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ruffle/swf/src/write.rs

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#![allow(
clippy::cognitive_complexity,
clippy::float_cmp,
clippy::inconsistent_digit_grouping,
clippy::unreadable_literal
)]
use crate::error::{Error, Result};
use crate::tag_code::TagCode;
use crate::types::*;
use byteorder::{LittleEndian, WriteBytesExt};
use enumset::EnumSet;
use std::cmp::max;
use std::io::{self, Write};
/// Writes an SWF file to an output stream.
/// # Example
/// ```
/// use swf::*;
///
/// let swf = Swf {
/// header: Header {
/// version: 6,
/// compression: Compression::Zlib,
/// stage_size: Rectangle { x_min: Twips::from_pixels(0.0), x_max: Twips::from_pixels(400.0), y_min: Twips::from_pixels(0.0), y_max: Twips::from_pixels(400.0) },
/// frame_rate: 60.0,
/// num_frames: 1,
/// },
/// tags: vec![
/// Tag::SetBackgroundColor(Color { r: 255, g: 0, b: 0, a: 255 }),
/// Tag::ShowFrame
/// ]
/// };
/// let output = Vec::new();
/// swf::write_swf(&swf, output).unwrap();
/// ```
pub fn write_swf<W: Write>(swf: &Swf, mut output: W) -> Result<()> {
let signature = match swf.header.compression {
Compression::None => b"FWS",
Compression::Zlib => b"CWS",
Compression::Lzma => b"ZWS",
};
output.write_all(&signature[..])?;
output.write_u8(swf.header.version)?;
// Write SWF body.
let mut swf_body = Vec::new();
{
let mut writer = Writer::new(&mut swf_body, swf.header.version);
writer.write_rectangle(&swf.header.stage_size)?;
writer.write_fixed8(swf.header.frame_rate)?;
writer.write_u16(swf.header.num_frames)?;
// Write main timeline tag list.
writer.write_tag_list(&swf.tags)?;
}
// Write SWF header.
// Uncompressed SWF length.
output.write_u32::<LittleEndian>(swf_body.len() as u32 + 8)?;
// Compress SWF body.
match swf.header.compression {
Compression::None => {
output.write_all(&swf_body)?;
}
Compression::Zlib => write_zlib_swf(&mut output, &swf_body)?,
// LZMA header.
// SWF format has a mangled LZMA header, so we have to do some magic to convert the
// standard LZMA header to SWF format.
// https://adobe.ly/2s8oYzn
Compression::Lzma => write_lzma_swf(&mut output, &swf_body)?,
};
Ok(())
}
#[cfg(feature = "flate2")]
fn write_zlib_swf<W: Write>(mut output: W, swf_body: &[u8]) -> Result<()> {
use flate2::write::ZlibEncoder;
use flate2::Compression;
let mut encoder = ZlibEncoder::new(&mut output, Compression::best());
encoder.write_all(&swf_body)?;
encoder.finish()?;
Ok(())
}
#[cfg(all(feature = "libflate", not(feature = "flate2")))]
fn write_zlib_swf<W: Write>(mut output: W, swf_body: &[u8]) -> Result<()> {
use libflate::zlib::Encoder;
let mut encoder = Encoder::new(&mut output)?;
encoder.write_all(&swf_body)?;
encoder.finish().into_result()?;
Ok(())
}
#[cfg(not(any(feature = "flate2", feature = "libflate")))]
fn write_zlib_swf<W: Write>(_output: W, _swf_body: &[u8]) -> Result<()> {
Err(Error::unsupported(
"Support for Zlib compressed SWFs is not enabled.",
))
}
#[cfg(feature = "lzma")]
fn write_lzma_swf<W: Write>(mut output: W, swf_body: &[u8]) -> Result<()> {
use xz2::{
stream::{Action, LzmaOptions, Stream},
write::XzEncoder,
};
let mut stream = Stream::new_lzma_encoder(&LzmaOptions::new_preset(9).unwrap()).unwrap();
let mut lzma_header = [0; 13];
stream.process(&[], &mut lzma_header, Action::Run).unwrap();
// Compressed length. We just write out a dummy value.
output.write_u32::<LittleEndian>(0xffffffff)?;
output.write_all(&lzma_header[0..5])?; // LZMA property bytes.
let mut encoder = XzEncoder::new_stream(&mut output, stream);
encoder.write_all(&swf_body)?;
Ok(())
}
#[cfg(not(feature = "lzma"))]
fn write_lzma_swf<W: Write>(_output: W, _swf_body: &[u8]) -> Result<()> {
Err(Error::unsupported(
"Support for LZMA compressed SWFs is not enabled.",
))
}
pub trait SwfWrite<W: Write> {
fn get_inner(&mut self) -> &mut W;
fn write_u8(&mut self, n: u8) -> io::Result<()> {
self.get_inner().write_u8(n)
}
fn write_u16(&mut self, n: u16) -> io::Result<()> {
self.get_inner().write_u16::<LittleEndian>(n)
}
fn write_u32(&mut self, n: u32) -> io::Result<()> {
self.get_inner().write_u32::<LittleEndian>(n)
}
fn write_u64(&mut self, n: u64) -> io::Result<()> {
self.get_inner().write_u64::<LittleEndian>(n)
}
fn write_i8(&mut self, n: i8) -> io::Result<()> {
self.get_inner().write_i8(n)
}
fn write_i16(&mut self, n: i16) -> io::Result<()> {
self.get_inner().write_i16::<LittleEndian>(n)
}
fn write_i32(&mut self, n: i32) -> io::Result<()> {
self.get_inner().write_i32::<LittleEndian>(n)
}
fn write_fixed8(&mut self, n: f32) -> io::Result<()> {
self.write_i16((n * 256f32) as i16)
}
fn write_fixed16(&mut self, n: f64) -> io::Result<()> {
self.write_i32((n * 65536f64) as i32)
}
fn write_f32(&mut self, n: f32) -> io::Result<()> {
self.get_inner().write_f32::<LittleEndian>(n)
}
fn write_f64(&mut self, n: f64) -> io::Result<()> {
// Flash weirdly stores f64 as two LE 32-bit chunks.
// First word is the hi-word, second word is the lo-word.
let mut num = [0u8; 8];
(&mut num[..]).write_f64::<LittleEndian>(n)?;
num.swap(0, 4);
num.swap(1, 5);
num.swap(2, 6);
num.swap(3, 7);
self.get_inner().write_all(&num)
}
fn write_c_string(&mut self, s: &str) -> io::Result<()> {
self.get_inner().write_all(s.as_bytes())?;
self.write_u8(0)
}
}
struct Writer<W: Write> {
pub output: W,
pub version: u8,
pub byte: u8,
pub bit_index: u8,
pub num_fill_bits: u8,
pub num_line_bits: u8,
}
impl<W: Write> SwfWrite<W> for Writer<W> {
fn get_inner(&mut self) -> &mut W {
&mut self.output
}
fn write_u8(&mut self, n: u8) -> io::Result<()> {
self.flush_bits()?;
self.output.write_u8(n)
}
fn write_u16(&mut self, n: u16) -> io::Result<()> {
self.flush_bits()?;
self.output.write_u16::<LittleEndian>(n)
}
fn write_u32(&mut self, n: u32) -> io::Result<()> {
self.flush_bits()?;
self.output.write_u32::<LittleEndian>(n)
}
fn write_i8(&mut self, n: i8) -> io::Result<()> {
self.flush_bits()?;
self.output.write_i8(n)
}
fn write_i16(&mut self, n: i16) -> io::Result<()> {
self.flush_bits()?;
self.output.write_i16::<LittleEndian>(n)
}
fn write_i32(&mut self, n: i32) -> io::Result<()> {
self.flush_bits()?;
self.output.write_i32::<LittleEndian>(n)
}
fn write_f32(&mut self, n: f32) -> io::Result<()> {
self.flush_bits()?;
self.output.write_f32::<LittleEndian>(n)
}
fn write_f64(&mut self, n: f64) -> io::Result<()> {
self.flush_bits()?;
self.output.write_f64::<LittleEndian>(n)
}
fn write_c_string(&mut self, s: &str) -> io::Result<()> {
self.flush_bits()?;
self.get_inner().write_all(s.as_bytes())?;
self.write_u8(0)
}
}
impl<W: Write> Writer<W> {
fn new(output: W, version: u8) -> Writer<W> {
Writer {
output,
version,
byte: 0,
bit_index: 8,
num_fill_bits: 0,
num_line_bits: 0,
}
}
#[allow(dead_code)]
fn into_inner(self) -> W {
self.output
}
fn write_bit(&mut self, set: bool) -> Result<()> {
self.bit_index -= 1;
if set {
self.byte |= 1 << self.bit_index;
}
if self.bit_index == 0 {
self.flush_bits()?;
}
Ok(())
}
fn flush_bits(&mut self) -> io::Result<()> {
if self.bit_index != 8 {
self.output.write_u8(self.byte)?;
self.bit_index = 8;
self.byte = 0;
}
Ok(())
}
fn write_ubits(&mut self, num_bits: u8, n: u32) -> Result<()> {
for i in 0..num_bits {
self.write_bit(n & (1 << u32::from(num_bits - i - 1)) != 0)?;
}
Ok(())
}
fn write_sbits(&mut self, num_bits: u8, n: i32) -> Result<()> {
self.write_ubits(num_bits, n as u32)
}
fn write_sbits_twips(&mut self, num_bits: u8, twips: Twips) -> Result<()> {
self.write_sbits(num_bits, twips.get())
}
fn write_fbits(&mut self, num_bits: u8, n: f32) -> Result<()> {
self.write_sbits(num_bits, (n * 65536f32) as i32)
}
fn write_encoded_u32(&mut self, mut n: u32) -> Result<()> {
loop {
let mut byte = (n & 0b01111111) as u8;
n >>= 7;
if n != 0 {
byte |= 0b10000000;
}
self.write_u8(byte)?;
if n == 0 {
break;
}
}
Ok(())
}
fn write_rectangle(&mut self, rectangle: &Rectangle) -> Result<()> {
self.flush_bits()?;
let num_bits: u8 = [
rectangle.x_min,
rectangle.x_max,
rectangle.y_min,
rectangle.y_max,
]
.iter()
.map(|x| count_sbits_twips(*x))
.max()
.unwrap();
self.write_ubits(5, num_bits.into())?;
self.write_sbits_twips(num_bits, rectangle.x_min)?;
self.write_sbits_twips(num_bits, rectangle.x_max)?;
self.write_sbits_twips(num_bits, rectangle.y_min)?;
self.write_sbits_twips(num_bits, rectangle.y_max)?;
Ok(())
}
fn write_character_id(&mut self, id: CharacterId) -> Result<()> {
self.write_u16(id)?;
Ok(())
}
fn write_rgb(&mut self, color: &Color) -> Result<()> {
self.write_u8(color.r)?;
self.write_u8(color.g)?;
self.write_u8(color.b)?;
Ok(())
}
fn write_rgba(&mut self, color: &Color) -> Result<()> {
self.write_u8(color.r)?;
self.write_u8(color.g)?;
self.write_u8(color.b)?;
self.write_u8(color.a)?;
Ok(())
}
fn write_color_transform_no_alpha(&mut self, color_transform: &ColorTransform) -> Result<()> {
// TODO: Assert that alpha is 1.0?
self.flush_bits()?;
let has_mult = color_transform.r_multiply != 1f32
|| color_transform.g_multiply != 1f32
|| color_transform.b_multiply != 1f32;
let has_add =
color_transform.r_add != 0 || color_transform.g_add != 0 || color_transform.b_add != 0;
let multiply = [
color_transform.r_multiply,
color_transform.g_multiply,
color_transform.b_multiply,
];
let add = [
color_transform.a_add,
color_transform.g_add,
color_transform.b_add,
color_transform.a_add,
];
self.write_bit(has_mult)?;
self.write_bit(has_add)?;
let mut num_bits = if has_mult {
multiply
.iter()
.map(|n| count_sbits((*n * 256f32) as i32))
.max()
.unwrap()
} else {
0u8
};
if has_add {
num_bits = max(
num_bits,
add.iter()
.map(|n| count_sbits(i32::from(*n)))
.max()
.unwrap(),
);
}
self.write_ubits(4, num_bits.into())?;
if has_mult {
self.write_sbits(num_bits, (color_transform.r_multiply * 256f32) as i32)?;
self.write_sbits(num_bits, (color_transform.g_multiply * 256f32) as i32)?;
self.write_sbits(num_bits, (color_transform.b_multiply * 256f32) as i32)?;
}
if has_add {
self.write_sbits(num_bits, color_transform.r_add.into())?;
self.write_sbits(num_bits, color_transform.g_add.into())?;
self.write_sbits(num_bits, color_transform.b_add.into())?;
}
Ok(())
}
fn write_color_transform(&mut self, color_transform: &ColorTransform) -> Result<()> {
self.flush_bits()?;
let has_mult = color_transform.r_multiply != 1f32
|| color_transform.g_multiply != 1f32
|| color_transform.b_multiply != 1f32
|| color_transform.a_multiply != 1f32;
let has_add = color_transform.r_add != 0
|| color_transform.g_add != 0
|| color_transform.b_add != 0
|| color_transform.a_add != 0;
let multiply = [
color_transform.r_multiply,
color_transform.g_multiply,
color_transform.b_multiply,
color_transform.a_multiply,
];
let add = [
color_transform.r_add,
color_transform.g_add,
color_transform.b_add,
color_transform.a_add,
];
self.write_bit(has_add)?;
self.write_bit(has_mult)?;
let mut num_bits = if has_mult {
multiply
.iter()
.map(|n| count_sbits((*n * 256f32) as i32))
.max()
.unwrap()
} else {
0u8
};
if has_add {
num_bits = max(
num_bits,
add.iter()
.map(|n| count_sbits(i32::from(*n)))
.max()
.unwrap(),
);
}
self.write_ubits(4, num_bits.into())?;
if has_mult {
self.write_sbits(num_bits, (color_transform.r_multiply * 256f32) as i32)?;
self.write_sbits(num_bits, (color_transform.g_multiply * 256f32) as i32)?;
self.write_sbits(num_bits, (color_transform.b_multiply * 256f32) as i32)?;
self.write_sbits(num_bits, (color_transform.a_multiply * 256f32) as i32)?;
}
if has_add {
self.write_sbits(num_bits, color_transform.r_add.into())?;
self.write_sbits(num_bits, color_transform.g_add.into())?;
self.write_sbits(num_bits, color_transform.b_add.into())?;
self.write_sbits(num_bits, color_transform.a_add.into())?;
}
Ok(())
}
fn write_matrix(&mut self, m: &Matrix) -> Result<()> {
self.flush_bits()?;
// Scale
let has_scale = m.a != 1f32 || m.d != 1f32;
self.write_bit(has_scale)?;
if has_scale {
let num_bits = max(count_fbits(m.a), count_fbits(m.d));
self.write_ubits(5, num_bits.into())?;
self.write_fbits(num_bits, m.a)?;
self.write_fbits(num_bits, m.d)?;
}
// Rotate/Skew
let has_rotate_skew = m.b != 0f32 || m.c != 0f32;
self.write_bit(has_rotate_skew)?;
if has_rotate_skew {
let num_bits = max(count_fbits(m.b), count_fbits(m.c));
self.write_ubits(5, num_bits.into())?;
self.write_fbits(num_bits, m.b)?;
self.write_fbits(num_bits, m.c)?;
}
// Translate (always written)
let num_bits = max(count_sbits_twips(m.tx), count_sbits_twips(m.ty));
self.write_ubits(5, num_bits.into())?;
self.write_sbits_twips(num_bits, m.tx)?;
self.write_sbits_twips(num_bits, m.ty)?;
self.flush_bits()?;
Ok(())
}
fn write_language(&mut self, language: Language) -> Result<()> {
self.write_u8(match language {
Language::Unknown => 0,
Language::Latin => 1,
Language::Japanese => 2,
Language::Korean => 3,
Language::SimplifiedChinese => 4,
Language::TraditionalChinese => 5,
})?;
Ok(())
}
fn write_tag(&mut self, tag: &Tag) -> Result<()> {
match *tag {
Tag::ShowFrame => self.write_tag_header(TagCode::ShowFrame, 0)?,
Tag::ExportAssets(ref exports) => self.write_export_assets(&exports[..])?,
Tag::Protect(ref password) => {
if let Some(ref password_md5) = *password {
self.write_tag_header(TagCode::Protect, password_md5.len() as u32 + 3)?;
self.write_u16(0)?; // Two null bytes? Not specified in SWF19.
self.write_c_string(password_md5)?;
} else {
self.write_tag_header(TagCode::Protect, 0)?;
}
}
Tag::CsmTextSettings(ref settings) => {
self.write_tag_header(TagCode::CsmTextSettings, 12)?;
self.write_character_id(settings.id)?;
self.write_u8(
if settings.use_advanced_rendering {
0b01_000000
} else {
0
} | match settings.grid_fit {
TextGridFit::None => 0,
TextGridFit::Pixel => 0b01_000,
TextGridFit::SubPixel => 0b10_000,
},
)?;
self.write_f32(settings.thickness)?;
self.write_f32(settings.sharpness)?;
self.write_u8(0)?; // Reserved (0).
}
Tag::DefineBinaryData { id, ref data } => {
self.write_tag_header(TagCode::DefineBinaryData, data.len() as u32 + 6)?;
self.write_u16(id)?;
self.write_u32(0)?; // Reserved
self.output.write_all(data)?;
}
Tag::DefineBits { id, ref jpeg_data } => {
self.write_tag_header(TagCode::DefineBits, jpeg_data.len() as u32 + 2)?;
self.write_u16(id)?;
self.output.write_all(jpeg_data)?;
}
Tag::DefineBitsJpeg2 { id, ref jpeg_data } => {
self.write_tag_header(TagCode::DefineBitsJpeg2, jpeg_data.len() as u32 + 2)?;
self.write_u16(id)?;
self.output.write_all(jpeg_data)?;
}
Tag::DefineBitsJpeg3(ref jpeg) => {
self.write_tag_header(
TagCode::DefineBitsJpeg3,
(jpeg.data.len() + jpeg.alpha_data.len() + 6) as u32,
)?;
self.write_u16(jpeg.id)?;
if jpeg.version >= 4 {
self.write_fixed8(jpeg.deblocking)?;
}
// TODO(Herschel): Verify deblocking parameter is zero in version 3.
self.write_u32(jpeg.data.len() as u32)?;
self.output.write_all(&jpeg.data)?;
self.output.write_all(&jpeg.alpha_data)?;
}
Tag::DefineBitsLossless(ref tag) => {
let mut length = 7 + tag.data.len();
if tag.format == BitmapFormat::ColorMap8 {
length += 1;
}
// TODO(Herschel): Throw error if RGB15 in tag version 2.
let tag_code = if tag.version == 1 {
TagCode::DefineBitsLossless
} else {
TagCode::DefineBitsLossless2
};
self.write_tag_header(tag_code, length as u32)?;
self.write_character_id(tag.id)?;
let format_id = match tag.format {
BitmapFormat::ColorMap8 => 3,
BitmapFormat::Rgb15 => 4,
BitmapFormat::Rgb32 => 5,
};
self.write_u8(format_id)?;
self.write_u16(tag.width)?;
self.write_u16(tag.height)?;
if tag.format == BitmapFormat::ColorMap8 {
self.write_u8(tag.num_colors)?;
}
self.output.write_all(&tag.data)?;
}
Tag::DefineButton(ref button) => self.write_define_button(button)?,
Tag::DefineButton2(ref button) => self.write_define_button_2(button)?,
Tag::DefineButtonColorTransform(ref button_color) => {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_character_id(button_color.id)?;
for color_transform in &button_color.color_transforms {
writer.write_color_transform_no_alpha(color_transform)?;
writer.flush_bits()?;
}
}
self.write_tag_header(TagCode::DefineButtonCxform, buf.len() as u32)?;
self.output.write_all(&buf)?;
}
Tag::DefineButtonSound(ref button_sounds) => {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(button_sounds.id)?;
if let Some(ref sound) = button_sounds.over_to_up_sound {
writer.write_u16(sound.0)?;
writer.write_sound_info(&sound.1)?;
} else {
writer.write_u16(0)?
};
if let Some(ref sound) = button_sounds.up_to_over_sound {
writer.write_u16(sound.0)?;
writer.write_sound_info(&sound.1)?;
} else {
writer.write_u16(0)?
};
if let Some(ref sound) = button_sounds.over_to_down_sound {
writer.write_u16(sound.0)?;
writer.write_sound_info(&sound.1)?;
} else {
writer.write_u16(0)?
};
if let Some(ref sound) = button_sounds.down_to_over_sound {
writer.write_u16(sound.0)?;
writer.write_sound_info(&sound.1)?;
} else {
writer.write_u16(0)?
};
}
self.write_tag_header(TagCode::DefineButtonSound, buf.len() as u32)?;
self.output.write_all(&buf)?;
}
Tag::DefineEditText(ref edit_text) => self.write_define_edit_text(edit_text)?,
Tag::DefineFont(ref font) => {
let num_glyphs = font.glyphs.len();
let mut offsets = vec![];
let mut buf = vec![];
{
let mut writer = Writer::new(&mut buf, self.version);
for glyph in &font.glyphs {
let offset = num_glyphs * 2 + writer.output.len();
offsets.push(offset as u16);
// Bit length for fill and line indices.
// TODO: This theoretically could be >1?
writer.num_fill_bits = 1;
writer.num_line_bits = 0;
writer.write_ubits(4, 1)?;
writer.write_ubits(4, 0)?;
for shape_record in glyph {
writer.write_shape_record(shape_record, 1)?;
}
// End shape record.
writer.write_ubits(6, 0)?;
writer.flush_bits()?;
}
}
let tag_len = (2 + 2 * font.glyphs.len() + buf.len()) as u32;
self.write_tag_header(TagCode::DefineFont, tag_len)?;
self.write_u16(font.id)?;
for offset in offsets {
self.write_u16(offset)?;
}
self.output.write_all(&buf)?;
}
Tag::DefineFont2(ref font) => self.write_define_font_2(font)?,
Tag::DefineFont4(ref font) => self.write_define_font_4(font)?,
Tag::DefineFontAlignZones {
id,
thickness,
ref zones,
} => {
self.write_tag_header(TagCode::DefineFontAlignZones, 3 + 10 * zones.len() as u32)?;
self.write_character_id(id)?;
self.write_u8(match thickness {
FontThickness::Thin => 0b00_000000,
FontThickness::Medium => 0b01_000000,
FontThickness::Thick => 0b10_000000,
})?;
for zone in zones {
self.write_u8(2)?; // Always 2 dimensions.
self.write_i16(zone.left)?;
self.write_i16(zone.width)?;
self.write_i16(zone.bottom)?;
self.write_i16(zone.height)?;
self.write_u8(0b000000_11)?; // Always 2 dimensions.
}
}
Tag::DefineFontInfo(ref font_info) => {
let use_wide_codes = self.version >= 6 || font_info.version >= 2;
let len = font_info.name.len()
+ if use_wide_codes { 2 } else { 1 } * font_info.code_table.len()
+ if font_info.version >= 2 { 1 } else { 0 }
+ 4;
let tag_id = if font_info.version == 1 {
TagCode::DefineFontInfo
} else {
TagCode::DefineFontInfo2
};
self.write_tag_header(tag_id, len as u32)?;
self.write_u16(font_info.id)?;
// SWF19 has ANSI and Shift-JIS backwards?
self.write_u8(font_info.name.len() as u8)?;
self.output.write_all(font_info.name.as_bytes())?;
self.write_u8(
if font_info.is_small_text { 0b100000 } else { 0 }
| if font_info.is_ansi { 0b10000 } else { 0 }
| if font_info.is_shift_jis { 0b1000 } else { 0 }
| if font_info.is_italic { 0b100 } else { 0 }
| if font_info.is_bold { 0b10 } else { 0 }
| if use_wide_codes { 0b1 } else { 0 },
)?;
// TODO(Herschel): Assert language is unknown for v1.
if font_info.version >= 2 {
self.write_language(font_info.language)?;
}
for &code in &font_info.code_table {
if use_wide_codes {
self.write_u16(code)?;
} else {
self.write_u8(code as u8)?;
}
}
}
Tag::DefineFontName {
id,
ref name,
ref copyright_info,
} => {
let len = name.len() + copyright_info.len() + 4;
self.write_tag_header(TagCode::DefineFontName, len as u32)?;
self.write_character_id(id)?;
self.write_c_string(name)?;
self.write_c_string(copyright_info)?;
}
Tag::DefineMorphShape(ref define_morph_shape) => {
self.write_define_morph_shape(define_morph_shape)?
}
Tag::DefineScalingGrid {
id,
ref splitter_rect,
} => {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(id)?;
writer.write_rectangle(splitter_rect)?;
writer.flush_bits()?;
}
self.write_tag_header(TagCode::DefineScalingGrid, buf.len() as u32)?;
self.output.write_all(&buf)?;
}
Tag::DefineShape(ref shape) => self.write_define_shape(shape)?,
Tag::DefineSound(ref sound) => self.write_define_sound(sound)?,
Tag::DefineSprite(ref sprite) => self.write_define_sprite(sprite)?,
Tag::DefineText(ref text) => self.write_define_text(text)?,
Tag::DefineVideoStream(ref video) => self.write_define_video_stream(video)?,
Tag::DoAbc(ref do_abc) => {
let len = do_abc.data.len() + do_abc.name.len() + 5;
self.write_tag_header(TagCode::DoAbc, len as u32)?;
self.write_u32(if do_abc.is_lazy_initialize { 1 } else { 0 })?;
self.write_c_string(&do_abc.name)?;
self.output.write_all(&do_abc.data)?;
}
Tag::DoAction(ref action_data) => {
self.write_tag_header(TagCode::DoAction, action_data.len() as u32)?;
self.output.write_all(action_data)?;
}
Tag::DoInitAction {
id,
ref action_data,
} => {
self.write_tag_header(TagCode::DoInitAction, action_data.len() as u32 + 2)?;
self.write_u16(id)?;
self.output.write_all(action_data)?;
}
Tag::EnableDebugger(ref password_md5) => {
let len = password_md5.len() as u32 + 1;
if self.version >= 6 {
// SWF v6+ uses EnableDebugger2 tag.
self.write_tag_header(TagCode::EnableDebugger2, len + 2)?;
self.write_u16(0)?; // Reserved
} else {
self.write_tag_header(TagCode::EnableDebugger, len)?;
}
self.write_c_string(password_md5)?;
}
Tag::EnableTelemetry { ref password_hash } => {
if !password_hash.is_empty() {
self.write_tag_header(TagCode::EnableTelemetry, 34)?;
self.write_u16(0)?;
self.output.write_all(&password_hash[0..32])?;
} else {
self.write_tag_header(TagCode::EnableTelemetry, 2)?;
self.write_u16(0)?;
}
}
Tag::End => self.write_tag_header(TagCode::End, 0)?,
Tag::ImportAssets {
ref url,
ref imports,
} => {
let len = imports.iter().map(|e| e.name.len() as u32 + 3).sum::<u32>()
+ url.len() as u32
+ 1
+ 2;
// SWF v8 and later use ImportAssets2 tag.
if self.version >= 8 {
self.write_tag_header(TagCode::ImportAssets2, len + 2)?;
self.write_c_string(url)?;
self.write_u8(1)?;
self.write_u8(0)?;
} else {
self.write_tag_header(TagCode::ImportAssets, len)?;
self.write_c_string(url)?;
}
self.write_u16(imports.len() as u16)?;
for &ExportedAsset { id, ref name } in imports {
self.write_u16(id)?;
self.write_c_string(name)?;
}
}
Tag::JpegTables(ref data) => {
self.write_tag_header(TagCode::JpegTables, data.len() as u32)?;
self.output.write_all(data)?;
}
Tag::Metadata(ref metadata) => {
self.write_tag_header(TagCode::Metadata, metadata.len() as u32 + 1)?;
self.write_c_string(metadata)?;
}
// TODO: Allow clone of color.
Tag::SetBackgroundColor(ref color) => {
self.write_tag_header(TagCode::SetBackgroundColor, 3)?;
self.write_rgb(&color)?;
}
Tag::ScriptLimits {
max_recursion_depth,
timeout_in_seconds,
} => {
self.write_tag_header(TagCode::ScriptLimits, 4)?;
self.write_u16(max_recursion_depth)?;
self.write_u16(timeout_in_seconds)?;
}
Tag::SetTabIndex { depth, tab_index } => {
self.write_tag_header(TagCode::SetTabIndex, 4)?;
self.write_u16(depth)?;
self.write_u16(tab_index)?;
}
Tag::PlaceObject(ref place_object) => match (*place_object).version {
1 => self.write_place_object(place_object)?,
2 => self.write_place_object_2_or_3(place_object, 2)?,
3 => self.write_place_object_2_or_3(place_object, 3)?,
4 => self.write_place_object_2_or_3(place_object, 4)?,
_ => return Err(Error::invalid_data("Invalid PlaceObject version.")),
},
Tag::RemoveObject(ref remove_object) => {
if let Some(id) = remove_object.character_id {
self.write_tag_header(TagCode::RemoveObject, 4)?;
self.write_u16(id)?;
} else {
self.write_tag_header(TagCode::RemoveObject2, 2)?;
}
self.write_u16(remove_object.depth)?;
}
Tag::SoundStreamBlock(ref data) => {
self.write_tag_header(TagCode::SoundStreamBlock, data.len() as u32)?;
self.output.write_all(data)?;
}
Tag::SoundStreamHead(ref sound_stream_head) => {
self.write_sound_stream_head(sound_stream_head, 1)?;
}
Tag::SoundStreamHead2(ref sound_stream_head) => {
self.write_sound_stream_head(sound_stream_head, 2)?;
}
Tag::StartSound(ref start_sound) => {
let sound_info = &start_sound.sound_info;
let length = 3
+ if sound_info.in_sample.is_some() { 4 } else { 0 }
+ if sound_info.out_sample.is_some() {
4
} else {
0
}
+ if sound_info.num_loops > 1 { 2 } else { 0 }
+ if let Some(ref e) = sound_info.envelope {
e.len() as u32 * 8 + 1
} else {
0
};
self.write_tag_header(TagCode::StartSound, length)?;
self.write_u16(start_sound.id)?;
self.write_sound_info(sound_info)?;
}
Tag::StartSound2 {
ref class_name,
ref sound_info,
} => {
let length = class_name.len() as u32
+ 2
+ if sound_info.in_sample.is_some() { 4 } else { 0 }
+ if sound_info.out_sample.is_some() {
4
} else {
0
}
+ if sound_info.num_loops > 1 { 2 } else { 0 }
+ if let Some(ref e) = sound_info.envelope {
e.len() as u32 * 8 + 1
} else {
0
};
self.write_tag_header(TagCode::StartSound2, length)?;
self.write_c_string(class_name)?;
self.write_sound_info(sound_info)?;
}
Tag::SymbolClass(ref symbols) => {
let len = symbols
.iter()
.map(|e| e.class_name.len() as u32 + 3)
.sum::<u32>()
+ 2;
self.write_tag_header(TagCode::SymbolClass, len)?;
self.write_u16(symbols.len() as u16)?;
for &SymbolClassLink { id, ref class_name } in symbols {
self.write_u16(id)?;
self.write_c_string(class_name)?;
}
}
Tag::VideoFrame(ref frame) => {
self.write_tag_header(TagCode::VideoFrame, 4 + frame.data.len() as u32)?;
self.write_character_id(frame.stream_id)?;
self.write_u16(frame.frame_num)?;
self.output.write_all(&frame.data)?;
}
Tag::FileAttributes(ref attributes) => {
self.write_tag_header(TagCode::FileAttributes, 4)?;
let mut flags = 0u32;
if attributes.use_direct_blit {
flags |= 0b01000000;
}
if attributes.use_gpu {
flags |= 0b00100000;
}
if attributes.has_metadata {
flags |= 0b00010000;
}
if attributes.is_action_script_3 {
flags |= 0b00001000;
}
if attributes.use_network_sandbox {
flags |= 0b00000001;
}
self.write_u32(flags)?;
}
Tag::FrameLabel(FrameLabel {
ref label,
is_anchor,
}) => {
// TODO: Assert proper version
let is_anchor = is_anchor && self.version >= 6;
let length = label.len() as u32 + if is_anchor { 2 } else { 1 };
self.write_tag_header(TagCode::FrameLabel, length)?;
self.write_c_string(label)?;
if is_anchor {
self.write_u8(1)?;
}
}
Tag::DefineSceneAndFrameLabelData(ref data) => {
self.write_define_scene_and_frame_label_data(data)?
}
Tag::ProductInfo(ref product_info) => self.write_product_info(product_info)?,
Tag::DebugId(ref debug_id) => self.write_debug_id(debug_id)?,
Tag::Unknown { tag_code, ref data } => {
self.write_tag_code_and_length(tag_code, data.len() as u32)?;
self.output.write_all(data)?;
}
}
Ok(())
}
fn write_define_button(&mut self, button: &Button) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(button.id)?;
for record in &button.records {
writer.write_button_record(record, 1)?;
}
writer.write_u8(0)?; // End button records
// TODO: Assert we have some action.
writer.output.write_all(&button.actions[0].action_data)?;
}
self.write_tag_header(TagCode::DefineButton, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_button_2(&mut self, button: &Button) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(button.id)?;
let flags = if button.is_track_as_menu { 1 } else { 0 };
writer.write_u8(flags)?;
let mut record_data = Vec::new();
{
let mut writer_2 = Writer::new(&mut record_data, self.version);
for record in &button.records {
writer_2.write_button_record(record, 2)?;
}
writer_2.write_u8(0)?; // End button records
}
writer.write_u16(record_data.len() as u16 + 2)?;
writer.output.write_all(&record_data)?;
let mut iter = button.actions.iter().peekable();
while let Some(action) = iter.next() {
if iter.peek().is_some() {
let length = action.action_data.len() as u16 + 4;
writer.write_u16(length)?;
} else {
writer.write_u16(0)?;
}
writer.write_u8(
if action
.conditions
.contains(&ButtonActionCondition::IdleToOverDown)
{
0b1000_0000
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OutDownToIdle)
{
0b100_0000
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OutDownToOverDown)
{
0b10_0000
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OverDownToOutDown)
{
0b1_0000
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OverDownToOverUp)
{
0b1000
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OverUpToOverDown)
{
0b100
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::OverUpToIdle)
{
0b10
} else {
0
} | if action
.conditions
.contains(&ButtonActionCondition::IdleToOverUp)
{
0b1
} else {
0
},
)?;
let mut flags = if action
.conditions
.contains(&ButtonActionCondition::OverDownToIdle)
{
0b1
} else {
0
};
if action.conditions.contains(&ButtonActionCondition::KeyPress) {
if let Some(key_code) = action.key_code {
flags |= key_code << 1;
}
}
writer.write_u8(flags)?;
writer.output.write_all(&action.action_data)?;
}
}
self.write_tag_header(TagCode::DefineButton2, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_morph_shape(&mut self, data: &DefineMorphShape) -> Result<()> {
if data.start.fill_styles.len() != data.end.fill_styles.len()
|| data.start.line_styles.len() != data.end.line_styles.len()
{
return Err(Error::invalid_data(
"Start and end state of a morph shape must have the same number of styles.",
));
}
let num_fill_styles = data.start.fill_styles.len();
let num_line_styles = data.start.line_styles.len();
let num_fill_bits = count_ubits(num_fill_styles as u32);
let num_line_bits = count_ubits(num_line_styles as u32);
// Need to write styles first, to calculate offset to EndEdges.
let mut start_buf = Vec::new();
{
let mut writer = Writer::new(&mut start_buf, self.version);
// Styles
// TODO(Herschel): Make fn write_style_len. Check version.
if num_fill_styles >= 0xff {
writer.write_u8(0xff)?;
writer.write_u16(num_fill_styles as u16)?;
} else {
writer.write_u8(num_fill_styles as u8)?;
}
for (start, end) in data
.start
.fill_styles
.iter()
.zip(data.end.fill_styles.iter())
{
writer.write_morph_fill_style(start, end, data.version)?;
}
if num_line_styles >= 0xff {
writer.write_u8(0xff)?;
writer.write_u16(num_line_styles as u16)?;
} else {
writer.write_u8(num_line_styles as u8)?;
}
for (start, end) in data
.start
.line_styles
.iter()
.zip(data.end.line_styles.iter())
{
writer.write_morph_line_style(start, end, data.version)?;
}
// TODO(Herschel): Make fn write_shape.
writer.write_ubits(4, num_fill_bits.into())?;
writer.write_ubits(4, num_line_bits.into())?;
writer.num_fill_bits = num_fill_bits;
writer.num_line_bits = num_line_bits;
for shape_record in &data.start.shape {
writer.write_shape_record(shape_record, 1)?;
}
// End shape record.
writer.write_ubits(6, 0)?;
writer.flush_bits()?;
}
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_character_id(data.id)?;
writer.write_rectangle(&data.start.shape_bounds)?;
writer.write_rectangle(&data.end.shape_bounds)?;
if data.version >= 2 {
writer.write_rectangle(&data.start.edge_bounds)?;
writer.write_rectangle(&data.end.edge_bounds)?;
writer.write_u8(
if data.has_non_scaling_strokes {
0b10
} else {
0
} | if data.has_scaling_strokes { 0b1 } else { 0 },
)?;
}
// Offset to EndEdges.
writer.write_u32(start_buf.len() as u32)?;
writer.output.write_all(&start_buf)?;
// EndEdges.
writer.write_u8(0)?; // NumFillBits and NumLineBits are written as 0 for the end shape.
writer.num_fill_bits = num_fill_bits;
writer.num_line_bits = num_line_bits;
for shape_record in &data.end.shape {
writer.write_shape_record(shape_record, 1)?;
}
// End shape record.
writer.write_ubits(6, 0)?;
writer.flush_bits()?;
}
let tag_code = if data.version == 1 {
TagCode::DefineMorphShape
} else {
TagCode::DefineMorphShape2
};
self.write_tag_header(tag_code, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_morph_fill_style(
&mut self,
start: &FillStyle,
end: &FillStyle,
shape_version: u8,
) -> Result<()> {
match (start, end) {
(&FillStyle::Color(ref start_color), &FillStyle::Color(ref end_color)) => {
self.write_u8(0x00)?; // Solid color.
self.write_rgba(start_color)?;
self.write_rgba(end_color)?;
}
(
&FillStyle::LinearGradient(ref start_gradient),
&FillStyle::LinearGradient(ref end_gradient),
) => {
self.write_u8(0x10)?; // Linear gradient.
self.write_morph_gradient(start_gradient, end_gradient)?;
}
(
&FillStyle::RadialGradient(ref start_gradient),
&FillStyle::RadialGradient(ref end_gradient),
) => {
self.write_u8(0x12)?; // Linear gradient.
self.write_morph_gradient(start_gradient, end_gradient)?;
}
(
&FillStyle::FocalGradient {
gradient: ref start_gradient,
focal_point: start_focal_point,
},
&FillStyle::FocalGradient {
gradient: ref end_gradient,
focal_point: end_focal_point,
},
) => {
if self.version < 8 || shape_version < 2 {
return Err(Error::invalid_data(
"Focal gradients are only support in SWF version 8 \
and higher.",
));
}
self.write_u8(0x13)?; // Focal gradient.
self.write_morph_gradient(start_gradient, end_gradient)?;
self.write_fixed8(start_focal_point)?;
self.write_fixed8(end_focal_point)?;
}
(
&FillStyle::Bitmap {
id,
matrix: ref start_matrix,
is_smoothed,
is_repeating,
},
&FillStyle::Bitmap {
id: end_id,
matrix: ref end_matrix,
is_smoothed: end_is_smoothed,
is_repeating: end_is_repeating,
},
) if id == end_id && is_smoothed == end_is_smoothed
|| is_repeating == end_is_repeating =>
{
let fill_style_type = match (is_smoothed, is_repeating) {
(true, true) => 0x40,
(true, false) => 0x41,
(false, true) => 0x42,
(false, false) => 0x43,
};
self.write_u8(fill_style_type)?;
self.write_u16(id)?;
self.write_matrix(start_matrix)?;
self.write_matrix(end_matrix)?;
}
_ => {
return Err(Error::invalid_data(
"Morph start and end fill styles must be the same variant.",
))
}
}
Ok(())
}
fn write_morph_gradient(&mut self, start: &Gradient, end: &Gradient) -> Result<()> {
self.write_matrix(&start.matrix)?;
self.write_matrix(&end.matrix)?;
if start.records.len() != end.records.len() {
return Err(Error::invalid_data(
"Morph start and end gradient must have the same amount of records.",
));
}
self.write_gradient_flags(start)?;
for (start_record, end_record) in start.records.iter().zip(end.records.iter()) {
self.write_u8(start_record.ratio)?;
self.write_rgba(&start_record.color)?;
self.write_u8(end_record.ratio)?;
self.write_rgba(&end_record.color)?;
}
Ok(())
}
fn write_morph_line_style(
&mut self,
start: &LineStyle,
end: &LineStyle,
shape_version: u8,
) -> Result<()> {
if shape_version < 2 {
// TODO(Herschel): Handle overflow.
self.write_u16(start.width.get() as u16)?;
self.write_u16(end.width.get() as u16)?;
self.write_rgba(&start.color)?;
self.write_rgba(&end.color)?;
} else {
if start.start_cap != end.start_cap
|| start.join_style != end.join_style
|| start.allow_scale_x != end.allow_scale_x
|| start.allow_scale_y != end.allow_scale_y
|| start.is_pixel_hinted != end.is_pixel_hinted
|| start.allow_close != end.allow_close
|| start.end_cap != end.end_cap
{
return Err(Error::invalid_data(
"Morph start and end line styles must have the same join parameters.",
));
}
// TODO(Herschel): Handle overflow.
self.write_u16(start.width.get() as u16)?;
self.write_u16(end.width.get() as u16)?;
// MorphLineStyle2
self.write_ubits(
2,
match start.start_cap {
LineCapStyle::Round => 0,
LineCapStyle::None => 1,
LineCapStyle::Square => 2,
},
)?;
self.write_ubits(
2,
match start.join_style {
LineJoinStyle::Round => 0,
LineJoinStyle::Bevel => 1,
LineJoinStyle::Miter(_) => 2,
},
)?;
self.write_bit(start.fill_style.is_some())?;
self.write_bit(!start.allow_scale_x)?;
self.write_bit(!start.allow_scale_y)?;
self.write_bit(start.is_pixel_hinted)?;
self.write_ubits(5, 0)?;
self.write_bit(!start.allow_close)?;
self.write_ubits(
2,
match start.end_cap {
LineCapStyle::Round => 0,
LineCapStyle::None => 1,
LineCapStyle::Square => 2,
},
)?;
if let LineJoinStyle::Miter(miter_factor) = start.join_style {
self.write_fixed8(miter_factor)?;
}
match (&start.fill_style, &end.fill_style) {
(&None, &None) => {
self.write_rgba(&start.color)?;
self.write_rgba(&end.color)?;
}
(&Some(ref start_fill), &Some(ref end_fill)) => {
self.write_morph_fill_style(start_fill, end_fill, shape_version)?
}
_ => {
return Err(Error::invalid_data(
"Morph start and end line styles must both have fill styles.",
))
}
}
}
Ok(())
}
fn write_define_scene_and_frame_label_data(
&mut self,
data: &DefineSceneAndFrameLabelData,
) -> Result<()> {
let mut buf = Vec::with_capacity((data.scenes.len() + data.frame_labels.len()) * 4);
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_encoded_u32(data.scenes.len() as u32)?;
for scene in &data.scenes {
writer.write_encoded_u32(scene.frame_num)?;
writer.write_c_string(&scene.label)?;
}
writer.write_encoded_u32(data.frame_labels.len() as u32)?;
for frame_label in &data.frame_labels {
writer.write_encoded_u32(frame_label.frame_num)?;
writer.write_c_string(&frame_label.label)?;
}
}
self.write_tag_header(TagCode::DefineSceneAndFrameLabelData, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_shape(&mut self, shape: &Shape) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(shape.id)?;
writer.write_rectangle(&shape.shape_bounds)?;
if shape.version >= 4 {
writer.write_rectangle(&shape.edge_bounds)?;
writer.flush_bits()?;
writer.write_u8(
if shape.has_fill_winding_rule {
0b100
} else {
0
} | if shape.has_non_scaling_strokes {
0b10
} else {
0
} | if shape.has_scaling_strokes { 0b1 } else { 0 },
)?;
}
writer.write_shape_styles(&shape.styles, shape.version)?;
for shape_record in &shape.shape {
writer.write_shape_record(shape_record, shape.version)?;
}
// End shape record.
writer.write_ubits(6, 0)?;
writer.flush_bits()?;
}
let tag_code = match shape.version {
1 => TagCode::DefineShape,
2 => TagCode::DefineShape2,
3 => TagCode::DefineShape3,
4 => TagCode::DefineShape4,
_ => return Err(Error::invalid_data("Invalid DefineShape version.")),
};
self.write_tag_header(tag_code, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_sound(&mut self, sound: &Sound) -> Result<()> {
self.write_tag_header(TagCode::DefineSound, 7 + sound.data.len() as u32)?;
self.write_u16(sound.id)?;
self.write_sound_format(&sound.format)?;
self.write_u32(sound.num_samples)?;
self.output.write_all(&sound.data)?;
Ok(())
}
fn write_define_sprite(&mut self, sprite: &Sprite) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u16(sprite.id)?;
writer.write_u16(sprite.num_frames)?;
writer.write_tag_list(&sprite.tags)?;
};
self.write_tag_header(TagCode::DefineSprite, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_export_assets(&mut self, exports: &[ExportedAsset]) -> Result<()> {
let len = exports.iter().map(|e| e.name.len() as u32 + 1).sum::<u32>()
+ exports.len() as u32 * 2
+ 2;
self.write_tag_header(TagCode::ExportAssets, len)?;
self.write_u16(exports.len() as u16)?;
for &ExportedAsset { id, ref name } in exports {
self.write_u16(id)?;
self.write_c_string(name)?;
}
Ok(())
}
fn write_button_record(&mut self, record: &ButtonRecord, tag_version: u8) -> Result<()> {
// TODO: Validate version
let flags = if record.blend_mode != BlendMode::Normal {
0b10_0000
} else {
0
} | if !record.filters.is_empty() {
0b1_0000
} else {
0
} | if record.states.contains(&ButtonState::HitTest) {
0b1000
} else {
0
} | if record.states.contains(&ButtonState::Down) {
0b100
} else {
0
} | if record.states.contains(&ButtonState::Over) {
0b10
} else {
0
} | if record.states.contains(&ButtonState::Up) {
0b1
} else {
0
};
self.write_u8(flags)?;
self.write_u16(record.id)?;
self.write_u16(record.depth)?;
self.write_matrix(&record.matrix)?;
if tag_version >= 2 {
self.write_color_transform(&record.color_transform)?;
if !record.filters.is_empty() {
self.write_u8(record.filters.len() as u8)?;
for filter in &record.filters {
self.write_filter(filter)?;
}
}
if record.blend_mode != BlendMode::Normal {
self.write_blend_mode(record.blend_mode)?;
}
}
Ok(())
}
fn write_blend_mode(&mut self, blend_mode: BlendMode) -> Result<()> {
self.write_u8(match blend_mode {
BlendMode::Normal => 0,
BlendMode::Layer => 2,
BlendMode::Multiply => 3,
BlendMode::Screen => 4,
BlendMode::Lighten => 5,
BlendMode::Darken => 6,
BlendMode::Difference => 7,
BlendMode::Add => 8,
BlendMode::Subtract => 9,
BlendMode::Invert => 10,
BlendMode::Alpha => 11,
BlendMode::Erase => 12,
BlendMode::Overlay => 13,
BlendMode::HardLight => 14,
})?;
Ok(())
}
fn write_shape_styles(&mut self, styles: &ShapeStyles, shape_version: u8) -> Result<()> {
// TODO: Check shape_version.
if styles.fill_styles.len() >= 0xff {
self.write_u8(0xff)?;
self.write_u16(styles.fill_styles.len() as u16)?;
} else {
self.write_u8(styles.fill_styles.len() as u8)?;
}
for fill_style in &styles.fill_styles {
self.write_fill_style(fill_style, shape_version)?;
}
if styles.line_styles.len() >= 0xff {
self.write_u8(0xff)?;
self.write_u16(styles.line_styles.len() as u16)?;
} else {
self.write_u8(styles.line_styles.len() as u8)?;
}
for line_style in &styles.line_styles {
self.write_line_style(line_style, shape_version)?;
}
let num_fill_bits = count_ubits(styles.fill_styles.len() as u32);
let num_line_bits = count_ubits(styles.line_styles.len() as u32);
self.write_ubits(4, num_fill_bits.into())?;
self.write_ubits(4, num_line_bits.into())?;
self.num_fill_bits = num_fill_bits;
self.num_line_bits = num_line_bits;
Ok(())
}
fn write_shape_record(&mut self, record: &ShapeRecord, shape_version: u8) -> Result<()> {
match *record {
ShapeRecord::StraightEdge { delta_x, delta_y } => {
self.write_ubits(2, 0b11)?; // Straight edge
// TODO: Check underflow?
let mut num_bits = max(count_sbits_twips(delta_x), count_sbits_twips(delta_y));
num_bits = max(2, num_bits);
let is_axis_aligned = delta_x.get() == 0 || delta_y.get() == 0;
self.write_ubits(4, u32::from(num_bits) - 2)?;
self.write_bit(!is_axis_aligned)?;
if is_axis_aligned {
self.write_bit(delta_x.get() == 0)?;
}
if delta_x.get() != 0 {
self.write_sbits_twips(num_bits, delta_x)?;
}
if delta_y.get() != 0 {
self.write_sbits_twips(num_bits, delta_y)?;
}
}
ShapeRecord::CurvedEdge {
control_delta_x,
control_delta_y,
anchor_delta_x,
anchor_delta_y,
} => {
self.write_ubits(2, 0b10)?; // Curved edge
let num_bits = [
control_delta_x,
control_delta_y,
anchor_delta_x,
anchor_delta_y,
]
.iter()
.map(|x| count_sbits_twips(*x))
.max()
.unwrap();
self.write_ubits(4, u32::from(num_bits) - 2)?;
self.write_sbits_twips(num_bits, control_delta_x)?;
self.write_sbits_twips(num_bits, control_delta_y)?;
self.write_sbits_twips(num_bits, anchor_delta_x)?;
self.write_sbits_twips(num_bits, anchor_delta_y)?;
}
ShapeRecord::StyleChange(ref style_change) => {
self.write_bit(false)?; // Style change
let num_fill_bits = self.num_fill_bits;
let num_line_bits = self.num_line_bits;
self.write_bit(style_change.new_styles.is_some())?;
self.write_bit(style_change.line_style.is_some())?;
self.write_bit(style_change.fill_style_1.is_some())?;
self.write_bit(style_change.fill_style_0.is_some())?;
self.write_bit(style_change.move_to.is_some())?;
if let Some((move_x, move_y)) = style_change.move_to {
let num_bits = max(count_sbits_twips(move_x), count_sbits_twips(move_y));
self.write_ubits(5, num_bits.into())?;
self.write_sbits_twips(num_bits, move_x)?;
self.write_sbits_twips(num_bits, move_y)?;
}
if let Some(fill_style_index) = style_change.fill_style_0 {
self.write_ubits(num_fill_bits, fill_style_index)?;
}
if let Some(fill_style_index) = style_change.fill_style_1 {
self.write_ubits(num_fill_bits, fill_style_index)?;
}
if let Some(line_style_index) = style_change.line_style {
self.write_ubits(num_line_bits, line_style_index)?;
}
if let Some(ref new_styles) = style_change.new_styles {
if shape_version < 2 {
return Err(Error::invalid_data(
"Only DefineShape2 and higher may change styles.",
));
}
self.write_shape_styles(new_styles, shape_version)?;
}
}
}
Ok(())
}
fn write_fill_style(&mut self, fill_style: &FillStyle, shape_version: u8) -> Result<()> {
match *fill_style {
FillStyle::Color(ref color) => {
self.write_u8(0x00)?; // Solid color.
if shape_version >= 3 {
self.write_rgba(color)?
} else {
self.write_rgb(color)?;
}
}
FillStyle::LinearGradient(ref gradient) => {
self.write_u8(0x10)?; // Linear gradient.
self.write_gradient(gradient, shape_version)?;
}
FillStyle::RadialGradient(ref gradient) => {
self.write_u8(0x12)?; // Linear gradient.
self.write_gradient(gradient, shape_version)?;
}
FillStyle::FocalGradient {
ref gradient,
focal_point,
} => {
if self.version < 8 {
return Err(Error::invalid_data(
"Focal gradients are only support in SWF version 8 \
and higher.",
));
}
self.write_u8(0x13)?; // Focal gradient.
self.write_gradient(gradient, shape_version)?;
self.write_fixed8(focal_point)?;
}
FillStyle::Bitmap {
id,
ref matrix,
is_smoothed,
is_repeating,
} => {
// Bitmap smoothing only an option in SWF version 8+.
// Lower versions use 0x40 and 0x41 type even when unsmoothed.
let fill_style_type = match (is_smoothed || self.version < 8, is_repeating) {
(true, true) => 0x40,
(true, false) => 0x41,
(false, true) => 0x42,
(false, false) => 0x43,
};
self.write_u8(fill_style_type)?;
self.write_u16(id)?;
self.write_matrix(matrix)?;
}
}
Ok(())
}
fn write_line_style(&mut self, line_style: &LineStyle, shape_version: u8) -> Result<()> {
// TODO(Herschel): Handle overflow.
self.write_u16(line_style.width.get() as u16)?;
if shape_version >= 4 {
// LineStyle2
self.write_ubits(
2,
match line_style.start_cap {
LineCapStyle::Round => 0,
LineCapStyle::None => 1,
LineCapStyle::Square => 2,
},
)?;
self.write_ubits(
2,
match line_style.join_style {
LineJoinStyle::Round => 0,
LineJoinStyle::Bevel => 1,
LineJoinStyle::Miter(_) => 2,
},
)?;
self.write_bit(line_style.fill_style.is_some())?;
self.write_bit(!line_style.allow_scale_x)?;
self.write_bit(!line_style.allow_scale_y)?;
self.write_bit(line_style.is_pixel_hinted)?;
self.write_ubits(5, 0)?;
self.write_bit(!line_style.allow_close)?;
self.write_ubits(
2,
match line_style.end_cap {
LineCapStyle::Round => 0,
LineCapStyle::None => 1,
LineCapStyle::Square => 2,
},
)?;
if let LineJoinStyle::Miter(miter_factor) = line_style.join_style {
self.write_fixed8(miter_factor)?;
}
match line_style.fill_style {
None => self.write_rgba(&line_style.color)?,
Some(ref fill) => self.write_fill_style(fill, shape_version)?,
}
} else if shape_version >= 3 {
// LineStyle1 with RGBA
self.write_rgba(&line_style.color)?;
} else {
// LineStyle1 with RGB
self.write_rgb(&line_style.color)?;
}
Ok(())
}
fn write_gradient(&mut self, gradient: &Gradient, shape_version: u8) -> Result<()> {
self.write_matrix(&gradient.matrix)?;
self.flush_bits()?;
self.write_gradient_flags(gradient)?;
for record in &gradient.records {
self.write_u8(record.ratio)?;
if shape_version >= 3 {
self.write_rgba(&record.color)?;
} else {
self.write_rgb(&record.color)?;
}
}
Ok(())
}
fn write_gradient_flags(&mut self, gradient: &Gradient) -> Result<()> {
let mut flags = 0;
flags |= match &gradient.spread {
GradientSpread::Pad => 0,
GradientSpread::Reflect => 0b0100_0000,
GradientSpread::Repeat => 0b1000_0000,
};
flags |= match &gradient.interpolation {
GradientInterpolation::RGB => 0b00_0000,
GradientInterpolation::LinearRGB => 0b_01_0000,
};
flags |= (gradient.records.len() as u8) & 0b1111;
self.write_u8(flags)?;
Ok(())
}
fn write_place_object(&mut self, place_object: &PlaceObject) -> Result<()> {
// TODO: Assert that the extraneous fields are the defaults.
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
if let PlaceObjectAction::Place(character_id) = place_object.action {
writer.write_u16(character_id)?;
} else {
return Err(Error::invalid_data(
"PlaceObject version 1 can only use a Place action.",
));
}
writer.write_u16(place_object.depth)?;
if let Some(ref matrix) = place_object.matrix {
writer.write_matrix(matrix)?;
} else {
writer.write_matrix(&Matrix::identity())?;
}
if let Some(ref color_transform) = place_object.color_transform {
writer.write_color_transform_no_alpha(color_transform)?;
}
}
self.write_tag_header(TagCode::PlaceObject, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_place_object_2_or_3(
&mut self,
place_object: &PlaceObject,
place_object_version: u8,
) -> Result<()> {
let mut buf = Vec::new();
{
// TODO: Assert version.
let mut writer = Writer::new(&mut buf, self.version);
writer.write_u8(
if place_object.clip_actions.is_some() {
0b1000_0000
} else {
0
} | if place_object.clip_depth.is_some() {
0b0100_0000
} else {
0
} | if place_object.name.is_some() {
0b0010_0000
} else {
0
} | if place_object.ratio.is_some() {
0b0001_0000
} else {
0
} | if place_object.color_transform.is_some() {
0b0000_1000
} else {
0
} | if place_object.matrix.is_some() {
0b0000_0100
} else {
0
} | match place_object.action {
PlaceObjectAction::Place(_) => 0b10,
PlaceObjectAction::Modify => 0b01,
PlaceObjectAction::Replace(_) => 0b11,
},
)?;
if place_object_version >= 3 {
writer.write_u8(
if place_object.background_color.is_some() {
0b100_0000
} else {
0
} | if place_object.is_visible.is_some() {
0b10_0000
} else {
0
} | if place_object.is_image { 0b1_0000 } else { 0 }
| if place_object.class_name.is_some() {
0b1000
} else {
0
}
| if place_object.is_bitmap_cached.is_some() {
0b100
} else {
0
}
| if place_object.blend_mode.is_some() {
0b10
} else {
0
}
| if place_object.filters.is_some() {
0b1
} else {
0
},
)?;
}
writer.write_u16(place_object.depth)?;
if place_object_version >= 3 {
if let Some(ref class_name) = place_object.class_name {
writer.write_c_string(class_name)?;
}
}
match place_object.action {
PlaceObjectAction::Place(character_id)
| PlaceObjectAction::Replace(character_id) => writer.write_u16(character_id)?,
PlaceObjectAction::Modify => (),
}
if let Some(ref matrix) = place_object.matrix {
writer.write_matrix(matrix)?;
};
if let Some(ref color_transform) = place_object.color_transform {
writer.write_color_transform(color_transform)?;
};
if let Some(ratio) = place_object.ratio {
writer.write_u16(ratio)?;
}
if let Some(ref name) = place_object.name {
writer.write_c_string(name)?;
};
if let Some(clip_depth) = place_object.clip_depth {
writer.write_u16(clip_depth)?;
}
if place_object_version >= 3 {
if let Some(filters) = &place_object.filters {
writer.write_u8(filters.len() as u8)?;
for filter in filters {
writer.write_filter(filter)?;
}
}
if let Some(blend_mode) = place_object.blend_mode {
writer.write_blend_mode(blend_mode)?;
}
if let Some(is_bitmap_cached) = place_object.is_bitmap_cached {
writer.write_u8(if is_bitmap_cached { 1 } else { 0 })?;
}
if let Some(is_visible) = place_object.is_visible {
writer.write_u8(if is_visible { 1 } else { 0 })?;
}
if let Some(ref background_color) = place_object.background_color {
writer.write_rgba(background_color)?;
}
}
if let Some(clip_actions) = &place_object.clip_actions {
writer.write_clip_actions(clip_actions)?;
}
writer.flush_bits()?;
// PlaceObject4 adds some embedded AMF data per instance.
if place_object_version >= 4 {
if let Some(ref data) = place_object.amf_data {
writer.output.write_all(data)?;
}
}
}
let tag_code = match place_object_version {
2 => TagCode::PlaceObject2,
3 => TagCode::PlaceObject3,
4 => TagCode::PlaceObject4,
_ => return Err(Error::invalid_data("Invalid PlaceObject version.")),
};
self.write_tag_header(tag_code, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_filter(&mut self, filter: &Filter) -> Result<()> {
match *filter {
Filter::DropShadowFilter(ref drop_shadow) => {
self.write_u8(0)?;
self.write_rgba(&drop_shadow.color)?;
self.write_fixed16(drop_shadow.blur_x)?;
self.write_fixed16(drop_shadow.blur_y)?;
self.write_fixed16(drop_shadow.angle)?;
self.write_fixed16(drop_shadow.distance)?;
self.write_fixed8(drop_shadow.strength)?;
self.write_bit(drop_shadow.is_inner)?;
self.write_bit(drop_shadow.is_knockout)?;
self.write_bit(true)?;
self.write_ubits(5, drop_shadow.num_passes.into())?;
}
Filter::BlurFilter(ref blur) => {
self.write_u8(1)?;
self.write_fixed16(blur.blur_x)?;
self.write_fixed16(blur.blur_y)?;
self.write_u8(blur.num_passes << 3)?;
}
Filter::GlowFilter(ref glow) => {
self.write_u8(2)?;
self.write_rgba(&glow.color)?;
self.write_fixed16(glow.blur_x)?;
self.write_fixed16(glow.blur_y)?;
self.write_fixed8(glow.strength)?;
self.write_bit(glow.is_inner)?;
self.write_bit(glow.is_knockout)?;
self.write_bit(true)?;
self.write_ubits(5, glow.num_passes.into())?;
}
Filter::BevelFilter(ref bevel) => {
self.write_u8(3)?;
self.write_rgba(&bevel.shadow_color)?;
self.write_rgba(&bevel.highlight_color)?;
self.write_fixed16(bevel.blur_x)?;
self.write_fixed16(bevel.blur_y)?;
self.write_fixed16(bevel.angle)?;
self.write_fixed16(bevel.distance)?;
self.write_fixed8(bevel.strength)?;
self.write_bit(bevel.is_inner)?;
self.write_bit(bevel.is_knockout)?;
self.write_bit(true)?;
self.write_bit(bevel.is_on_top)?;
self.write_ubits(4, bevel.num_passes.into())?;
}
Filter::GradientGlowFilter(ref glow) => {
self.write_u8(4)?;
self.write_u8(glow.colors.len() as u8)?;
for gradient_record in &glow.colors {
self.write_rgba(&gradient_record.color)?;
}
for gradient_record in &glow.colors {
self.write_u8(gradient_record.ratio)?;
}
self.write_fixed16(glow.blur_x)?;
self.write_fixed16(glow.blur_y)?;
self.write_fixed16(glow.angle)?;
self.write_fixed16(glow.distance)?;
self.write_fixed8(glow.strength)?;
self.write_bit(glow.is_inner)?;
self.write_bit(glow.is_knockout)?;
self.write_bit(true)?;
self.write_bit(glow.is_on_top)?;
self.write_ubits(4, glow.num_passes.into())?;
}
Filter::ConvolutionFilter(ref convolve) => {
self.write_u8(5)?;
self.write_u8(convolve.num_matrix_cols)?;
self.write_u8(convolve.num_matrix_rows)?;
self.write_fixed16(convolve.divisor)?;
self.write_fixed16(convolve.bias)?;
for val in &convolve.matrix {
self.write_fixed16(*val)?;
}
self.write_rgba(&convolve.default_color)?;
self.write_u8(
if convolve.is_clamped { 0b10 } else { 0 }
| if convolve.is_preserve_alpha { 0b1 } else { 0 },
)?;
}
Filter::ColorMatrixFilter(ref color_matrix) => {
self.write_u8(6)?;
for i in 0..20 {
self.write_fixed16(color_matrix.matrix[i])?;
}
}
Filter::GradientBevelFilter(ref bevel) => {
self.write_u8(7)?;
self.write_u8(bevel.colors.len() as u8)?;
for gradient_record in &bevel.colors {
self.write_rgba(&gradient_record.color)?;
}
for gradient_record in &bevel.colors {
self.write_u8(gradient_record.ratio)?;
}
self.write_fixed16(bevel.blur_x)?;
self.write_fixed16(bevel.blur_y)?;
self.write_fixed16(bevel.angle)?;
self.write_fixed16(bevel.distance)?;
self.write_fixed8(bevel.strength)?;
self.write_bit(bevel.is_inner)?;
self.write_bit(bevel.is_knockout)?;
self.write_bit(true)?;
self.write_bit(bevel.is_on_top)?;
self.write_ubits(4, bevel.num_passes.into())?;
}
}
self.flush_bits()?;
Ok(())
}
fn write_clip_actions(&mut self, clip_actions: &[ClipAction]) -> Result<()> {
self.write_u16(0)?; // Reserved
{
let mut all_events = EnumSet::new();
for action in clip_actions {
all_events |= action.events;
}
self.write_clip_event_flags(all_events)?;
}
for action in clip_actions {
self.write_clip_event_flags(action.events)?;
let action_length =
action.action_data.len() as u32 + if action.key_code.is_some() { 1 } else { 0 };
self.write_u32(action_length)?;
if let Some(k) = action.key_code {
self.write_u8(k)?;
}
self.output.write_all(&action.action_data)?;
}
if self.version <= 5 {
self.write_u16(0)?;
} else {
self.write_u32(0)?;
}
Ok(())
}
fn write_clip_event_flags(&mut self, clip_events: EnumSet<ClipEventFlag>) -> Result<()> {
// TODO: Assert proper version.
self.write_bit(clip_events.contains(ClipEventFlag::KeyUp))?;
self.write_bit(clip_events.contains(ClipEventFlag::KeyDown))?;
self.write_bit(clip_events.contains(ClipEventFlag::MouseUp))?;
self.write_bit(clip_events.contains(ClipEventFlag::MouseDown))?;
self.write_bit(clip_events.contains(ClipEventFlag::MouseMove))?;
self.write_bit(clip_events.contains(ClipEventFlag::Unload))?;
self.write_bit(clip_events.contains(ClipEventFlag::EnterFrame))?;
self.write_bit(clip_events.contains(ClipEventFlag::Load))?;
self.write_bit(clip_events.contains(ClipEventFlag::DragOver))?;
self.write_bit(clip_events.contains(ClipEventFlag::RollOut))?;
self.write_bit(clip_events.contains(ClipEventFlag::RollOver))?;
self.write_bit(clip_events.contains(ClipEventFlag::ReleaseOutside))?;
self.write_bit(clip_events.contains(ClipEventFlag::Release))?;
self.write_bit(clip_events.contains(ClipEventFlag::Press))?;
self.write_bit(clip_events.contains(ClipEventFlag::Initialize))?;
self.write_bit(clip_events.contains(ClipEventFlag::Data))?;
if self.version >= 6 {
self.write_ubits(5, 0)?;
self.write_bit(clip_events.contains(ClipEventFlag::Construct))?;
self.write_bit(clip_events.contains(ClipEventFlag::KeyPress))?;
self.write_bit(clip_events.contains(ClipEventFlag::DragOut))?;
self.write_u8(0)?;
}
self.flush_bits()?;
Ok(())
}
fn write_sound_stream_head(
&mut self,
stream_head: &SoundStreamHead,
version: u8,
) -> Result<()> {
let tag_code = if version >= 2 {
TagCode::SoundStreamHead2
} else {
TagCode::SoundStreamHead
};
// MP3 compression has added latency seek field.
let length = if stream_head.stream_format.compression == AudioCompression::Mp3 {
6
} else {
4
};
self.write_tag_header(tag_code, length)?;
self.write_sound_format(&stream_head.playback_format)?;
self.write_sound_format(&stream_head.stream_format)?;
self.write_u16(stream_head.num_samples_per_block)?;
if stream_head.stream_format.compression == AudioCompression::Mp3 {
self.write_i16(stream_head.latency_seek)?;
}
Ok(())
}
fn write_sound_format(&mut self, sound_format: &SoundFormat) -> Result<()> {
self.write_ubits(
4,
match sound_format.compression {
AudioCompression::UncompressedUnknownEndian => 0,
AudioCompression::Adpcm => 1,
AudioCompression::Mp3 => 2,
AudioCompression::Uncompressed => 3,
AudioCompression::Nellymoser16Khz => 4,
AudioCompression::Nellymoser8Khz => 5,
AudioCompression::Nellymoser => 6,
AudioCompression::Speex => 11,
},
)?;
self.write_ubits(
2,
match sound_format.sample_rate {
5512 => 0,
11025 => 1,
22050 => 2,
44100 => 3,
_ => return Err(Error::invalid_data("Invalid sample rate.")),
},
)?;
self.write_bit(sound_format.is_16_bit)?;
self.write_bit(sound_format.is_stereo)?;
self.flush_bits()?;
Ok(())
}
fn write_sound_info(&mut self, sound_info: &SoundInfo) -> Result<()> {
let flags = match sound_info.event {
SoundEvent::Event => 0b00_0000u8,
SoundEvent::Start => 0b01_0000u8,
SoundEvent::Stop => 0b10_0000u8,
} | if sound_info.in_sample.is_some() {
0b1
} else {
0
} | if sound_info.out_sample.is_some() {
0b10
} else {
0
} | if sound_info.num_loops > 1 { 0b100 } else { 0 }
| if sound_info.envelope.is_some() {
0b1000
} else {
0
};
self.write_u8(flags)?;
if let Some(n) = sound_info.in_sample {
self.write_u32(n)?;
}
if let Some(n) = sound_info.out_sample {
self.write_u32(n)?;
}
if sound_info.num_loops > 1 {
self.write_u16(sound_info.num_loops)?;
}
if let Some(ref envelope) = sound_info.envelope {
self.write_u8(envelope.len() as u8)?;
for point in envelope {
self.write_u32(point.sample)?;
self.write_u16((point.left_volume * 32768f32) as u16)?;
self.write_u16((point.right_volume * 32768f32) as u16)?;
}
}
Ok(())
}
fn write_define_font_2(&mut self, font: &Font) -> Result<()> {
let mut buf = Vec::new();
{
let num_glyphs = font.glyphs.len();
// We must write the glyph shapes into a temporary buffer
// so that we can calculate their offsets.
let mut offsets = vec![];
let mut has_wide_offsets = false;
let has_wide_codes = !font.is_ansi;
let mut shape_buf = Vec::new();
{
let mut shape_writer = Writer::new(&mut shape_buf, self.version);
// ShapeTable
shape_writer.num_fill_bits = 1;
shape_writer.num_line_bits = 0;
for glyph in &font.glyphs {
// Store offset for later.
let offset = num_glyphs * 4 + shape_writer.output.len();
offsets.push(offset);
if offset > 0xFFFF {
has_wide_offsets = true;
}
shape_writer.write_ubits(4, 1)?;
shape_writer.write_ubits(4, 0)?;
for shape_record in &glyph.shape_records {
shape_writer.write_shape_record(shape_record, 1)?;
}
// End shape record.
shape_writer.write_ubits(6, 0)?;
shape_writer.flush_bits()?;
}
}
let mut writer = Writer::new(&mut buf, self.version);
writer.write_character_id(font.id)?;
writer.write_u8(
if font.layout.is_some() { 0b10000000 } else { 0 }
| if font.is_shift_jis { 0b1000000 } else { 0 }
| if font.is_small_text { 0b100000 } else { 0 }
| if font.is_ansi { 0b10000 } else { 0 }
| if has_wide_offsets { 0b1000 } else { 0 }
| if has_wide_codes { 0b100 } else { 0 }
| if font.is_italic { 0b10 } else { 0 }
| if font.is_bold { 0b1 } else { 0 },
)?;
writer.write_language(font.language)?;
writer.write_u8(font.name.len() as u8)?;
writer.output.write_all(font.name.as_bytes())?;
writer.write_u16(num_glyphs as u16)?;
// If there are no glyphs, then the following tables are omitted.
if num_glyphs > 0 {
// OffsetTable
for offset in offsets {
if has_wide_offsets {
writer.write_u32(offset as u32)?;
} else {
writer.write_u16(offset as u16)?;
}
}
// CodeTableOffset
let code_table_offset =
(num_glyphs + 1) * if has_wide_offsets { 4 } else { 2 } + shape_buf.len();
if has_wide_offsets {
writer.write_u32(code_table_offset as u32)?;
} else {
writer.write_u16(code_table_offset as u16)?;
}
writer.output.write_all(&shape_buf)?;
// CodeTable
for glyph in &font.glyphs {
if has_wide_codes {
writer.write_u16(glyph.code)?;
} else {
writer.write_u8(glyph.code as u8)?;
}
}
}
if let Some(ref layout) = font.layout {
writer.write_u16(layout.ascent)?;
writer.write_u16(layout.descent)?;
writer.write_i16(layout.leading)?;
for glyph in &font.glyphs {
writer.write_i16(
glyph
.advance
.ok_or_else(|| Error::invalid_data("glyph.advance cannot be None"))?,
)?;
}
for glyph in &font.glyphs {
writer.write_rectangle(
glyph
.bounds
.as_ref()
.ok_or_else(|| Error::invalid_data("glyph.bounds cannot be None"))?,
)?;
}
writer.write_u16(layout.kerning.len() as u16)?;
for kerning_record in &layout.kerning {
writer.write_kerning_record(kerning_record, has_wide_codes)?;
}
}
}
let tag_code = if font.version == 2 {
TagCode::DefineFont2
} else {
TagCode::DefineFont3
};
self.write_tag_header(tag_code, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_font_4(&mut self, font: &Font4) -> Result<()> {
let mut tag_len = 4 + font.name.len();
if let Some(ref data) = font.data {
tag_len += data.len()
};
self.write_tag_header(TagCode::DefineFont4, tag_len as u32)?;
self.write_character_id(font.id)?;
self.write_u8(
if font.data.is_some() { 0b100 } else { 0 }
| if font.is_italic { 0b10 } else { 0 }
| if font.is_bold { 0b1 } else { 0 },
)?;
self.write_c_string(&font.name)?;
if let Some(ref data) = font.data {
self.output.write_all(data)?;
}
Ok(())
}
fn write_kerning_record(
&mut self,
kerning: &KerningRecord,
has_wide_codes: bool,
) -> Result<()> {
if has_wide_codes {
self.write_u16(kerning.left_code)?;
self.write_u16(kerning.right_code)?;
} else {
self.write_u8(kerning.left_code as u8)?;
self.write_u8(kerning.right_code as u8)?;
}
self.write_i16(kerning.adjustment.get() as i16)?; // TODO(Herschel): Handle overflow
Ok(())
}
fn write_define_text(&mut self, text: &Text) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_character_id(text.id)?;
writer.write_rectangle(&text.bounds)?;
writer.write_matrix(&text.matrix)?;
let num_glyph_bits = text
.records
.iter()
.flat_map(|r| r.glyphs.iter().map(|g| count_ubits(g.index)))
.max()
.unwrap_or(0);
let num_advance_bits = text
.records
.iter()
.flat_map(|r| r.glyphs.iter().map(|g| count_sbits(g.advance)))
.max()
.unwrap_or(0);
writer.write_u8(num_glyph_bits)?;
writer.write_u8(num_advance_bits)?;
for record in &text.records {
let flags = 0b10000000
| if record.font_id.is_some() { 0b1000 } else { 0 }
| if record.color.is_some() { 0b100 } else { 0 }
| if record.y_offset.is_some() { 0b10 } else { 0 }
| if record.x_offset.is_some() { 0b1 } else { 0 };
writer.write_u8(flags)?;
if let Some(id) = record.font_id {
writer.write_character_id(id)?;
}
if let Some(ref color) = record.color {
writer.write_rgb(color)?;
}
if let Some(x) = record.x_offset {
writer.write_i16(x.get() as i16)?; // TODO(Herschel): Handle overflow.
}
if let Some(y) = record.y_offset {
writer.write_i16(y.get() as i16)?;
}
if let Some(height) = record.height {
writer.write_u16(height.get() as u16)?;
}
writer.write_u8(record.glyphs.len() as u8)?;
for glyph in &record.glyphs {
writer.write_ubits(num_glyph_bits, glyph.index)?;
writer.write_sbits(num_advance_bits, glyph.advance)?;
}
}
writer.write_u8(0)?; // End of text records.
}
self.write_tag_header(TagCode::DefineText, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_edit_text(&mut self, edit_text: &EditText) -> Result<()> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, self.version);
writer.write_character_id(edit_text.id)?;
writer.write_rectangle(&edit_text.bounds)?;
let flags = if edit_text.initial_text.is_some() {
0b10000000
} else {
0
} | if edit_text.is_word_wrap { 0b1000000 } else { 0 }
| if edit_text.is_multiline { 0b100000 } else { 0 }
| if edit_text.is_password { 0b10000 } else { 0 }
| if edit_text.is_read_only { 0b1000 } else { 0 }
| if edit_text.color.is_some() { 0b100 } else { 0 }
| if edit_text.max_length.is_some() {
0b10
} else {
0
}
| if edit_text.font_id.is_some() { 0b1 } else { 0 };
let flags2 = if edit_text.font_class_name.is_some() {
0b10000000
} else {
0
} | if edit_text.is_auto_size { 0b1000000 } else { 0 }
| if edit_text.layout.is_some() {
0b100000
} else {
0
}
| if !edit_text.is_selectable { 0b10000 } else { 0 }
| if edit_text.has_border { 0b1000 } else { 0 }
| if edit_text.was_static { 0b100 } else { 0 }
| if edit_text.is_html { 0b10 } else { 0 }
| if !edit_text.is_device_font { 0b1 } else { 0 };
writer.write_u8(flags)?;
writer.write_u8(flags2)?;
if let Some(font_id) = edit_text.font_id {
writer.write_character_id(font_id)?;
}
// TODO(Herschel): Check SWF version.
if let Some(ref class) = edit_text.font_class_name {
writer.write_c_string(class)?;
}
// TODO(Herschel): Height only exists iff HasFontId, maybe for HasFontClass too?
if let Some(height) = edit_text.height {
writer.write_u16(height.get() as u16)?
}
if let Some(ref color) = edit_text.color {
writer.write_rgba(color)?
}
if let Some(len) = edit_text.max_length {
writer.write_u16(len)?;
}
if let Some(ref layout) = edit_text.layout {
writer.write_u8(match layout.align {
TextAlign::Left => 0,
TextAlign::Right => 1,
TextAlign::Center => 2,
TextAlign::Justify => 3,
})?;
writer.write_u16(layout.left_margin.get() as u16)?; // TODO: Handle overflow
writer.write_u16(layout.right_margin.get() as u16)?;
writer.write_u16(layout.indent.get() as u16)?;
writer.write_i16(layout.leading.get() as i16)?;
}
writer.write_c_string(&edit_text.variable_name)?;
if let Some(ref text) = edit_text.initial_text {
writer.write_c_string(text)?;
}
}
self.write_tag_header(TagCode::DefineEditText, buf.len() as u32)?;
self.output.write_all(&buf)?;
Ok(())
}
fn write_define_video_stream(&mut self, video: &DefineVideoStream) -> Result<()> {
self.write_tag_header(TagCode::DefineVideoStream, 10)?;
self.write_character_id(video.id)?;
self.write_u16(video.num_frames)?;
self.write_u16(video.width)?;
self.write_u16(video.height)?;
self.write_u8(
match video.deblocking {
VideoDeblocking::UseVideoPacketValue => 0b000_0,
VideoDeblocking::None => 0b001_0,
VideoDeblocking::Level1 => 0b010_0,
VideoDeblocking::Level2 => 0b011_0,
VideoDeblocking::Level3 => 0b100_0,
VideoDeblocking::Level4 => 0b101_0,
} | if video.is_smoothed { 0b1 } else { 0 },
)?;
self.write_u8(match video.codec {
VideoCodec::H263 => 2,
VideoCodec::ScreenVideo => 3,
VideoCodec::VP6 => 4,
VideoCodec::VP6WithAlpha => 5,
})?;
Ok(())
}
fn write_product_info(&mut self, product_info: &ProductInfo) -> Result<()> {
self.write_tag_header(TagCode::ProductInfo, 26)?;
self.write_u32(product_info.product_id)?;
self.write_u32(product_info.edition)?;
self.write_u8(product_info.major_version)?;
self.write_u8(product_info.minor_version)?;
self.write_u64(product_info.build_number)?;
self.write_u64(product_info.compilation_date)?;
Ok(())
}
fn write_debug_id(&mut self, debug_id: &DebugId) -> Result<()> {
self.get_inner().write_all(debug_id)?;
Ok(())
}
fn write_tag_header(&mut self, tag_code: TagCode, length: u32) -> Result<()> {
self.write_tag_code_and_length(tag_code as u16, length)
}
fn write_tag_code_and_length(&mut self, tag_code: u16, length: u32) -> Result<()> {
// TODO: Test for tag code/length overflow.
let mut tag_code_and_length: u16 = tag_code << 6;
if length < 0b111111 {
tag_code_and_length |= length as u16;
self.write_u16(tag_code_and_length)?;
} else {
tag_code_and_length |= 0b111111;
self.write_u16(tag_code_and_length)?;
self.write_u32(length)?;
}
Ok(())
}
fn write_tag_list(&mut self, tags: &[Tag]) -> Result<()> {
// TODO: Better error handling. Can skip errored tags, unless EOF.
for tag in tags {
self.write_tag(tag)?;
}
// Implicit end tag.
self.write_tag(&Tag::End)?;
Ok(())
}
}
fn count_ubits(mut n: u32) -> u8 {
let mut num_bits = 0;
while n > 0 {
n >>= 1;
num_bits += 1;
}
num_bits
}
fn count_sbits(n: i32) -> u8 {
if n == 0 {
0
} else if n == -1 {
1
} else if n < 0 {
count_ubits((!n) as u32) + 1
} else {
count_ubits(n as u32) + 1
}
}
fn count_sbits_twips(n: Twips) -> u8 {
let n = n.get();
if n == 0 {
0
} else if n == -1 {
1
} else if n < 0 {
count_ubits((!n) as u32) + 1
} else {
count_ubits(n as u32) + 1
}
}
fn count_fbits(n: f32) -> u8 {
count_sbits((n * 65536f32) as i32)
}
#[cfg(test)]
mod tests {
use super::Writer;
use super::*;
use crate::test_data;
fn new_swf() -> Swf {
Swf {
header: Header {
version: 13,
compression: Compression::Zlib,
stage_size: Rectangle {
x_min: Twips::from_pixels(0.0),
x_max: Twips::from_pixels(640.0),
y_min: Twips::from_pixels(0.0),
y_max: Twips::from_pixels(480.0),
},
frame_rate: 60.0,
num_frames: 1,
},
tags: vec![],
}
}
#[test]
fn write_swfs() {
fn write_dummy_swf(compression: Compression) -> Result<()> {
let mut buf = Vec::new();
let mut swf = new_swf();
swf.header.compression = compression;
write_swf(&swf, &mut buf)?;
Ok(())
}
assert!(
write_dummy_swf(Compression::None).is_ok(),
"Failed to write uncompressed SWF."
);
assert!(
write_dummy_swf(Compression::Zlib).is_ok(),
"Failed to write zlib SWF."
);
if cfg!(feature = "lzma") {
assert!(
write_dummy_swf(Compression::Lzma).is_ok(),
"Failed to write LZMA SWF."
);
}
}
#[test]
fn write_fixed8() {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_fixed8(0f32).unwrap();
writer.write_fixed8(1f32).unwrap();
writer.write_fixed8(6.5f32).unwrap();
writer.write_fixed8(-20.75f32).unwrap();
}
assert_eq!(
buf,
[
0b00000000, 0b00000000, 0b00000000, 0b00000001, 0b10000000, 0b00000110, 0b01000000,
0b11101011
]
);
}
#[test]
fn write_encoded_u32() {
fn write_to_buf(n: u32) -> Vec<u8> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_encoded_u32(n).unwrap();
}
buf
}
assert_eq!(write_to_buf(0), [0]);
assert_eq!(write_to_buf(2), [2]);
assert_eq!(write_to_buf(129), [0b1_0000001, 0b0_0000001]);
assert_eq!(
write_to_buf(0b1100111_0000001_0000001),
[0b1_0000001, 0b1_0000001, 0b0_1100111]
);
assert_eq!(
write_to_buf(0b1111_0000000_0000000_0000000_0000000u32),
[
0b1_0000000,
0b1_0000000,
0b1_0000000,
0b1_0000000,
0b0000_1111
]
);
}
#[test]
fn write_bit() {
let bits = [
false, true, false, true, false, true, false, true, false, false, true, false, false,
true, false, true,
];
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
for b in &bits {
writer.write_bit(*b).unwrap();
}
}
assert_eq!(buf, [0b01010101, 0b00100101]);
}
#[test]
fn write_ubits() {
let num_bits = 2;
let nums = [1, 1, 1, 1, 0, 2, 1, 1];
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
for n in &nums {
writer.write_ubits(num_bits, *n).unwrap();
}
writer.flush_bits().unwrap();
}
assert_eq!(buf, [0b01010101, 0b00100101]);
}
#[test]
fn write_sbits() {
let num_bits = 2;
let nums = [1, 1, 1, 1, 0, -2, 1, 1];
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
for n in &nums {
writer.write_sbits(num_bits, *n).unwrap();
}
writer.flush_bits().unwrap();
}
assert_eq!(buf, [0b01010101, 0b00100101]);
}
#[test]
fn write_fbits() {
let num_bits = 18;
let nums = [1f32, -1f32];
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
for n in &nums {
writer.write_fbits(num_bits, *n).unwrap();
}
writer.flush_bits().unwrap();
}
assert_eq!(
buf,
[
0b01_000000,
0b00000000,
0b00_11_0000,
0b00000000,
0b0000_0000
]
);
}
#[test]
fn count_ubits() {
assert_eq!(super::count_ubits(0), 0u8);
assert_eq!(super::count_ubits(1u32), 1);
assert_eq!(super::count_ubits(2u32), 2);
assert_eq!(super::count_ubits(0b_00111101_00000000u32), 14);
}
#[test]
fn count_sbits() {
assert_eq!(super::count_sbits(0), 0u8);
assert_eq!(super::count_sbits(1), 2u8);
assert_eq!(super::count_sbits(2), 3u8);
assert_eq!(super::count_sbits(0b_00111101_00000000), 15u8);
assert_eq!(super::count_sbits(-1), 1u8);
assert_eq!(super::count_sbits(-2), 2u8);
assert_eq!(super::count_sbits(-0b_00110101_01010101), 15u8);
}
#[test]
fn write_c_string() {
{
let mut buf = Vec::new();
{
// TODO: What if I use a cursor instead of buf ?
let mut writer = Writer::new(&mut buf, 1);
writer.write_c_string("Hello!").unwrap();
}
assert_eq!(buf, "Hello!\0".bytes().collect::<Vec<_>>());
}
{
let mut buf = Vec::new();
{
// TODO: What if I use a cursor instead of buf ?
let mut writer = Writer::new(&mut buf, 1);
writer.write_c_string("😀😂!🐼").unwrap();
}
assert_eq!(buf, "😀😂!🐼\0".bytes().collect::<Vec<_>>());
}
}
#[test]
fn write_rectangle_zero() {
let rect: Rectangle = Default::default();
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_rectangle(&rect).unwrap();
writer.flush_bits().unwrap();
}
assert_eq!(buf, [0]);
}
#[test]
fn write_rectangle_signed() {
let rect = Rectangle {
x_min: Twips::from_pixels(-1.0),
x_max: Twips::from_pixels(1.0),
y_min: Twips::from_pixels(-1.0),
y_max: Twips::from_pixels(1.0),
};
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_rectangle(&rect).unwrap();
writer.flush_bits().unwrap();
}
assert_eq!(buf, [0b_00110_101, 0b100_01010, 0b0_101100_0, 0b_10100_000]);
}
#[test]
fn write_color() {
{
let color = Color {
r: 1,
g: 128,
b: 255,
a: 255,
};
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_rgb(&color).unwrap();
}
assert_eq!(buf, [1, 128, 255]);
}
{
let color = Color {
r: 1,
g: 2,
b: 3,
a: 11,
};
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_rgba(&color).unwrap();
}
assert_eq!(buf, [1, 2, 3, 11]);
}
}
#[test]
fn write_matrix() {
fn write_to_buf(m: &Matrix) -> Vec<u8> {
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_matrix(m).unwrap();
writer.flush_bits().unwrap();
}
buf
}
let m = Matrix::identity();
assert_eq!(write_to_buf(&m), [0]);
}
#[test]
fn write_tags() {
for (swf_version, tag, expected_tag_bytes) in test_data::tag_tests() {
let mut written_tag_bytes = Vec::new();
Writer::new(&mut written_tag_bytes, swf_version)
.write_tag(&tag)
.unwrap();
if written_tag_bytes != expected_tag_bytes {
panic!(
"Error reading tag.\nTag:\n{:?}\n\nWrote:\n{:?}\n\nExpected:\n{:?}",
tag, written_tag_bytes, expected_tag_bytes
);
}
}
}
#[test]
fn write_tag_to_buf_list() {
{
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_tag_list(&[]).unwrap();
}
assert_eq!(buf, [0, 0]);
}
{
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer.write_tag_list(&[Tag::ShowFrame]).unwrap();
}
assert_eq!(buf, [0b01_000000, 0b00000000, 0, 0]);
}
{
let mut buf = Vec::new();
{
let mut writer = Writer::new(&mut buf, 1);
writer
.write_tag_list(&[
Tag::Unknown {
tag_code: 512,
data: vec![0; 100],
},
Tag::ShowFrame,
])
.unwrap();
}
let mut expected = vec![0b00_111111, 0b10000000, 100, 0, 0, 0];
expected.extend_from_slice(&[0; 100]);
expected.extend_from_slice(&[0b01_000000, 0b00000000, 0, 0]);
assert_eq!(buf, expected);
}
}
}
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