This document describes the design and implementation of the Swift type checker. It is intended for developers who wish to modify, extend, or improve on the type checker, or simply to understand in greater depth how the Swift type system works. Familiarity with the Swift programming language is assumed.
The Swift language and its type system incorporate a number of popular language features, including object-oriented programming via classes, function and operator overloading, subtyping, and constrained parametric polymorphism. Swift makes extensive use of type inference, allowing one to omit the types of many variables and expressions. For example:
func round(_ x: Double) -> Int { /* ... */ }
var pi: Double = 3.14159
var three = round(pi) // 'three' has type 'Int'
func identity<T>(_ x: T) -> T { return x }
var eFloat: Float = -identity(2.71828) // numeric literal gets type 'Float'
Swift's type inference allows type information to flow in two
directions. As in most mainstream languages, type information can flow
from the leaves of the expression tree (e.g., the expression pi
,
which refers to a double) up to the root (the type of the variable
three
). However, Swift also allows type information to flow from the
context (e.g., the fixed type of the variable eFloat
) at the root of
the expression tree down to the leaves (the type of the numeric
literal 2.71828). This bi-directional type inference is common in
languages that use ML-like type systems, but is not present in
mainstream languages like C++, Java, C#, or Objective-C.
Swift implements bi-directional type inference using a constraint-based type checker that is reminiscent of the classical Hindley-Milner type inference algorithm. The use of a constraint system allows a straightforward, general presentation of language semantics that is decoupled from the actual implementation of the solver. It is expected that the constraints themselves will be relatively stable, while the solver will evolve over time to improve performance and diagnostics.
The Swift language contains a number of features not part of the Hindley-Milner type system, including constrained polymorphic types and function overloading, which complicate the presentation and implementation somewhat. On the other hand, Swift limits the scope of type inference to a single expression or statement, for purely practical reasons: we expect that we can provide better performance and vastly better diagnostics when the problem is limited in scope.
Type checking proceeds in three main stages:
Constraint Generation Given an input expression and (possibly) additional contextual information, generate a set of type constraints that describes the relationships among the types of the various subexpressions. The generated constraints may contain unknown types, represented by type variables, which will be determined by the solver.
Constraint Solving Solve the system of constraints by assigning concrete types to each of the type variables in the constraint system. The constraint solver should provide the most specific solution possible among different alternatives.
Solution Application Given the input expression, the set of type constraints generated from that expression, and the set of assignments of concrete types to each of the type variables, produce a well-typed expression that makes all implicit conversions (and other transformations) explicit and resolves all unknown types and overloads. This step cannot fail.
The following sections describe these three stages of type checking, as well as matters of performance and diagnostics.
A constraint system consists of a set of type constraints. Each type
constraint either places a requirement on a single type (e.g., it is
an integer literal type) or relates two types (e.g., one is a subtype
of the other). The types described in constraints can be any type in
the Swift type system including, e.g., builtin types, tuple types,
function types, enum/struct/class types, protocol types, and generic
types. Additionally, a type can be a type variable T
(which are
typically numbered, T0
, T1
, T2
, etc., and are introduced
as needed). Type variables can be used in place of any other type,
e.g., a tuple type (T0, Int, (T0) -> Int)
involving the type
variable T0
.
There are a number of different kinds of constraints used to describe the Swift type system:
Equality
An equality constraint requires two types to be identical. For
example, the constraint T0 == T1
effectively ensures that T0
and
T1
get the same concrete type binding. There are two different
flavors of equality constraints:
- Exact equality constraints, or "binding", written
T0 := X
for some type variableT0
and typeX
, which requires thatT0
be exactly identical toX
; - Equality constraints, written
X == Y
for typesX
andY
, which requireX
andY
to have the same type, ignoring lvalue types in the process. For example, the constraintT0 == X
would be satisfied by assigningT0
the typeX
and by assigningT0
the type@lvalue X
.
Subtyping
A subtype constraint requires the first type to be equivalent to or
a subtype of the second. For example, a class type Dog
is a
subtype of a class type Animal
if Dog
inherits from
Animal
either directly or indirectly. Subtyping constraints are
written X < Y
.
Conversion
A conversion constraint requires that the first type be convertible
to the second, which includes subtyping and equality. Additionally,
it allows a user-defined conversion function to be
called. Conversion constraints are written X <c Y
, read as
"X
can be converted to Y
."
Construction
A construction constraint, written X <C Y
requires that the
second type be a nominal type with a constructor that accepts a
value of the first type. For example, the constraint Int <C String
is satisfiable because String
has a constructor that
accepts an Int
.
Member
A member constraint X[.name] == Y
specifies that the first type
(X
) have a member (or an overloaded set of members) with the
given name, and that the type of that member be bound to the second
type (Y
). There are two flavors of member constraint: value
member constraints, which refer to the member in an expression
context, and type member constraints, which refer to the member in a
type context (and therefore can only refer to types).
Conformance
A conformance constraint X conforms to Y
specifies that the
first type (X
) must conform to the protocol Y
.
Checked cast
A constraint describing a checked cast from the first type to the
second, i.e., for x as T
.
Applicable function An applicable function requires that both types are function types with the same input and output types. It is used when the function type on the left-hand side is being split into its input and output types for function application purposes. Note, that it does not require the type attributes to match.
Overload binding An overload binding constraint binds a type variable by selecting a particular choice from an overload set. Multiple overloads are represented by a disjunction constraint.
Conjunction A constraint that is the conjunction of two or more other constraints. Typically used within a disjunction.
Disjunction A constraint that is the disjunction of two or more constraints. Disjunctions are used to model different decisions that the solver could make, i.e., the sets of overloaded functions from which the solver could choose, or different potential conversions, each of which might resolve in a (different) solution.
Archetype An archetype constraint requires that the constrained type be bound to an archetype. This is a very specific kind of constraint that is only used for calls to operators in protocols.
Class A class constraint requires that the constrained type be bound to a class type.
Self object of protocol
An internal-use-only constraint that describes the conformance of a
Self
type to a protocol. It is similar to a conformance
constraint but "looser" because it allows a protocol type to be the
self object of its own protocol (even when an existential type would
not conform to its own protocol).
Dynamic lookup value A constraint that requires that the constrained type be DynamicLookup or an lvalue thereof.
The process of constraint generation produces a constraint system that relates the types of the various subexpressions within an expression. Programmatically, constraint generation walks an expression from the leaves up to the root, assigning a type (which often involves type variables) to each subexpression as it goes.
Constraint generation is driven by the syntax of the
expression, and each different kind of expression---function
application, member access, etc.---generates a specific set of
constraints. Here, we enumerate the primary expression kinds in the
language and describe the type assigned to the expression and the
constraints generated from such as expression. We use T(a)
to
refer to the type assigned to the subexpression a
. The constraints
and types generated from the primary expression kinds are:
Declaration reference
An expression that refers to a declaration x
is assigned the
type of a reference to x
. For example, if x
is declared as
var x: Int
, the expression x
is assigned the type
@lvalue Int
. No constraints are generated.
When a name refers to a set of overloaded declarations, the selection of the appropriate declaration is handled by the solver. This particular issue is discussed in the Overloading section. Additionally, when the name refers to a generic function or a generic type, the declaration reference may introduce new type variables; see the Polymorphic Types section for more information.
Member reference
A member reference expression a.b
is assigned the type T0
for a fresh type variable T0
. In addition, the expression
generates the value member constraint T(a).b == T0
. Member
references may end up resolving to a member of a nominal type or an
element of a tuple; in the latter case, the name (b
) may
either be an identifier or a positional argument (e.g., 1
).
Note that resolution of the member constraint can refer to a set of overloaded declarations; this is described further in the Overloading section.
Unresolved member reference
An unresolved member reference .name
refers to a member of a
enum type. The enum type is assumed to have a fresh variable
type T0
(since that type can only be known from context), and a
value member constraint T0.name == T1
, for fresh type variable
T1
, captures the fact that it has a member named name
with
some as-yet-unknown type T1
. The type of the unresolved member
reference is T1
, the type of the member. When the unresolved
member reference is actually a call .name(x)
, the function
application is folded into the constraints generated by the
unresolved member reference.
Note that the constraint system above actually has insufficient
information to determine the type T0
without additional
contextual information. The Overloading section describes how the
overload-selection mechanism is used to resolve this problem.
Function application
A function application a(b)
generates two constraints. First,
the applicable function constraint T0 -> T1 ==Fn T(a)
(for fresh
type variables T0
and T1
) captures the rvalue-to-lvalue
conversion applied on the function (a
) and decomposes the
function type into its argument and result types. Second, the
conversion constraint T(b) <c T0
captures the requirement that
the actual argument type (b
) be convertible to the argument type
of the function. Finally, the expression is given the type T1
,
i.e., the result type of the function.
Construction
A type construction A(b)
, where A
refers to a type, generates
a construction constraint T(b) <C A
, which requires that A
have a constructor that accepts b
. The type of the expression is
A
.
Note that construction and function application use the same
syntax. Here, the constraint generator performs a shallow analysis
of the type of the "function" argument (A
or a
, in the
exposition above); if it obviously has metatype type, the expression
is considered a coercion/construction rather than a function
application. This particular area of the language needs more work.
Subscripting
A subscript operation a[b]
is similar to function application. A
value member constraint T(a).subscript == T0 -> T1
treats the
subscript as a function from the key type to the value type,
represented by fresh type variables T0
and T1
,
respectively. The constraint T(b) <c T0
requires the key
argument to be convertible to the key type, and the type of the
subscript operation is T1
.
Literals
A literal expression, such as 17
, 1.5
, or "Hello, world!
, is assigned a fresh type variable T0
. Additionally, a
literal constraint is placed on that type variable depending on the
kind of literal, e.g., "T0
is an integer literal."
Closures
A closure is assigned a function type based on the parameters and
return type. When a parameter has no specified type or is positional
($1
, $2
, etc.), it is assigned a fresh type variable to
capture the type. Similarly, if the return type is omitted, it is
assigned a fresh type variable.
When the body of the closure is a single expression, that expression participates in the type checking of its enclosing expression directly. Otherwise, the body of the closure is separately type-checked once the type checking of its context has computed a complete function type.
Array allocation
An array allocation new A[s]
is assigned the type A[]
. The
type checker (separately) checks that T(s)
is an array bound
type.
Address of
An address-of expression &a
always returns an @inout
type. Therefore, it is assigned the type @inout T0
for a fresh
type variable T0
. The subtyping constraint @inout T0 < @lvalue T(a)
captures the requirement that input expression be an lvalue
of some type.
Ternary operator
A ternary operator x ? y : z
generates a number of
constraints. The type T(x)
must conform to the LogicValue
protocol to determine which branch is taken. Then, a new type
variable T0
is introduced to capture the result type, and the
constraints T(y) <c T0
and T(z) <c T0
capture the need for
both branches of the ternary operator to convert to a common type.
There are a number of other expression kinds within the language; see the constraint generator for their mapping to constraints.
Overloading is the process of giving multiple, different definitions
to the same name. For example, we might overload a negate
function
to work on both Int
and Double
types, e.g.::
func negate(_ x: Int) -> Int { return -x } func negate(_ x: Double) -> Double { return -x }
Given that there are two definitions of negate
, what is the type
of the declaration reference expression negate
? If one selects the
first overload, the type is (Int) -> Int
; for the second overload,
the type is (Double) -> Double
. However, constraint generation
needs to assign some specific type to the expression, so that its
parent expressions can refer to that type.
Overloading in the type checker is modeled by introducing a fresh type
variable (call it T0
) for the type of the reference to an
overloaded declaration. Then, a disjunction constraint is introduced,
in which each term binds that type variable (via an exact equality
constraint) to the type produced by one of the overloads in the
overload set. In our negate example, the disjunction is
T0 := (Int) -> Int or T0 := (Double) -> Double
. The constraint
solver, discussed in the later section on Constraint Solving,
explores both possible bindings, and the overloaded reference resolves
to whichever binding results in a solution that satisfies all
constraints. It is possible that both overloads will result in a solution,
in which case the solutions will be ranked based on the rules
discussed in the section Comparing Solutions.
Overloading can be introduced both by expressions that refer to sets
of overloaded declarations and by member constraints that end up
resolving to a set of overloaded declarations. One particularly
interesting case is the unresolved member reference, e.g.,
.name
. As noted in the prior section, this generates the
constraint T0.name == T1
, where T0
is a fresh type variable
that will be bound to the enum type and T1
is a fresh type
variable that will be bound to the type of the selected member. The
issue noted in the prior section is that this constraint does not give
the solver enough information to determine T0
without
guesswork. However, we note that the type of an enum member actually
has a regular structure. For example, consider the Optional
type::
enum Optional<T> {
case none
case some(T)
}
The type of Optional<T>.none
is Optional<T>
, while the type of
Optional<T>.some
is (T) -> Optional<T>
. In fact, the
type of an enum element can have one of two forms: it can be T0
,
for an enum element that has no extra data, or it can be T2 -> T0
,
where T2
is the data associated with the enum element. For the
latter case, the actual arguments are parsed as part of the unresolved
member reference, so that a function application constraint describes
their conversion to the input type T2
.
The Swift language includes generics, a system of constrained
parameter polymorphism that enables polymorphic types and
functions. For example, one can implement a min
function as,
e.g.,::
func min<T : Comparable>(x: T, y: T) -> T {
if y < x { return y }
return x
}
Here, T
is a generic parameter that can be replaced with any
concrete type, so long as that type conforms to the protocol
Comparable
. The type of min
is (internally) written as <T : Comparable> (x: T, y: T) -> T
, which can be read as "for all T
,
where T
conforms to Comparable
, the type of the function is
(x: T, y: T) -> T
." Different uses of the min
function may
have different bindings for the generic parameter T
.
When the constraint generator encounters a reference to a generic
function, it immediately replaces each of the generic parameters within
the function type with a fresh type variable, introduces constraints
on that type variable to match the constraints listed in the generic
function, and produces a monomorphic function type based on the
newly-generated type variables. For example, the first occurrence of
the declaration reference expression min
would result in a type
(x : T0, y : T0) -> T0
, where T0
is a fresh type variable, as
well as the subtype constraint T0 < Comparable
, which expresses
protocol conformance. The next occurrence of the declaration reference
expression min
would produce the type (x : T1, y : T1) -> T1
,
where T1
is a fresh type variable (and therefore distinct from
T0
), and so on. This replacement process is referred to as
"opening" the generic function type, and is a fairly simple (but
effective) way to model the use of polymorphic functions within the
constraint system without complicating the solver. Note that this
immediate opening of generic function types is only valid because
Swift does not support first-class polymorphic functions, e.g., one
cannot declare a variable of type <T> T -> T
.
Uses of generic types are also immediately opened by the constraint solver. For example, consider the following generic dictionary type::
class Dictionary<Key : Hashable, Value> {
// ...
}
When the constraint solver encounters the expression Dictionary()
,
it opens up the type Dictionary
---which has not
been provided with any specific generic arguments---to the type
Dictionary<T0, T1>
, for fresh type variables T0
and T1
,
and introduces the constraint T0 conforms to Hashable
. This allows
the actual key and value types of the dictionary to be determined by
the context of the expression. As noted above for first-class
polymorphic functions, this immediate opening is valid because an
unbound generic type, i.e., one that does not have specified generic
arguments, cannot be used except where the generic arguments can be
inferred.
The primary purpose of the constraint solver is to take a given set of constraints and determine the most specific type binding for each of the type variables in the constraint system. As part of this determination, the constraint solver also resolves overloaded declaration references by selecting one of the overloads.
Solving the constraint systems generated by the Swift language can, in the worst case, require exponential time. Even the classic Hindley-Milner type inference algorithm requires exponential time, and the Swift type system introduces additional complications, especially overload resolution. However, the problem size for any particular expression is still fairly small, and the constraint solver can employ a number of tricks to improve performance. The Performance_ section describes some tricks that have been implemented or are planned, and it is expected that the solver will be extended with additional tricks going forward.
This section will focus on the basic ideas behind the design of the solver, as well as the type rules that it applies.
The constraint generation process introduces a number of constraints that can be immediately solved, either directly (because the solution is obvious and trivial) or by breaking the constraint down into a number of smaller constraints. This process, referred to as simplification, canonicalizes a constraint system for later stages of constraint solving. It is also re-invoked each time the constraint solver makes a guess (at resolving an overload or binding a type variable, for example), because each such guess often leads to other simplifications. When all type variables and overloads have been resolved, simplification terminates the constraint solving process either by detecting a trivial constraint that is not satisfied (hence, this is not a proper solution) or by reducing the set of constraints down to only simple constraints that are trivially satisfied.
The simplification process breaks down constraints into simpler constraints, and each different kind of constraint is handled by different rules based on the Swift type system. The constraints fall into five categories: relational constraints, member constraints, type properties, conjunctions, and disjunctions. Only the first three kinds of constraints have interesting simplification rules, and are discussed in the following sections.
Relational constraints describe a relationship between two types. This category covers the equality, subtyping, and conversion constraints, and provides the most common simplifications. The simplification of relationship constraints proceeds by comparing the structure of the two types and applying the typing rules of the Swift language to generate additional constraints. For example, if the constraint is a conversion constraint::
A -> B <c C -> D
then both types are function types, and we can break down this
constraint into two smaller constraints C < A
and B < D
by
applying the conversion rule for function types. Similarly, one can
destroy all of the various type constructors---tuple types, generic
type specializations, lvalue types, etc.---to produce simpler
requirements, based on the type rules of the language [1].
Relational constraints involving a type variable on one or both sides
generally cannot be solved directly. Rather, these constraints inform
the solving process later by providing possible type bindings,
described in the Type Variable Bindings section. The exception is
an equality constraint between two type variables, e.g., T0 == T1
. These constraints are simplified by unifying the equivalence
classes of T0
and T1
(using a basic union-find algorithm),
such that the solver need only determine a binding for one of the type
variables (and the other gets the same binding).
Member constraints specify that a certain type has a member of a given
name and provide a binding for the type of that member. A member
constraint A.member == B
can be simplified when the type of A
is determined to be a nominal or tuple type, in which case name lookup
can resolve the member name to an actual declaration. That declaration
has some type C
, so the member constraint is simplified to the
exact equality constraint B := C
.
The member name may refer to a set of overloaded declarations. In this
case, the type C
is a fresh type variable (call it T0
). A
disjunction constraint is introduced, each term of which new overload
set binds a different declaration's type to T0
, as described in
the section on Overloading_.
The kind of member constraint---type or value---also affects the
declaration type C
. A type constraint can only refer to member
types, and C
will be the declared type of the named member. A
value constraint, on the other hand, can refer to either a type or a
value, and C
is the type of a reference to that entity. For a
reference to a type, C
will be a metatype of the declared type.
The basic approach to constraint solving is to simplify the constraints until they can no longer be simplified, then produce (and check) educated guesses about which declaration from an overload set should be selected or what concrete type should be bound to a given type variable. Each guess is tested as an assumption, possibly with other guesses, until the solver either arrives at a solution or concludes that the guess was incorrect.
Within the implementation, each guess is modeled as an assumption within a new solver scope. The solver scope inherits all of the constraints, overload selections, and type variable bindings of its parent solver scope, then adds one more guess. As such, the solution space explored by the solver can be viewed as a tree, where the top-most node is the constraint system generated directly from the expression. The leaves of the tree are either solutions to the type-checking problem (where all constraints have been simplified away) or represent sets of assumptions that do not lead to a solution.
The following sections describe the techniques used by the solver to produce derived constraint systems that explore the solution space.
Overload selection is the simplest way to make an assumption. For an
overload set that introduced a disjunction constraint
T0 := A1 or T0 := A2 or ... or T0 := AN
into the constraint
system, each term in the disjunction will be visited separately. Each
solver state binds the type variable T0
and explores
whether the selected overload leads to a suitable solution.
A second way in which the solver makes assumptions is to guess at the concrete type to which a given type variable should be bound. That type binding is then introduced in a new, derived constraint system to determine if the binding is feasible.
The solver does not conjure concrete type bindings from nothing, nor does it perform an exhaustive search. Rather, it uses the constraints placed on that type variable to produce potential candidate types. There are several strategies employed by the solver.
A given type variable T0
often has relational constraints
placed on it that relate it to concrete types, e.g., T0 <c Int
or
Float <c T0
. In these cases, we can use the concrete types as a
starting point to make educated guesses for the type T0
.
To determine an appropriate guess, the relational constraints placed
on the type variable are categorized. Given a relational constraint of the form
T0 <? A
(where <?
is one of <
, <t
, or <c
), where
A
is some concrete type, A
is said to be "above"
T0
. Similarly, given a constraint of the form B <? T0
for a
concrete type B
, B
is said to be "below" T0
. The
above/below terminologies comes from a visualization of the lattice of
types formed by the conversion relationship, e.g., there is an edge
A -> B
in the latter if A
is convertible to B
. B
would
therefore be higher in the lattice than A
, and the topmost element
of the lattice is the element to which all types can be converted,
Any
(often called "top").
The concrete types "above" and "below" a given type variable provide bounds on the possible concrete types that can be assigned to that type variable. The solver computes [2] the join of the types "below" the type variable, i.e., the most specific (lowest) type to which all of the types "below" can be converted, and uses that join as a starting guess.
The join of the "below" types computed as a starting point may be too
specific, due to constraints that involve the type variable but
weren't simple enough to consider as part of the join. To cope with
such cases, if no solution can be found with the join of the "below"
types, the solver creates a new set of derived constraint systems with
weaker assumptions, corresponding to each of the types that the join
is directly convertible to. For example, if the join was some class
Derived
, the supertype fallback would then try the class Base
from which Derived
directly inherits. This fallback process
continues until the types produced are no longer convertible to the
meet of types "above" the type variable, i.e., the least specific
(highest) type from which all of the types "above" the type variable
can be converted [3].
If a type variable is bound by a conformance constraint to one of the
literal protocols, "T0
conforms to ExpressibleByIntegerLiteral
",
then the constraint solver will guess that the type variable can be
bound to the default literal type for that protocol. For example,
T0
would get the default integer literal type Int
, allowing
one to type-check expressions with too little type information to
determine the types of these literals, e.g., -1
.
The solver explores a potentially large solution space, and it is possible that it will find multiple solutions to the constraint system as given. Such cases are not necessarily ambiguities, because the solver can then compare the solutions to determine whether one of the solutions is better than all of the others. To do so, it computes a "score" for each solution based on a number of factors:
- How many user-defined conversions were applied.
- How many non-trivial function conversions were applied.
- How many literals were given "non-default" types.
Solutions with smaller scores are considered better solutions. When two solutions have the same score, the type variables and overload choices of the two systems are compared to produce a relative score:
-
If the two solutions have selected different type variable bindings for a type variable where a "more specific" type variable is a better match, and one of the type variable bindings is a subtype of the other, the solution with the subtype earns +1.
-
If an overload set has different selected overloads in the two solutions, the overloads are compared. If the type of the overload picked in one solution is a subtype of the type of the overload picked in the other solution, then first solution earns +1.
The solution with the greater relative score is considered to be better than the other solution.
Once the solver has produced a solution to the constraint system, that solution must be applied to the original expression to produce a fully type-checked expression that makes all implicit conversions and resolved overloads explicit. This application process walks the expression tree from the leaves to the root, rewriting each expression node based on the kind of expression:
Declaration references
Declaration references are rewritten with the precise type of the
declaration as referenced. For overloaded declaration references, the
Overload*Expr
node is replaced with a simple declaration
reference expression. For references to polymorphic functions or
members of generic types, a SpecializeExpr
node is introduced to
provide substitutions for all of the generic parameters.
Member references References to members are similar to declaration references. However, they have the added constraint that the base expression needs to be a reference. Therefore, an rvalue of non-reference type will be materialized to produce the necessary reference.
Literals Literals are converted to the appropriate literal type, which typically involves introducing calls to the witnesses for the appropriate literal protocols.
Closures Since the closure has acquired a complete function type, the body of the closure is type-checked with that complete function type.
The solution application step cannot fail for any type checking rule modeled by the constraint system. However, there are some failures that are intentionally left to the solution application phase, such as a postfix '!' applied to a non-optional type.
During constraint generation and solving, numerous constraints are created, broken apart, and solved. During constraint application as well as during diagnostics emission, it is important to track the relationship between the constraints and the actual AST nodes from which they originally came. For example, consider the following type checking problem::
struct X {
// user-defined conversions
func [conversion] __conversion () -> String { /* ... */ }
func [conversion] __conversion () -> Int { /* ... */ }
}
func f(_ i : Int, s : String) { }
var x : X
f(10.5, x)
This constraint system generates the constraints "T(f)
==Fn T0 -> T1
" (for fresh variables T0
and T1
), "(T2, X) <c T0
" (for fresh variable T2
) and "T2
conforms to
ExpressibleByFloatLiteral
". As part of the solution, after T0
is
replaced with (i : Int, s : String)
, the second of
these constraints is broken down into "T2 <c Int
" and "X <c String
". These two constraints are interesting for different
reasons: the first will fail, because Int
does not conform to
ExpressibleByFloatLiteral
. The second will succeed by selecting one
of the (overloaded) conversion functions.
In both of these cases, we need to map the actual constraint of
interest back to the expressions they refer to. In the first case, we
want to report not only that the failure occurred because Int
is
not ExpressibleByFloatLiteral
, but we also want to point out where
the Int
type actually came from, i.e., in the parameter. In the
second case, we want to determine which of the overloaded conversion
functions was selected to perform the conversion, so that conversion
function can be called by constraint application if all else succeeds.
Locators address both issues by tracking the location and derivation
of constraints. Each locator is anchored at a specific AST node
(expression, pattern, declaration etc.) i.e., the function application
f(10.5, x)
, and contains a path of zero or more derivation steps
from that anchor. For example, the "T(f)
==Fn T0 -> T1
"
constraint has a locator that is anchored at the function application
and a path with the "apply function" derivation step, meaning that
this is the function being applied. Similarly, the "(T2, X) <c T0
constraint has a locator anchored at the function application and a
path with the "apply argument" derivation step, meaning that this is
the argument to the function.
When constraints are simplified, the resulting constraints have
locators with longer paths. For example, when a conversion constraint between two
tuples is simplified conversion constraints between the corresponding
tuple elements, the resulting locators refer to specific elements. For
example, the T2 <c Int
constraint will be anchored at the function
application (still), and have two derivation steps in its path: the
"apply function" derivation step from its parent constraint followed
by the "tuple element 0" constraint that refers to this specific tuple
element. Similarly, the X <c String
constraint will have the same
locator, but with "tuple element 1" rather than "tuple element 0". The
ConstraintLocator
type in the constraint solver has a number of
different derivation step kinds (called "path elements" in the source)
that describe the various ways in which larger constraints can be
broken down into smaller ones.
Whenever the solver creates a new overload set, that overload set is
associated with a particular locator. Continuing the example from the
parent section, the solver will create an overload set containing the
two user-defined conversions. This overload set is created while
simplifying the constraint X <c String
, so it uses the locator
from that constraint extended by a "conversion member" derivation
step. The complete locator for this overload set is, therefore::
function application -> apply argument -> tuple element #1 -> conversion member
When the solver selects a particular overload from the overload set, it records the selected overload based on the locator of the overload set. When it comes time to perform constraint application, the locator is recreated based on context (as the bottom-up traversal walks the expressions to rewrite them with their final types) and used to find the appropriate conversion to call. The same mechanism is used to select the appropriate overload when an expression refers directly to an overloaded function. Additionally, when comparing two solutions to the same constraint system, overload sets present in both solutions can be found by comparing the locators for each of the overload choices made in each solution. Naturally, all of these operations require locators to be unique, which occurs in the constraint system itself.
Locators provide the derivation of location information that follows
the path of the solver, and can be used to query and recover the
important decisions made by the solver. However, the locators
determined by the solver may not directly refer to the most specific
AST node for the purposes of identifying the corresponding source
location. For example, the failed constraint "Int
conforms to
ExpressibleByFloatLiteral
" can most specifically by centered on the
floating-point literal 10.5
, but its locator is::
function application -> apply argument -> tuple element #0
The process of locator simplification maps a locator to its most
specific AST node. Essentially, it starts at the anchor of the
locator (in this case, the application f(10.5, x)
) and then walks
the path, matching derivation steps to subexpressions. The "function
application" derivation step extracts the argument ((10.5, x)
). Then, the "tuple element #0" derivation extracts the tuple
element 0 subexpression, 10.5
, at which point we have traversed
the entire path and now have the most specific expression for
source-location purposes.
Simplification does not always exhaust the complete path. For example,
consider a slight modification to our example, so that the argument to
f
is provided by another call, we get a different result
entirely::
func f(_ i : Int, s : String) { }
func g() -> (f : Float, x : X) { }
f(g())
Here, the failing constraint is Float <c Int
, with the same
locator::
function application -> apply argument -> tuple element #0
When we simplify this locator, we start with f(g())
. The "apply
argument" derivation step takes us to the argument expression
g()
. Here, however, there is no subexpression for the first tuple
element of g()
, because it's simple part of the tuple returned
from g
. At this point, simplification ceases, and creates the
simplified locator::
function application of g -> tuple element #0
The performance of the type checker is dependent on a number of factors, but the chief concerns are the size of the solution space (which is exponential in the worst case) and the effectiveness of the solver in exploring that solution space. This section describes some of the techniques used to improve solver performance, many of which can doubtless be improved.
The constraint graph describes the relationships among type variables in the constraint system. Each vertex in the constraint graph corresponds to a single type variable. The edges of the graph correspond to constraints in the constraint system, relating sets of type variables together. Technically, this makes the constraint graph a multigraph, although the internal representation is more akin to a graph with multiple kinds of edges: each vertex (node) tracks the set of constraints that mention the given type variable as well as the set of type variables that are adjacent to this type variable. A vertex also includes information about the equivalence class corresponding to a given type variable (when type variables have been merged) or the binding of a type variable to a specific type.
The constraint graph is critical to a number of solver optimizations. For example, it is used to compute the connected components within the constraint graph, so that each connected component can be solved independently. The partial results from all of the connected components are then combined into a complete solution. Additionally, the constraint graph is used to direct simplification, described below.
When the solver has attempted a type variable binding, that binding often leads to additional simplifications in the constraint system. The solver will query the constraint graph to determine which constraints mention the type variable and will place those constraints onto the simplification worklist. If those constraints can be simplified further, it may lead to additional type variable bindings, which in turn adds more constraints to the worklist. Once the worklist is exhausted, simplification has completed. The use of the worklist eliminates the need to reprocess constraints that could not have changed because the type variables they mention have not changed.
The solver proceeds through the solution space in a depth-first manner. Whenever the solver is about to make a guess---such as a speculative type variable binding or the selection of a term from a disjunction---it introduces a new solver scope to capture the results of that assumption. Subsequent solver scopes are nested as the solver builds up a set of assumptions, eventually leading to either a solution or an error. When a solution is found, the stack of solver scopes contains all of the assumptions needed to produce that solution, and is saved in a separate solution data structure.
The solver scopes themselves are designed to be fairly cheap to create and destroy. To support this, all of the major data structures used by the constraint solver have reversible operations, allowing the solver to easily backtrack. For example, the addition of a constraint to the constraint graph can be reversed by removing that same constraint. The constraint graph tracks all such additions in a stack: pushing a new solver scope stores a marker to the current top of the stack, and popping that solver scope reverses all of the operations on that stack until it hits the marker.
As the solver evaluates potential solutions, it keeps track of the score of the current solution and of the best complete solution found thus far. If the score of the current solution is ever greater than that of the best complete solution, it abandons the current solution and backtracks to continue its search.
The solver makes some attempt at evaluating cheaper solutions before more expensive solutions. For example, it will prefer to try normal conversions before user-defined conversions, prefer the "default" literal types over other literal types, and prefer cheaper conversions to more expensive conversions. However, some of the rules are fairly ad hoc, and could benefit from more study.
Each constraint system introduces its own memory allocation arena,
making allocations cheap and deallocation essentially free. The
allocation arena extends all the way into the AST context, so that
types composed of type variables (e.g., T0 -> T1
) will be
allocated within the constraint system's arena rather than the
permanent arena. Most data structures involved in constraint solving
use this same arena.
Swift 5.2 introduced a new diagnostic framework, which is described in detail in this blog post.
[1]: As of the time of this writing, the type rules of Swift have
not specifically been documented outside of the source code. The
constraints-based type checker contains a function matchTypes
that documents and implements each of these rules. A future revision
of this document will provide a more readily-accessible version.
[2]: More accurately, as of this writing, "will compute". The solver doesn't current compute meets and joins properly. Rather, it arbitrarily picks one of the constraints "below" to start with.
[3]: Again, as of this writing, the solver doesn't actually compute meets and joins, so the solver continues until it runs out of supertypes to enumerate.