Not every Rustacean has a background in systems programming, nor in computer science, so we've added explanations of terms that might be unfamiliar.
When a compiler is compiling your program, it does a number of different things.
One of the things that it does is turn the text of your program into an
‘abstract syntax tree’, or ‘AST’. This tree is a representation of the structure
of your program. For example, 2 + 3
can be turned into a tree:
+
/ \
2 3
And 2 + (3 * 4)
would look like this:
+
/ \
2 *
/ \
3 4
Arity refers to the number of arguments a function or operation takes.
fn main() { let x = (2, 3); let y = (4, 6); let z = (8, 2, 6); }let x = (2, 3); let y = (4, 6); let z = (8, 2, 6);
In the example above x
and y
have arity 2. z
has arity 3.
Bounds are constraints on a type or trait. For example, if a bound is placed on the argument a function takes, types passed to that function must abide by that constraint.
A type without a statically known size or alignment. (more info)
In computer programming, an expression is a combination of values, constants,
variables, operators and functions that evaluate to a single value. For example,
2 + (3 * 4)
is an expression that returns the value 14. It is worth noting
that expressions can have side-effects. For example, a function included in an
expression might perform actions other than simply returning a value.
In early programming languages, expressions and statements were two separate syntactic categories: expressions had a value and statements did things. However, later languages blurred this distinction, allowing expressions to do things and statements to have a value. In an expression-oriented language, (nearly) every statement is an expression and therefore returns a value. Consequently, these expression statements can themselves form part of larger expressions.
In computer programming, a statement is the smallest standalone element of a programming language that commands a computer to perform an action.