module io // BufferedReader provides a buffered interface for a reader struct BufferedReader { mut: reader Reader buf []byte // current offset in the buffer offset int len int } // BufferedReaderConfig are options that can be given to a reader pub struct BufferedReaderConfig { reader Reader buf_cap int = 128 * 1024 // large for fast reading of big(ish) files } // new_buffered_reader creates new BufferedReader pub fn new_buffered_reader(o BufferedReaderConfig) &BufferedReader { assert o.buf_cap >= 2 // create r := &BufferedReader{ reader: o.reader buf: []byte{len: o.buf_cap, cap: o.buf_cap} offset: 0 } return r } // read fufills the Reader interface pub fn (mut r BufferedReader) read(mut buf []byte) ?int { // read data out of the buffer if we dont have any if r.offset >= r.len-1 { r.fill_buffer()? } read := copy(buf, r.buf[r.offset..r.len]) r.offset += read return read } // fill buffer attempts to refill the internal buffer fn (mut r BufferedReader) fill_buffer() ? { // TODO we should keep track of when we get an end of stream // from the upstream reader so that we dont have to keep // trying to call this r.offset = 0 r.len = r.reader.read(mut r.buf) or { 0 } } // read_line reads a line from the buffered reader pub fn (mut r BufferedReader) read_line() ?string { mut line := []byte{} for { if r.offset >= (r.len-1) { // go fetch some new data r.fill_buffer()? } if r.len == 0 { // if we have no data then return nothing return none } // try and find a newline character mut i := r.offset for ; i < r.len; i++ { c := r.buf[i] if c == `\n` { // great, we hit something // do some checking for whether we hit \r\n or just \n if i != 0 && r.buf[i-1] == `\r` { x := i-1 line << r.buf[r.offset..x] } else { line << r.buf[r.offset..i] } r.offset = i + 1 return line.bytestr() } } line << r.buf[r.offset..i] r.offset = i } }