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#[cfg(any(feature = "alloc", feature = "std", test))]
use alloc::string::String;
use core::cmp;
#[cfg(any(feature = "alloc", feature = "std", test))]
use core::str;
use crate::encode::add_padding;
use crate::engine::{Config, Engine};
/// The output mechanism for ChunkedEncoder's encoded bytes.
pub trait Sink {
type Error;
/// Handle a chunk of encoded base64 data (as UTF-8 bytes)
fn write_encoded_bytes(&mut self, encoded: &[u8]) -> Result<(), Self::Error>;
}
const BUF_SIZE: usize = 1024;
/// A base64 encoder that emits encoded bytes in chunks without heap allocation.
pub struct ChunkedEncoder<'e, E: Engine + ?Sized> {
engine: &'e E,
max_input_chunk_len: usize,
}
impl<'e, E: Engine + ?Sized> ChunkedEncoder<'e, E> {
pub fn new(engine: &'e E) -> ChunkedEncoder<'e, E> {
ChunkedEncoder {
engine,
max_input_chunk_len: max_input_length(BUF_SIZE, engine.config().encode_padding()),
}
}
pub fn encode<S: Sink>(&self, bytes: &[u8], sink: &mut S) -> Result<(), S::Error> {
let mut encode_buf: [u8; BUF_SIZE] = [0; BUF_SIZE];
let mut input_index = 0;
while input_index < bytes.len() {
// either the full input chunk size, or it's the last iteration
let input_chunk_len = cmp::min(self.max_input_chunk_len, bytes.len() - input_index);
let chunk = &bytes[input_index..(input_index + input_chunk_len)];
let mut b64_bytes_written = self.engine.internal_encode(chunk, &mut encode_buf);
input_index += input_chunk_len;
let more_input_left = input_index < bytes.len();
if self.engine.config().encode_padding() && !more_input_left {
// no more input, add padding if needed. Buffer will have room because
// max_input_length leaves room for it.
b64_bytes_written += add_padding(bytes.len(), &mut encode_buf[b64_bytes_written..]);
}
sink.write_encoded_bytes(&encode_buf[0..b64_bytes_written])?;
}
Ok(())
}
}
/// Calculate the longest input that can be encoded for the given output buffer size.
///
/// If the config requires padding, two bytes of buffer space will be set aside so that the last
/// chunk of input can be encoded safely.
///
/// The input length will always be a multiple of 3 so that no encoding state has to be carried over
/// between chunks.
fn max_input_length(encoded_buf_len: usize, padded: bool) -> usize {
let effective_buf_len = if padded {
// make room for padding
encoded_buf_len
.checked_sub(2)
.expect("Don't use a tiny buffer")
} else {
encoded_buf_len
};
// No padding, so just normal base64 expansion.
(effective_buf_len / 4) * 3
}
// A really simple sink that just appends to a string
#[cfg(any(feature = "alloc", feature = "std", test))]
pub(crate) struct StringSink<'a> {
string: &'a mut String,
}
#[cfg(any(feature = "alloc", feature = "std", test))]
impl<'a> StringSink<'a> {
pub(crate) fn new(s: &mut String) -> StringSink {
StringSink { string: s }
}
}
#[cfg(any(feature = "alloc", feature = "std", test))]
impl<'a> Sink for StringSink<'a> {
type Error = ();
fn write_encoded_bytes(&mut self, s: &[u8]) -> Result<(), Self::Error> {
self.string.push_str(str::from_utf8(s).unwrap());
Ok(())
}
}
#[cfg(test)]
pub mod tests {
use rand::{
distributions::{Distribution, Uniform},
Rng, SeedableRng,
};
use crate::{
alphabet::STANDARD,
engine::general_purpose::{GeneralPurpose, GeneralPurposeConfig, PAD},
tests::random_engine,
};
use super::*;
#[test]
fn chunked_encode_empty() {
assert_eq!("", chunked_encode_str(&[], PAD));
}
#[test]
fn chunked_encode_intermediate_fast_loop() {
// > 8 bytes input, will enter the pretty fast loop
assert_eq!("Zm9vYmFyYmF6cXV4", chunked_encode_str(b"foobarbazqux", PAD));
}
#[test]
fn chunked_encode_fast_loop() {
// > 32 bytes input, will enter the uber fast loop
assert_eq!(
"Zm9vYmFyYmF6cXV4cXV1eGNvcmdlZ3JhdWx0Z2FycGx5eg==",
chunked_encode_str(b"foobarbazquxquuxcorgegraultgarplyz", PAD)
);
}
#[test]
fn chunked_encode_slow_loop_only() {
// < 8 bytes input, slow loop only
assert_eq!("Zm9vYmFy", chunked_encode_str(b"foobar", PAD));
}
#[test]
fn chunked_encode_matches_normal_encode_random_string_sink() {
let helper = StringSinkTestHelper;
chunked_encode_matches_normal_encode_random(&helper);
}
#[test]
fn max_input_length_no_pad() {
assert_eq!(768, max_input_length(1024, false));
}
#[test]
fn max_input_length_with_pad_decrements_one_triple() {
assert_eq!(765, max_input_length(1024, true));
}
#[test]
fn max_input_length_with_pad_one_byte_short() {
assert_eq!(765, max_input_length(1025, true));
}
#[test]
fn max_input_length_with_pad_fits_exactly() {
assert_eq!(768, max_input_length(1026, true));
}
#[test]
fn max_input_length_cant_use_extra_single_encoded_byte() {
assert_eq!(300, max_input_length(401, false));
}
pub fn chunked_encode_matches_normal_encode_random<S: SinkTestHelper>(sink_test_helper: &S) {
let mut input_buf: Vec<u8> = Vec::new();
let mut output_buf = String::new();
let mut rng = rand::rngs::SmallRng::from_entropy();
let input_len_range = Uniform::new(1, 10_000);
for _ in 0..5_000 {
input_buf.clear();
output_buf.clear();
let buf_len = input_len_range.sample(&mut rng);
for _ in 0..buf_len {
input_buf.push(rng.gen());
}
let engine = random_engine(&mut rng);
let chunk_encoded_string = sink_test_helper.encode_to_string(&engine, &input_buf);
engine.encode_string(&input_buf, &mut output_buf);
assert_eq!(output_buf, chunk_encoded_string, "input len={}", buf_len);
}
}
fn chunked_encode_str(bytes: &[u8], config: GeneralPurposeConfig) -> String {
let mut s = String::new();
let mut sink = StringSink::new(&mut s);
let engine = GeneralPurpose::new(&STANDARD, config);
let encoder = ChunkedEncoder::new(&engine);
encoder.encode(bytes, &mut sink).unwrap();
s
}
// An abstraction around sinks so that we can have tests that easily to any sink implementation
pub trait SinkTestHelper {
fn encode_to_string<E: Engine>(&self, engine: &E, bytes: &[u8]) -> String;
}
struct StringSinkTestHelper;
impl SinkTestHelper for StringSinkTestHelper {
fn encode_to_string<E: Engine>(&self, engine: &E, bytes: &[u8]) -> String {
let encoder = ChunkedEncoder::new(engine);
let mut s = String::new();
let mut sink = StringSink::new(&mut s);
encoder.encode(bytes, &mut sink).unwrap();
s
}
}
}
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