Statements

Statement  = DefStmt | IfStmt | ForStmt | SimpleStmt .
SimpleStmt = SmallStmt {';' SmallStmt} [';'] '\n' .
SmallStmt  = ReturnStmt
           | BreakStmt | ContinueStmt | PassStmt
           | AssignStmt
           | ExprStmt
           | LoadStmt
           .

Pass statements

A pass statement does nothing. Use a pass statement when the syntax requires a statement but no behavior is required, such as the body of a function that does nothing.

PassStmt = 'pass' .

Example:

def noop():
   pass
def list_to_dict(items):
  # Convert list of tuples to dict
  m = {}
  for k, m[k] in items:
    pass
  return m

Assignments

An assignment statement has the form lhs = rhs. It evaluates the expression on the right-hand side then assigns its value (or values) to the variable (or variables) on the left-hand side.

AssignStmt = Expression '=' Expression .

The expression on the left-hand side is called a target. The simplest target is the name of a variable, but a target may also have the form of an index expression, to update the element of a list or dictionary, or a dot expression, to update the field of an object:

k = 1
a[i] = v
m.f = ""

Compound targets may consist of a comma-separated list of subtargets, optionally surrounded by parentheses or square brackets, and targets may be nested arbitarily in this way. An assignment to a compound target checks that the right-hand value is a sequence with the same number of elements as the target. Each element of the sequence is then assigned to the corresponding element of the target, recursively applying the same logic.

pi, e = 3.141, 2.718
(x, y) = f()
[zero, one, two] = range(3)
[(a, b), (c, d)] = {"a": "b", "c": "d"}.items()
a, b = {"a": 1, "b": 2}

The same process for assigning a value to a target expression is used in for loops and in comprehensions.

Augmented assignments

An augmented assignment, which has the form lhs op= rhs updates the variable lhs by applying a binary arithmetic operator op (one of +, -, *, /, //, %, &, |, ^, <<, >>) to the previous value of lhs and the value of rhs.

AssignStmt = Expression ('+=' | '-=' | '*=' | '/=' | '//=' | '%=' | '&=' | '|=' | '^=' | '<<=' | '>>=') Expression .

The left-hand side must be a simple target: a name, an index expression, or a dot expression.

x -= 1
x.filename += ".star"
a[index()] *= 2

Any subexpressions in the target on the left-hand side are evaluated exactly once, before the evaluation of rhs. The first two assignments above are thus equivalent to:

x = x - 1
x.filename = x.filename + ".star"

and the third assignment is similar in effect to the following two statements but does not declare a new temporary variable i:

i = index()
a[i] = a[i] * 2

Function definitions

A def statement creates a named function and assigns it to a variable.

DefStmt = 'def' identifier '(' [Parameters [',']] ')' ':' Suite .

Example:

def twice(x):
    return x * 2
str(twice)              # "<function twice>"
twice(2)                # 4
twice("two")            # "twotwo"

The function's name is preceded by the def keyword and followed by the parameter list (which is enclosed in parentheses), a colon, and then an indented block of statements which form the body of the function.

The parameter list is a comma-separated list whose elements are of several kinds. First come zero or more required parameters, which are simple identifiers; all calls must provide an argument value for these parameters.

The required parameters are followed by zero or more optional parameters, of the form name=expression. The expression specifies the default value for the parameter for use in calls that do not provide an argument value for it.

The required parameters are optionally followed by a single parameter name preceded by a *. This is the called the varargs parameter, and it accumulates surplus positional arguments specified by a call. It is conventionally named *args.

The varargs parameter may be followed by zero or more parameters, again of the forms name or name=expression, but these parameters differ from earlier ones in that they are keyword-only: if a call provides their values, it must do so as keyword arguments, not positional ones.

def f(a, *, b=2, c):
  print(a, b, c)
f(1)                    # error: function f missing 1 argument (c)
f(1, 3)                 # error: function f accepts 1 positional argument (2 given)
f(1, c=3)               # "1 2 3"
def g(a, *args, b=2, c):
  print(a, b, c, args)
g(1, 3)                 # error: function g missing 1 argument (c)
g(1, 4, c=3)            # "1 2 3 (4,)"

A non-variadic function may also declare keyword-only parameters, by using a bare * in place of the *args parameter. This form does not declare a parameter but marks the boundary between the earlier parameters and the keyword-only parameters. This form must be followed by at least one optional parameter.

Finally, there may be an optional parameter name preceded by **. This is called the keyword arguments parameter, and accumulates in a dictionary any surplus name=value arguments that do not match a prior parameter. It is conventionally named **kwargs.

The final parameter may be followed by a trailing comma.

Here are some example parameter lists:

def f(): pass
def f(a, b, c): pass
def f(a, b, c=1): pass
def f(a, b, c=1, *args): pass
def f(a, b, c=1, *args, **kwargs): pass
def f(**kwargs): pass
def f(a, b, c=1, *, d=1): pass
def f(
  a,
  *args,
  **kwargs,
)

Execution of a def statement creates a new function object. The function object contains: the syntax of the function body; the default value for each optional parameter; the value of each free variable referenced within the function body; and the global dictionary of the current module.

Return statements

A return statement ends the execution of a function and returns a value to the caller of the function.

ReturnStmt = 'return' [Expression] .

A return statement may have zero, one, or more result expressions separated by commas. With no expressions, the function has the result None. With a single expression, the function's result is the value of that expression. With multiple expressions, the function's result is a tuple.

return                  # returns None
return 1                # returns 1
return 1, 2             # returns (1, 2)

Expression statements

An expression statement evaluates an expression and discards its result.

ExprStmt = Expression .

Any expression may be used as a statement, but an expression statement is most often used to call a function for its side effects.

list.append(1)

If statements

An if statement evaluates an expression (the condition), then, if the truth value of the condition is True, executes a list of statements.

IfStmt = 'if' Test ':' Suite {'elif' Test ':' Suite} ['else' ':' Suite] .

Example:

if score >= 100:
    print("You win!")
    return

An if statement may have an else block defining a second list of statements to be executed if the condition is false.

if score >= 100:
        print("You win!")
        return
else:
        print("Keep trying...")
        continue

It is common for the else block to contain another if statement. To avoid increasing the nesting depth unnecessarily, the else and following if may be combined as elif:

if x > 0:
        result = +1
elif x < 0:
        result = -1
else:
        result = 0

An if statement is permitted only within a function definition. An if statement at top level results in a static error.

Implementation note:The Go implementation of Starlark permits `if`-statements to appear at top level if the `-globalreassign` flag is enabled.

While loops

A while loop evaluates an expression (the condition) and if the truth value of the condition is True, it executes a list of statement and repeats the process until the truth value of the condition becomes False.

WhileStmt = 'while' Test ':' Suite .

Example:

while n > 0:
    r = r + n
    n = n - 1

A while statement is permitted only within a function definition. A while statement at top level results in a static error.

Implementation note:The Go implementation of Starlark permits `while` loops only if the `-recursion` flag is enabled. A `while` statement is permitted at top level if the `-globalreassign` flag is enabled.

For loops

A for loop evaluates its operand, which must be an iterable value. Then, for each element of the iterable's sequence, the loop assigns the successive element values to one or more variables and executes a list of statements, the loop body.

ForStmt = 'for' LoopVariables 'in' Expression ':' Suite .

Example:

for x in range(10):
   print(10)

The assignment of each value to the loop variables follows the same rules as an ordinary assignment. In this example, two-element lists are repeatedly assigned to the pair of variables (a, i):

for a, i in [["a", 1], ["b", 2], ["c", 3]]:
  print(a, i)                          # prints "a 1", "b 2", "c 3"

Because Starlark loops always iterate over a finite sequence, they are guaranteed to terminate, unlike loops in most languages which can execute an arbitrary and perhaps unbounded number of iterations.

Within the body of a for loop, break and continue statements may be used to stop the execution of the loop or advance to the next iteration.

In Starlark, a for loop is permitted only within a function definition. A for loop at top level results in a static error.

Implementation note:The Go implementation of Starlark permits loops to appear at top level if the `-globalreassign` flag is enabled.

Break and Continue

The break and continue statements terminate the current iteration of a for loop. Whereas the continue statement resumes the loop at the next iteration, a break statement terminates the entire loop.

BreakStmt    = 'break' .
ContinueStmt = 'continue' .

Example:

for x in range(10):
    if x%2 == 1:
        continue        # skip odd numbers
    if x > 7:
        break           # stop at 8
    print(x)            # prints "0", "2", "4", "6"

Both statements affect only the innermost lexically enclosing loop. It is a static error to use a break or continue statement outside a loop.

Load statements

The load statement loads another Starlark module, extracts one or more values from it, and binds them to names in the current module.

Syntactically, a load statement looks like a function call load(...).

LoadStmt = 'load' '(' string {',' [identifier '='] string} [','] ')' .

A load statement requires at least two "arguments". The first must be a literal string; it identifies the module to load. Its interpretation is determined by the application into which the Starlark interpreter is embedded, and is not specified here.

During execution, the application determines what action to take for a load statement. A typical implementation locates and executes a Starlark file, populating a cache of files executed so far to avoid duplicate work, to obtain a module, which is a mapping from global names to values.

The remaining arguments are a mixture of literal strings, such as "x", or named literal strings, such as y="x".

The literal string ("x"), which must denote a valid identifier not starting with _, specifies the name to extract from the loaded module. In effect, names starting with _ are not exported. The name (y) specifies the local name; if no name is given, the local name matches the quoted name.

load("module.star", "x", "y", "z")       # assigns x, y, and z
load("module.star", "x", y2="y", "z")    # assigns x, y2, and z

A load statement may not be nested inside any other statement.