An experimental programming language for exploring first class iterators.
See examples for more.
fn main() {
'Hello, world!\n' -> SINKS::stdout();
}Nothing to build, yet!
The design of Burn is very simple as this is a learning experience in writing compilers. The focus of this language is on creating first class support for iterators as a way to logically model data flow through a program. The Burn run-time will concurrently read and write streams making it easier for programmers to focus on transforming the data in a meaningful way. See DESIGN.md for more information on the technical design of the compiler.
boolu8u16u32u64i8i16i32i64stream<T>
You may notice there are no floating point or strings in Burn, but in
the example above there is a string literal. The actual type of that
string literal in Burn is stream<u8>. This makes interchanging input
streams much easier; a useful feature for testing.
Functions are intended to model transfer functions, or "black boxes" with N inputs and M outputs. The below functions demonstrates how any number of inputs and outputs may be specified. Unlike other programming languages, all outputs must be named in Burn.
fn mix(a stream<u8>, b stream<u8>) -> (out stream<u8>) {
while !a.eof() && !b.eof() {
a.next() -> out;
b.next() -> out;
}
}
fn unmix(input stream<u8>) -> (a stream<u8>, b stream<u8>) {
while !input.eof() {
input.next() -> a; // next() is guaranteed here
input.next() -> b; // but not here. In this case Burn detects
// the EOF and it will be a no-op.
}
}
fn sum(a i32, b i32) -> (c i32) {
// Return may still be used without referencing the return value names
return a + b;
}Additionally, if a function's outputs are all stream types, then Burn
will execute the function as needed to progress the program. In other
words, you may setup a chain of functions for which data will flow
through one item at a time, rather than shuffling large buffers.
Burn uses tuples to group inputs and outputs, however there is no
tuple type. This means you cannot assign a tuple to a variable; it
must be unpacked. Use _ to discard unneeded values.
x, y := unmix(data);The arrow operator -> has three purposes:
- Function definitions to describe inputs and outputs
- Syntactic sugar for passing tuples to functions
- Most importantly, write a value to a stream
Syntactic sugar
fn main() {
// All equivalent to mix('hello', 'world');
('hello', 'world') -> mix();
'world' -> mix('hello', _);
'hello' -> mix(_, 'world');
}Write a value to a stream
fn main() {
s := 'foo';
' bar' -> s;
// When checked, s == 'foo bar'
}Burn uses special namespaces SOURCES and SINKS for defining all the
sources and sinks a programmer may use. Remember this is an experimental
language, so defining new sources or sinks is not possible. Below is the
complete list.
| Function | Returns | Description |
|---|---|---|
SOURCES::stdin() |
stream<u8> |
Standard input |
SOURCES::args() |
stream<stream<u8>> |
Space separated command line arguments |
SOURCES::raw_args() |
stream<u8> |
Command line arguments |
SOURCES::tcp(port int) |
(input stream<u8>, output stream<u8>) |
Opens a port and accepts a connection, returning the input and output streams associated with the connection |
SOURCES::file(filename stream<u8>) |
(found bool, data stream<u8>) |
Reads a file from the filesystem |
SINKS::file(filename stream<u8>) |
stream<u8> |
Writes a file to the filesystem |
SINKS::stdout() |
stream<u8> |
Standard output |
SINKS::stderr() |
stream<u8> |
Standard error |
| Method | Returns | Description |
|---|---|---|
next() |
T |
Reads and consumes the next item in the stream |
consume(n u32) |
stream<T> |
Reads and consumes the next n items in the stream |
get(n u32) |
T |
Returns the nth item in the stream without consuming any items |
len() |
u32 |
Returns the number of items currently in the stream |
eof() |
bool |
Returns whether the stream has ended or not (end of file) |
cycle() |
stream<T> |
Cycles the input stream indefinitely |
split(delim stream<T>) |
stream<stream<T>> |
Splits the stream into chunks, excluding delim |
parse() |
- | Context specific; converts a stream<u8> to the inferred numeric type (defaulting to i32 if it cannot be inferred) |
- Design
- Lexing
- Parsing
- Checking
- Code generation
Contributions are welcome!