Assets;
use crate::{
svg, Color, DeferDraw, EventCtx, GeomBatch, JustDraw, MultiKey, Prerender, ScreenDims, Widget,
};
pub const DEFAULT_FONT: Font = Font::OverpassRegular;
pub const DEFAULT_FONT_SIZE: usize = 21;
const DEFAULT_FG_COLOR: Color = Color::WHITE;
pub const BG_COLOR: Color = Color::grey(0.3);
pub const SELECTED_COLOR: Color = Color::grey(0.5);
pub const INACTIVE_CHOICE_COLOR: Color = Color::grey(0.8);
pub const SCALE_LINE_HEIGHT: f64 = 1.2;
pub const MAX_CHAR_WIDTH: f64 = 25.0;
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub enum Font {
BungeeInlineRegular,
BungeeRegular,
OverpassBold,
OverpassRegular,
OverpassSemiBold,
OverpassMonoBold,
ZcoolXiaoWei,
}
impl Font {
pub fn family(self) -> &'static str {
match self {
Font::BungeeInlineRegular => "Bungee Inline",
Font::BungeeRegular => "Bungee",
Font::OverpassBold => "Overpass",
Font::OverpassRegular => "Overpass",
Font::OverpassSemiBold => "Overpass",
Font::OverpassMonoBold => "Overpass Mono",
Font::ZcoolXiaoWei => "ZCOOL XiaoWei",
}
}
}
#[derive(Debug, Clone)]
pub struct TextSpan {
text: String,
fg_color: Color,
size: usize,
font: Font,
underlined: bool,
}
impl TextSpan {
pub fn fg(mut self, color: Color) -> TextSpan {
assert_eq!(self.fg_color, DEFAULT_FG_COLOR);
self.fg_color = color;
self
}
pub fn maybe_fg(mut self, color: Option<Color>) -> TextSpan {
assert_eq!(self.fg_color, DEFAULT_FG_COLOR);
if let Some(c) = color {
self.fg_color = c;
}
self
}
pub fn draw(self, ctx: &EventCtx) -> Widget {
Text::from(self).draw(ctx)
}
pub fn batch(self, ctx: &EventCtx) -> Widget {
Text::from(self).batch(ctx)
}
pub fn display_title(mut self) -> TextSpan {
self.font = Font::BungeeInlineRegular;
self.size = 64;
self
}
pub fn big_heading_styled(mut self) -> TextSpan {
self.font = Font::BungeeRegular;
self.size = 32;
self
}
pub fn big_heading_plain(mut self) -> TextSpan {
self.font = Font::OverpassBold;
self.size = 32;
self
}
pub fn small_heading(mut self) -> TextSpan {
self.font = Font::OverpassSemiBold;
self.size = 26;
self
}
pub fn body(mut self) -> TextSpan {
self.font = Font::OverpassRegular;
self.size = 21;
self
}
pub fn secondary(mut self) -> TextSpan {
self.font = Font::OverpassRegular;
self.size = 21;
self.fg_color = Color::hex("#A3A3A3");
self
}
pub fn small(mut self) -> TextSpan {
self.font = Font::OverpassRegular;
self.size = 16;
self
}
pub fn big_monospaced(mut self) -> TextSpan {
self.font = Font::OverpassMonoBold;
self.size = 32;
self
}
pub fn small_monospaced(mut self) -> TextSpan {
self.font = Font::OverpassMonoBold;
self.size = 16;
self
}
pub fn underlined(mut self) -> TextSpan {
self.underlined = true;
self
}
}
#[allow(non_snake_case)]
pub fn Line<S: Into<String>>(text: S) -> TextSpan {
TextSpan {
text: text.into(),
fg_color: DEFAULT_FG_COLOR,
size: DEFAULT_FONT_SIZE,
font: DEFAULT_FONT,
underlined: false,
}
}
#[derive(Debug, Clone)]
pub struct Text {
lines: Vec<(Option<Color>, Vec<TextSpan>)>,
bg_color: Option<Color>,
}
impl Text {
pub fn new() -> Text {
Text {
lines: Vec::new(),
bg_color: None,
}
}
pub fn from(line: TextSpan) -> Text {
let mut txt = Text::new();
txt.add(line);
txt
}
pub fn from_all(lines: Vec<TextSpan>) -> Text {
let mut txt = Text::new();
for l in lines {
txt.append(l);
}
txt
}
pub fn from_multiline(lines: Vec<TextSpan>) -> Text {
let mut txt = Text::new();
for l in lines {
txt.add(l);
}
txt
}
pub fn with_bg(mut self) -> Text {
assert!(self.bg_color.is_none());
self.bg_color = Some(BG_COLOR);
self
}
pub fn bg(mut self, bg: Color) -> Text {
assert!(self.bg_color.is_none());
self.bg_color = Some(bg);
self
}
pub fn tooltip<MK: Into<Option<MultiKey>>>(ctx: &EventCtx, hotkey: MK, action: &str) -> Text {
if let Some(ref key) = hotkey.into() {
Text::from_all(vec![
Line(key.describe()).fg(ctx.style().hotkey_color).small(),
Line(format!(" - {}", action)).small(),
])
} else {
Text::from(Line(action).small())
}
}
pub fn change_fg(mut self, fg: Color) -> Text {
for (_, spans) in self.lines.iter_mut() {
for span in spans {
span.fg_color = fg;
}
}
self
}
pub fn add(&mut self, line: TextSpan) {
self.lines.push((None, vec![line]));
}
pub fn add_highlighted(&mut self, line: TextSpan, highlight: Color) {
self.lines.push((Some(highlight), vec![line]));
}
pub(crate) fn highlight_last_line(&mut self, highlight: Color) {
self.lines.last_mut().unwrap().0 = Some(highlight);
}
pub fn append(&mut self, line: TextSpan) {
if self.lines.is_empty() {
self.add(line);
return;
}
let last = self.lines.last().unwrap().1.last().unwrap();
assert_eq!(line.size, last.size);
assert_eq!(line.font, last.font);
self.lines.last_mut().unwrap().1.push(line);
}
pub fn add_appended(&mut self, lines: Vec<TextSpan>) {
for (idx, l) in lines.into_iter().enumerate() {
if idx == 0 {
self.add(l);
} else {
self.append(l);
}
}
}
pub fn append_all(&mut self, lines: Vec<TextSpan>) {
for l in lines {
self.append(l);
}
}
pub fn is_empty(&self) -> bool {
self.lines.is_empty()
}
pub fn extend(&mut self, other: Text) {
self.lines.extend(other.lines);
}
pub(crate) fn dims(self, assets: &Assets) -> ScreenDims {
self.render(assets).get_dims()
}
pub fn render<A: AsRef<Assets>>(self, assets: &A) -> GeomBatch {
let assets: &Assets = assets.as_ref();
self.inner_render(assets, svg::HIGH_QUALITY)
}
pub(crate) fn inner_render(self, assets: &Assets, tolerance: f32) -> GeomBatch {
let hash_key = self.hash_key();
if let Some(batch) = assets.get_cached_text(&hash_key) {
return batch;
}
let mut output_batch = GeomBatch::new();
let mut master_batch = GeomBatch::new();
let mut y = 0.0;
let mut max_width = 0.0_f64;
for (line_color, line) in self.lines {
let line_height = assets.line_height(line[0].font, line[0].size);
let line_batch = render_line(line, tolerance, assets);
let line_dims = if line_batch.is_empty() {
ScreenDims::new(0.0, line_height)
} else {
ScreenDims::new(line_batch.get_dims().width + 5.0, line_height)
};
if let Some(c) = line_color {
master_batch.push(
c,
Polygon::rectangle(line_dims.width, line_dims.height).translate(0.0, y),
);
}
y += line_dims.height;
let offset = line_height / SCALE_LINE_HEIGHT * 0.2;
master_batch.append(line_batch.translate(0.0, y - offset));
max_width = max_width.max(line_dims.width);
}
if let Some(c) = self.bg_color {
output_batch.push(c, Polygon::rectangle(max_width, y));
}
output_batch.append(master_batch);
output_batch.autocrop_dims = false;
assets.cache_text(hash_key, output_batch.clone());
output_batch
}
pub fn render_autocropped<A: AsRef<Assets>>(self, assets: &A) -> GeomBatch {
let mut batch = self.render(assets);
batch.autocrop_dims = true;
batch.autocrop()
}
fn hash_key(&self) -> String {
let mut hasher = DefaultHasher::new();
hasher.write(format!("{:?}", self).as_ref());
format!("{:x}", hasher.finish())
}
pub fn draw(self, ctx: &EventCtx) -> Widget {
JustDraw::wrap(ctx, self.render(ctx))
}
pub fn batch(self, ctx: &EventCtx) -> Widget {
DeferDraw::new(self.render(ctx))
}
pub fn wrap_to_pct(self, ctx: &EventCtx, pct: usize) -> Text {
self.inner_wrap_to_pct(
(pct as f64) / 100.0 * ctx.canvas.window_width,
&ctx.prerender.assets,
)
}
pub(crate) fn inner_wrap_to_pct(mut self, limit: f64, assets: &Assets) -> Text {
let mut lines = Vec::new();
for (bg, spans) in self.lines.drain(..) {
if render_line(spans.clone(), svg::LOW_QUALITY, assets)
.get_dims()
.width
< limit
{
lines.push((bg, spans));
continue;
}
let mut width_left = limit;
let mut current_line = Vec::new();
for span in spans {
let mut current_span = span.clone();
current_span.text = String::new();
for word in span.text.split_whitespace() {
let width = render_line(
vec![TextSpan {
text: word.to_string(),
size: span.size,
font: span.font,
fg_color: span.fg_color,
underlined: false,
}],
svg::LOW_QUALITY,
assets,
)
.get_dims()
.width;
if width_left > width {
current_span.text.push(' ');
current_span.text.push_str(word);
width_left -= width;
} else {
current_line.push(current_span);
lines.push((bg, current_line.drain(..).collect()));
current_span = span.clone();
current_span.text = word.to_string();
width_left = limit;
}
}
if !current_span.text.is_empty() {
current_line.push(current_span);
}
}
if !current_line.is_empty() {
lines.push((bg, current_line));
}
}
self.lines = lines;
self
}
}
fn render_line(spans: Vec<TextSpan>, tolerance: f32, assets: &Assets) -> GeomBatch {
let mut svg = r##"<svg width="9999" height="9999" viewBox="0 0 9999 9999" xmlns="http://www.w3.org/2000/svg">"##.to_string();
write!(
&mut svg,
r##"<text x="0" y="0" xml:space="preserve" font-size="{}" font-family="{}" {}>"##,
spans[0].size,
spans[0].font.family(),
match spans[0].font {
Font::OverpassBold => "font-weight=\"bold\"",
Font::OverpassSemiBold => "font-weight=\"600\"",
_ => "",
}
)
.unwrap();
let mut contents = String::new();
for span in spans {
write!(
&mut contents,
r##"<tspan fill="{}" {}>{}</tspan>"##,
span.fg_color.to_hex(),
if span.underlined {
"text-decoration=\"underline\""
} else {
""
},
htmlescape::encode_minimal(&span.text)
)
.unwrap();
}
write!(&mut svg, "{}</text></svg>", contents).unwrap();
let svg_tree = match usvg::Tree::from_str(&svg, &assets.text_opts) {
Ok(t) => t,
Err(err) => panic!("render_line({}): {}", contents, err),
};
let mut batch = GeomBatch::new();
match crate::svg::add_svg_inner(&mut batch, svg_tree, tolerance) {
Ok(_) => batch,
Err(err) => panic!("render_line({}): {}", contents, err),
}
}
pub trait TextExt {
fn draw_text(self, ctx: &EventCtx) -> Widget;
fn batch_text(self, ctx: &EventCtx) -> Widget;
}
impl TextExt for &str {
fn draw_text(self, ctx: &EventCtx) -> Widget {
Line(self).draw(ctx)
}
fn batch_text(self, ctx: &EventCtx) -> Widget {
Line(self).batch(ctx)
}
}
impl TextExt for String {
fn draw_text(self, ctx: &EventCtx) -> Widget {
Line(self).draw(ctx)
}
fn batch_text(self, ctx: &EventCtx) -> Widget {
Line(self).batch(ctx)
}
}
impl TextSpan {
pub fn render_curvey(self, prerender: &Prerender, path: &PolyLine, scale: f64) -> GeomBatch {
let assets = &prerender.assets;
let tolerance = svg::HIGH_QUALITY;
let mut svg = r##"<svg width="9999" height="9999" viewBox="0 0 9999 9999" xmlns="http://www.w3.org/2000/svg">"##.to_string();
write!(
&mut svg,
r##"<path id="txtpath" fill="none" stroke="none" d=""##
)
.unwrap();
write!(
&mut svg,
"M {} {}",
path.points()[0].x(),
path.points()[0].y()
)
.unwrap();
for pt in path.points().into_iter().skip(1) {
write!(&mut svg, " L {} {}", pt.x(), pt.y()).unwrap();
}
write!(&mut svg, "\" />").unwrap();
let start_offset = (path.length() / 2.0).inner_meters()
- (Text::from(Line(&self.text)).dims(assets).width * scale) / 2.0;
write!(
&mut svg,
r##"<text xml:space="preserve" font-size="{}" font-family="{}" {} fill="{}" startOffset="{}">"##,
(self.size as f64) * scale,
self.font.family(),
match self.font {
Font::OverpassBold => "font-weight=\"bold\"",
Font::OverpassSemiBold => "font-weight=\"600\"",
_ => "",
},
self.fg_color.to_hex(),
start_offset,
)
.unwrap();
write!(
&mut svg,
r##"<textPath href="#txtpath">{}</textPath></text></svg>"##,
self.text
)
.unwrap();
let svg_tree = match usvg::Tree::from_str(&svg, &assets.text_opts) {
Ok(t) => t,
Err(err) => panic!("curvey({}): {}", self.text, err),
};
let mut batch = GeomBatch::new();
match crate::svg::add_svg_inner(&mut batch, svg_tree, tolerance) {
Ok(_) => batch,
Err(err) => panic!("curvey({}): {}", self.text, err),
}
}
}