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mozilla-central/third_party/rust/base64/src/read/decoder.rs (file symbol)

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use crate::{engine::Engine, DecodeError, PAD_BYTE};

use std::{cmp, fmt, io};

// This should be large, but it has to fit on the stack.

pub(crate) const BUF_SIZE: usize = 1024;

// 4 bytes of base64 data encode 3 bytes of raw data (modulo padding).

const BASE64_CHUNK_SIZE: usize = 4;

const DECODED_CHUNK_SIZE: usize = 3;

/// A `Read` implementation that decodes base64 data read from an underlying reader.

///

/// # Examples

///

/// ```

/// use std::io::Read;

/// use std::io::Cursor;

/// use base64::engine::general_purpose;

///

/// // use a cursor as the simplest possible `Read` -- in real code this is probably a file, etc.

/// let mut wrapped_reader = Cursor::new(b"YXNkZg==");

/// let mut decoder = base64::read::DecoderReader::new(

///     &mut wrapped_reader,

///     &general_purpose::STANDARD);

///

/// // handle errors as you normally would

/// let mut result = Vec::new();

/// decoder.read_to_end(&mut result).unwrap();

///

/// assert_eq!(b"asdf", &result[..]);

///

/// ```

pub struct DecoderReader<'e, E: Engine, R: io::Read> {

    engine: &'e E,

    /// Where b64 data is read from

    inner: R,

    // Holds b64 data read from the delegate reader.

    b64_buffer: [u8; BUF_SIZE],

    // The start of the pending buffered data in b64_buffer.

    b64_offset: usize,

    // The amount of buffered b64 data.

    b64_len: usize,

    // Since the caller may provide us with a buffer of size 1 or 2 that's too small to copy a

    // decoded chunk in to, we have to be able to hang on to a few decoded bytes.

    // Technically we only need to hold 2 bytes but then we'd need a separate temporary buffer to

    // decode 3 bytes into and then juggle copying one byte into the provided read buf and the rest

    // into here, which seems like a lot of complexity for 1 extra byte of storage.

    decoded_buffer: [u8; DECODED_CHUNK_SIZE],

    // index of start of decoded data

    decoded_offset: usize,

    // length of decoded data

    decoded_len: usize,

    // used to provide accurate offsets in errors

    total_b64_decoded: usize,

    // offset of previously seen padding, if any

    padding_offset: Option<usize>,

impl<'e, E: Engine, R: io::Read> fmt::Debug for DecoderReader<'e, E, R> {

    fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {

        f.debug_struct("DecoderReader")

            .field("b64_offset", &self.b64_offset)

            .field("b64_len", &self.b64_len)

            .field("decoded_buffer", &self.decoded_buffer)

            .field("decoded_offset", &self.decoded_offset)

            .field("decoded_len", &self.decoded_len)

            .field("total_b64_decoded", &self.total_b64_decoded)

            .field("padding_offset", &self.padding_offset)

            .finish()

impl<'e, E: Engine, R: io::Read> DecoderReader<'e, E, R> {

    /// Create a new decoder that will read from the provided reader `r`.

    pub fn new(reader: R, engine: &'e E) -> Self {

        DecoderReader {

            engine,

            inner: reader,

            b64_buffer: [0; BUF_SIZE],

            b64_offset: 0,

            b64_len: 0,

            decoded_buffer: [0; DECODED_CHUNK_SIZE],

            decoded_offset: 0,

            decoded_len: 0,

            total_b64_decoded: 0,

            padding_offset: None,

    /// Write as much as possible of the decoded buffer into the target buffer.

    /// Must only be called when there is something to write and space to write into.

    /// Returns a Result with the number of (decoded) bytes copied.

    fn flush_decoded_buf(&mut self, buf: &mut [u8]) -> io::Result<usize> {

        debug_assert!(self.decoded_len > 0);

        debug_assert!(!buf.is_empty());

        let copy_len = cmp::min(self.decoded_len, buf.len());

        debug_assert!(copy_len > 0);

        debug_assert!(copy_len <= self.decoded_len);

        buf[..copy_len].copy_from_slice(

            &self.decoded_buffer[self.decoded_offset..self.decoded_offset + copy_len],

);

        self.decoded_offset += copy_len;

        self.decoded_len -= copy_len;

        debug_assert!(self.decoded_len < DECODED_CHUNK_SIZE);

        Ok(copy_len)

    /// Read into the remaining space in the buffer after the current contents.

    /// Must only be called when there is space to read into in the buffer.

    /// Returns the number of bytes read.

    fn read_from_delegate(&mut self) -> io::Result<usize> {

        debug_assert!(self.b64_offset + self.b64_len < BUF_SIZE);

        let read = self

            .inner

            .read(&mut self.b64_buffer[self.b64_offset + self.b64_len..])?;

        self.b64_len += read;

        debug_assert!(self.b64_offset + self.b64_len <= BUF_SIZE);

        Ok(read)

    /// Decode the requested number of bytes from the b64 buffer into the provided buffer. It's the

    /// caller's responsibility to choose the number of b64 bytes to decode correctly.

///

    /// Returns a Result with the number of decoded bytes written to `buf`.

    fn decode_to_buf(&mut self, b64_len_to_decode: usize, buf: &mut [u8]) -> io::Result<usize> {

        debug_assert!(self.b64_len >= b64_len_to_decode);

        debug_assert!(self.b64_offset + self.b64_len <= BUF_SIZE);

        debug_assert!(!buf.is_empty());

        let b64_to_decode = &self.b64_buffer[self.b64_offset..self.b64_offset + b64_len_to_decode];

        let decode_metadata = self

            .engine

            .internal_decode(

                b64_to_decode,

                buf,

                self.engine.internal_decoded_len_estimate(b64_len_to_decode),

            .map_err(|e| match e {

                DecodeError::InvalidByte(offset, byte) => {

                    // This can be incorrect, but not in a way that probably matters to anyone:

                    // if there was padding handled in a previous decode, and we are now getting

                    // InvalidByte due to more padding, we should arguably report InvalidByte with

                    // PAD_BYTE at the original padding position (`self.padding_offset`), but we

                    // don't have a good way to tie those two cases together, so instead we

                    // just report the invalid byte as if the previous padding, and its possibly

                    // related downgrade to a now invalid byte, didn't happen.

                    DecodeError::InvalidByte(self.total_b64_decoded + offset, byte)

                DecodeError::InvalidLength => DecodeError::InvalidLength,

                DecodeError::InvalidLastSymbol(offset, byte) => {

                    DecodeError::InvalidLastSymbol(self.total_b64_decoded + offset, byte)

                DecodeError::InvalidPadding => DecodeError::InvalidPadding,

})

            .map_err(|e| io::Error::new(io::ErrorKind::InvalidData, e))?;

        if let Some(offset) = self.padding_offset {

            // we've already seen padding

            if decode_metadata.decoded_len > 0 {

                // we read more after already finding padding; report error at first padding byte

                return Err(io::Error::new(

                    io::ErrorKind::InvalidData,

                    DecodeError::InvalidByte(offset, PAD_BYTE),

));

        self.padding_offset = self.padding_offset.or(decode_metadata

            .padding_offset

            .map(|offset| self.total_b64_decoded + offset));

        self.total_b64_decoded += b64_len_to_decode;

        self.b64_offset += b64_len_to_decode;

        self.b64_len -= b64_len_to_decode;

        debug_assert!(self.b64_offset + self.b64_len <= BUF_SIZE);

        Ok(decode_metadata.decoded_len)

    /// Unwraps this `DecoderReader`, returning the base reader which it reads base64 encoded

    /// input from.

///

    /// Because `DecoderReader` performs internal buffering, the state of the inner reader is

    /// unspecified. This function is mainly provided because the inner reader type may provide

    /// additional functionality beyond the `Read` implementation which may still be useful.

    pub fn into_inner(self) -> R {

        self.inner

impl<'e, E: Engine, R: io::Read> io::Read for DecoderReader<'e, E, R> {

    /// Decode input from the wrapped reader.

///

    /// Under non-error circumstances, this returns `Ok` with the value being the number of bytes

    /// written in `buf`.

///

    /// Where possible, this function buffers base64 to minimize the number of read() calls to the

    /// delegate reader.

///

    /// # Errors

///

    /// Any errors emitted by the delegate reader are returned. Decoding errors due to invalid

    /// base64 are also possible, and will have `io::ErrorKind::InvalidData`.

    fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> {

        if buf.is_empty() {

            return Ok(0);

        // offset == BUF_SIZE when we copied it all last time

        debug_assert!(self.b64_offset <= BUF_SIZE);

        debug_assert!(self.b64_offset + self.b64_len <= BUF_SIZE);

        debug_assert!(if self.b64_offset == BUF_SIZE {

            self.b64_len == 0

        } else {

            self.b64_len <= BUF_SIZE

});

        debug_assert!(if self.decoded_len == 0 {

            // can be = when we were able to copy the complete chunk

            self.decoded_offset <= DECODED_CHUNK_SIZE

        } else {

            self.decoded_offset < DECODED_CHUNK_SIZE

});

        // We shouldn't ever decode into decoded_buffer when we can't immediately write at least one

        // byte into the provided buf, so the effective length should only be 3 momentarily between

        // when we decode and when we copy into the target buffer.

        debug_assert!(self.decoded_len < DECODED_CHUNK_SIZE);

        debug_assert!(self.decoded_len + self.decoded_offset <= DECODED_CHUNK_SIZE);

        if self.decoded_len > 0 {

            // we have a few leftover decoded bytes; flush that rather than pull in more b64

            self.flush_decoded_buf(buf)

        } else {

            let mut at_eof = false;

            while self.b64_len < BASE64_CHUNK_SIZE {

                // Copy any bytes we have to the start of the buffer.

                self.b64_buffer

                    .copy_within(self.b64_offset..self.b64_offset + self.b64_len, 0);

                self.b64_offset = 0;

                // then fill in more data

                let read = self.read_from_delegate()?;

                if read == 0 {

                    // we never read into an empty buf, so 0 => we've hit EOF

                    at_eof = true;

                    break;

            if self.b64_len == 0 {

                debug_assert!(at_eof);

                // we must be at EOF, and we have no data left to decode

                return Ok(0);

};

            debug_assert!(if at_eof {

                // if we are at eof, we may not have a complete chunk

                self.b64_len > 0

            } else {

                // otherwise, we must have at least one chunk

                self.b64_len >= BASE64_CHUNK_SIZE

});

            debug_assert_eq!(0, self.decoded_len);

            if buf.len() < DECODED_CHUNK_SIZE {

                // caller requested an annoyingly short read

                // have to write to a tmp buf first to avoid double mutable borrow

                let mut decoded_chunk = [0_u8; DECODED_CHUNK_SIZE];

                // if we are at eof, could have less than BASE64_CHUNK_SIZE, in which case we have

                // to assume that these last few tokens are, in fact, valid (i.e. must be 2-4 b64

                // tokens, not 1, since 1 token can't decode to 1 byte).

                let to_decode = cmp::min(self.b64_len, BASE64_CHUNK_SIZE);

                let decoded = self.decode_to_buf(to_decode, &mut decoded_chunk[..])?;

                self.decoded_buffer[..decoded].copy_from_slice(&decoded_chunk[..decoded]);

                self.decoded_offset = 0;

                self.decoded_len = decoded;

                // can be less than 3 on last block due to padding

                debug_assert!(decoded <= 3);

                self.flush_decoded_buf(buf)

            } else {

                let b64_bytes_that_can_decode_into_buf = (buf.len() / DECODED_CHUNK_SIZE)

                    .checked_mul(BASE64_CHUNK_SIZE)

                    .expect("too many chunks");

                debug_assert!(b64_bytes_that_can_decode_into_buf >= BASE64_CHUNK_SIZE);

                let b64_bytes_available_to_decode = if at_eof {

                    self.b64_len

                } else {

                    // only use complete chunks

                    self.b64_len - self.b64_len % 4

};

                let actual_decode_len = cmp::min(

                    b64_bytes_that_can_decode_into_buf,

                    b64_bytes_available_to_decode,

);

                self.decode_to_buf(actual_decode_len, buf)