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extern crate deflate;

use std::borrow::Cow;
use std::error;
use std::fmt;
use std::io::{self, Write};
use std::mem;
use std::result;

use chunk;
use crc::Crc32;
use common::{Info, ColorType, BitDepth, Compression};
use filter::{FilterType, filter};
use traits::{WriteBytesExt, HasParameters, Parameter};

pub type Result<T> = result::Result<T, EncodingError>;

#[derive(Debug)]
pub enum EncodingError {
    IoError(io::Error),
    Format(Cow<'static, str>),
}

impl error::Error for EncodingError {
    fn description(&self) -> &str {
        use self::EncodingError::*;
        match *self {
            IoError(ref err) => err.description(),
            Format(ref desc) => &desc,
        }
    }
}

impl fmt::Display for EncodingError {
    fn fmt(&self, fmt: &mut fmt::Formatter) -> result::Result<(), fmt::Error> {
        write!(fmt, "{}", (self as &error::Error).description())
    }
}

impl From<io::Error> for EncodingError {
    fn from(err: io::Error) -> EncodingError {
        EncodingError::IoError(err)
    }
}
impl From<EncodingError> for io::Error {
    fn from(err: EncodingError) -> io::Error {
        io::Error::new(io::ErrorKind::Other, (&err as &error::Error).description())
    }
}

/// PNG Encoder
pub struct Encoder<W: Write> {
    w: W,
    info: Info,
}

impl<W: Write> Encoder<W> {
    pub fn new(w: W, width: u32, height: u32) -> Encoder<W> {
        let mut info = Info::default();
        info.width = width;
        info.height = height;
        Encoder { w: w, info: info }
    }

    pub fn write_header(self) -> Result<Writer<W>> {
        Writer::new(self.w, self.info).init()
    }
}

impl<W: Write> HasParameters for Encoder<W> {}

impl<W: Write> Parameter<Encoder<W>> for ColorType {
    fn set_param(self, this: &mut Encoder<W>) {
        this.info.color_type = self
    }
}

impl<W: Write> Parameter<Encoder<W>> for BitDepth {
    fn set_param(self, this: &mut Encoder<W>) {
        this.info.bit_depth = self
    }
}

/// Set compression param for a ```Compression``` or any type that can transform 
/// into a ```Compression```, notably ```deflate::Compression``` and 
/// ```deflate::CompressionOptions``` which "just work".
impl<W: Write, C: Into<Compression>> Parameter<Encoder<W>> for C {
    fn set_param(self, this: &mut Encoder<W>) {
        this.info.compression = self.into()
    }
}

impl <W: Write> Parameter<Encoder<W>> for FilterType {
    fn set_param(self, this: &mut Encoder<W>) {
        this.info.filter = self
    }
}

/// PNG writer
pub struct Writer<W: Write> {
    w: W,
    info: Info,
}

impl<W: Write> Writer<W> {
    fn new(w: W, info: Info) -> Writer<W> {
        let w = Writer { w: w, info: info };
        w
    }

    fn init(mut self) -> Result<Self> {
        try!(self.w.write_all(&[137, 80, 78, 71, 13, 10, 26, 10]));
        let mut data = [0; 13];
        try!((&mut data[..]).write_be(self.info.width));
        try!((&mut data[4..]).write_be(self.info.height));
        data[8] = self.info.bit_depth as u8;
        data[9] = self.info.color_type as u8;
        data[12] = if self.info.interlaced { 1 } else { 0 };
        try!(self.write_chunk(chunk::IHDR, &data));
        Ok(self)
    }

    pub fn write_chunk(&mut self, name: [u8; 4], data: &[u8]) -> Result<()> {
        try!(self.w.write_be(data.len() as u32));
        try!(self.w.write_all(&name));
        try!(self.w.write_all(data));
        let mut crc = Crc32::new();
        crc.update(&name);
        crc.update(data);
        try!(self.w.write_be(crc.checksum()));
        Ok(())
    }

    /// Writes the image data.
    pub fn write_image_data(&mut self, data: &[u8]) -> Result<()> {
        let bpp = self.info.bytes_per_pixel();
        let in_len = self.info.raw_row_length() - 1;
        let mut prev = vec![0; in_len];
        let mut current = vec![0; in_len];
        let data_size = in_len * self.info.height as usize;
        if data_size != data.len() {
            let message = format!("wrong data size, expected {} got {}", data_size, data.len());
            return Err(EncodingError::Format(message.into()));
        }
        let mut zlib = deflate::write::ZlibEncoder::new(Vec::new(), self.info.compression.clone());
        let filter_method = self.info.filter;
        for line in data.chunks(in_len) {
            current.copy_from_slice(&line);
            try!(zlib.write_all(&[filter_method as u8]));
            filter(filter_method, bpp, &prev, &mut current);
            try!(zlib.write_all(&current));
            mem::swap(&mut prev, &mut current);
        }
        self.write_chunk(chunk::IDAT, &try!(zlib.finish()))
    }
}

impl<W: Write> Drop for Writer<W> {
    fn drop(&mut self) {
        let _ = self.write_chunk(chunk::IEND, &[]);
    }
}

#[cfg(test)]
mod tests {
    use super::*;

    extern crate rand;
    extern crate glob;

    use self::rand::Rng;
    use std::{io, cmp};
    use std::io::Write;
    use std::fs::File;

    #[test]
    fn roundtrip() {
        // More loops = more random testing, but also more test wait time
        for _ in 0..10 {
            for path in glob::glob("tests/pngsuite/*.png").unwrap().map(|r| r.unwrap()) {
                if path.file_name().unwrap().to_str().unwrap().starts_with("x") {
                    // x* files are expected to fail to decode
                    continue;
                }
                // Decode image
                let decoder = ::Decoder::new(File::open(path).unwrap());
                let (info, mut reader) = decoder.read_info().unwrap();
                if info.line_size != 32 {
                    // TODO encoding only works with line size 32?
                    continue;
                }
                let mut buf = vec![0; info.buffer_size()];
                reader.next_frame(&mut buf).unwrap();
                // Encode decoded image
                let mut out = Vec::new();
                {
                    let mut wrapper = RandomChunkWriter {
                        rng: self::rand::thread_rng(),
                        w: &mut out
                    };

                    let mut encoder = Encoder::new(&mut wrapper, info.width, info.height).write_header().unwrap();
                    encoder.write_image_data(&buf).unwrap();
                }
                // Decode encoded decoded image
                let decoder = ::Decoder::new(&*out);
                let (info, mut reader) = decoder.read_info().unwrap();
                let mut buf2 = vec![0; info.buffer_size()];
                reader.next_frame(&mut buf2).unwrap();
                // check if the encoded image is ok:
                assert_eq!(buf, buf2);
            }
        }
    }

    #[test]
    fn expect_error_on_wrong_image_len() -> Result<()> {
        use std::io::Cursor;

        let width = 10;
        let height = 10;

        let output = vec![0u8; 1024];
        let writer = Cursor::new(output);
        let mut encoder = Encoder::new(writer, width as u32, height as u32);
        encoder.set(BitDepth::Eight);
        encoder.set(ColorType::RGB);
        let mut png_writer = encoder.write_header()?;

        let correct_image_size = width * height * 3;
        let image = vec![0u8; correct_image_size + 1];
        let result = png_writer.write_image_data(image.as_ref());
        assert!(result.is_err());

        Ok(())
    }

    /// A Writer that only writes a few bytes at a time
    struct RandomChunkWriter<'a, R: Rng, W: Write + 'a> {
        rng: R,
        w: &'a mut W
    }

    impl<'a, R: Rng, W: Write + 'a> Write for RandomChunkWriter<'a, R, W> {
        fn write(&mut self, buf: &[u8]) -> io::Result<usize> {
            // choose a random length to write
            let len = cmp::min(self.rng.gen_range(1, 50), buf.len());

            self.w.write(&buf[0..len])
        }

        fn flush(&mut self) -> io::Result<()> {
            self.w.flush()
        }
    }

}