which allows solving of a constraint system to succeed without emitting
errors in the face of ambiguous solutions. This is important for CSDiag
because it is in the business of trying to solve subexpressions of a global
expression - and it wants to know the difference between a subexpression
that is inherently impossible to solve, vs one that is simply ambiguous
because its context has been removed.
Use this in CSDiag's typeCheckChildIndependently() to provide it an
extra flag that enables this behavior. This is currently unused, so NFC
with this patch.
Swift SVN r30402
It looks like we were checking in the wrong place, as a result we didn't
catch stuff like
class G<T : AnyObject> {}
_ = G<P>()
This would crash later in IRGen.
Make the conformsToProtocol() check do the right thing, and remove some
other miscellaneous diagnostics in the process. Also, make the
"type 'T' does not conform to protocol 'P'" diagnostic a bit more
detailed.
Unfortunately in a few instances we lose a more descriptive diagnostic to
a general 'cannot invoke 'foo' with argument list of type 'T'' error. The
argument matching diagnostics need to be addressed anyway though.
Fixes <rdar://problem/20311619>.
Swift SVN r29737
them with diagnoseGeneralFailure() which would miss out on the common cases
where the subexpr of the ParenExpr is the issue.
For example, before we would produce:
t.swift:8:8: error: could not find an overload for '&' that accepts the supplied arguments
if !(x & 4.0) {}
~~~^~~~~~
now we produce:
t.swift:8:6: error: binary operator '&' cannot be applied to operands of type 'Int' and 'Double'
if !(x & 4.0) {}
^
t.swift:8:6: note: overloads for '&' exist with these partially matching parameter lists: (Int, Int)
if !(x & 4.0) {}
^
also, remove some special handling for lvalues and inout from overload
diagnostics, which can't matter anymore.
Swift SVN r29661
X.Protocol is an instance of Y.Type only if X conforms to Y. Since X
is a protocol, this is only true if X contains Y and Y is
self-conforming.
Note that this updates some tests that actually contained invalid code.
Fixes <rdar://problem/20915927>.
Swift SVN r29349
If 'x.init' appears as a member reference other than 'self.init' or 'super.init' within an initializer, treat it as a regular static member lookup for 'init' members. This allows a more explicit syntax for dynamic initializations; 'self.someMetatype()' looks too much like it's invoking a method. It also allows for partial applications of initializers using 'someMetatype.init' (though this needs some SILGen fixes, coming up next). While we're in the neighborhood, do some other correctness and QoI fixes:
- Only lookup initializers as members of metatypes, not instances, and add a fixit (instead of crashing) to insert '.dynamicType' if the initializer is found on an instance.
- Make it so that constructing a class-constrained archetype type correctly requires a 'required' or protocol initializer.
- Warn on unused initializer results. This seems to me like just the right thing to do, but is also a small guard against the fact that 'self.init' is now valid in a static method, but produces a newly-constructed value instead of delegating initialization (and evaluating to void).
Swift SVN r29344
Rename existentialConformsToSelf() to existentialTypeSupported(). This
predicate is the "protocol has no Self or associated type requirements"
check, which is a looser condition than self-conformance. This was being
tested to see if the user could refer to the protocol via an existential
type.
The new existentialConformsToSelf() now checks for protocol being @objc,
and for the absence of static methods. This is used as part of the
argument type matching logic in matchType() to determine if the
existential can be bound to a generic type parameter.
The latter condition is stricter, for two reasons:
1) We allow binding existentials to multiple type parameters all sharing
the same generic type parameter T, so we don't want the user to be
able to see any static methods on T.
2) There is an IRGen limitation whereby only existentials without witness
tables can be passed in this manner.
Using the above, the representsNonTrivialGenericParameter() function
has been renamed to canBindGenericParamToExistential(). It now allows
an existential type to be bound to a generic type parameter only under
the following circumstances:
A) If the generic type parameter has no conformances, the match is allowed.
B) If the generic type parameter has at least one conformance, then all
of the conformances on the generic type parameter must be
existentialConformsToSelf() (condition 1 above), and all conformances
on the existential must be @objc (condition 2 above).
Fixes <rdar://problem/18378390> and <rdar://problem/18683843>, and lays
the groundwork for fixing a few other related issues.
Swift SVN r29337
result in slightly more descriptive diagnostics in some cases. (Specifically,
for diagnostics involving binary operators.)
(rdar://problem/21080030)
Swift SVN r29020
variable has the must-be-materializable bit set if the old one does.
When assigning a fixed type to a type variable that must be
materializable, transfer the bit to any type variables within the fixed
type, as appropriate.
Add Options field to SavedTypeVariableBinding to save/restore type
variable options during solution.
<rdar://problem/21026806> Propagate MustBeMaterializable bit among type variables appropriately
Swift SVN r28883
Add a new option, TVO_MustBeMaterializable, to
TypeVariableType::Implementation, and set it for type variables
resulting from opening a generic type. This solution isn't complete (we
don't yet copy the non-materializable bit on unification of type
variables, and it's possible to bind a must-be-materializable type
variable to a type with type variables that later get bound to
non-materializable types) but it addresses all reported crashes for this
issue.
<rdar://problem/20807269> Crash in non-materializable type
Swift SVN r28792
Fix a nullptr dereference when looking for a base expression
in a member access. Remove use of Optional<T*>, it wasn't providing
any value versus nullptr checking.
Swift SVN r28648
When in an initializer, we allow setting into immutable properties
provided that the type of base in `base.member` matches that of that
initializer's containing type. This was an approximation for allowing
full access into `self` during initialization but this doesn't work when
passing in a different struct of the same type because that struct
should be still be immutable.
Check whether the base of the member access is the implicit self
parameter of the initializer before allowing mutation.
rdar://problem/19814302
Swift SVN r28634
ConstraintSystem::dump to ConstraintSystem::print for
consistency with other parts of the compiler. Enhance
CS::print to print the ID # of a Type Variable, so you
don't have to count them to realize that you're looking
at typevar #13
Swift SVN r27874
In addition to being better for performance in these cases, this disables the "self."
requirement in these blocks. {}() constructs are often used to work around statements
that are not exprs in Swift, so they are reasonably important.
Fixing this takes a couple of pieces working together:
- Add a new 'extraFunctionAttrs' map to the ConstraintSystem for solution
invariant function attributes that are inferred (like @noescape).
- Teach constraint simplification of function applications to propagate
@noescape between unified function types.
- Teach CSGen of ApplyExprs to mark the callee functiontype as noescape
when it is obviously a ClosureExpr.
This is a very limited fix in some ways: you could argue that ApplyExpr should
*always* mark its callee as noescape. However, doing so would just introduce a
ton of function conversions to remove it again, so we don't do that.
Swift SVN r27723
Add syntax "[#Color(...)#]" for object literals, to be used by
Playgrounds for inline color wells etc. The arguments are forwarded to
the relevant constructor (although we will probably change this soon,
since (colorLiteralRed:... blue:... green:... alpha) is kind of
verbose). Add _ColorLiteralConvertible and _ImageLiteralConvertible
protocols, and link them to the new expressions in the type checker.
CSApply replaces the object literal expressions with a call to the
appropriate protocol witness.
Swift SVN r27479
A non-throwing function can be a trivial subtype of a throwing
function. Encode this rule more directly, introduce some additional
tests to ensure that we get the behavior right where we need exact
matches, and add a failure kind with custom diagnostic for cases where
function types mismatch due to 'throws'.
Swift SVN r27255
Improves the placement of open-existential expressions when accessing
a property or subscript declared in a protocol extension. We need to
delay until the load occurs when the property/subscript has a usable
setter.
Swift SVN r27064
To use members of protocol extensions on existential types, we
introduce an OpenExistentialExpr expression to open up the existential
type (into a local archetype) and perform the operations on that local
archetype.
Unlike with uses of initializers or dynamic-Self-producing
methods of protocols, which produce similar ASTs, we have the type
checker perform the "open" operation and then track it through
constraint application. This scheme is better (because it's more
direct), but it's still using a simplistic approach to deciding where
the actual OpenExistentialExpr goes that needs improvement.
Swift SVN r26964
- Implement SILGen for conditional multi-pattern PBD's.
- Have the type checker check where clauses on PBDs.
- Change the AST to represent complex if/let PBD's with
composed PBDs instead of breaking them down. For example,
represent:
if let x? = foo(), y? = bar() where x == y {
as a single PBD in a StmtCondition instead of representing
it as three entries in the condition.
The later change is good for AST/source fidelity as well as providing
a cheap way to exercise all the logic I'm building.
Swift SVN r26959
This pushes tuple pattern labels forward:
- Actually record them in TuplePatternElt.
- Remove the tuple shuffle ban that prevents some cases
(e.g. the one in the radar) of a tuple with labels being shuffled
onto a tuple without labels.
- Remove dead code enabled by removing the restriction.
Swift SVN r26852
Previously, we were reconstructing this mapping from the "full" opened
type produced by declaration references. However, when dealing with
same-type constraints between associated types and type parameters, we
could end up with an incomplete mapping, which let archetypes slip
through. Most of the churn here is sorting out the locators we need to
use to find the opened-type information. Fixes rdar://problem/18208283
and at least 3 dupes of it that I've found so far.
Swift SVN r25375
John pointed out that messing with the type checker's notion of "subtype"
is a bad idea. Instead, we should just have a separate check for ABI
compatibility...and eventually (rdar://problem/19517003) just insert the
appropriate thunks rather than forcing the user to perform the conversion.
I'm leaving all the tests as they are because I'm adding a post-type-checking
diagnostic in the next commit, and that should pass all the same tests.
Part of rdar://problem/19600325
Swift SVN r25116
Penalize solutions that involve 'as' -> 'as!' changes by recording a Fix
when simplifying the corresponding checked-cast constraint.
<rdar://problem/19724719> Type checker thinks "(optionalNSString ?? nonoptionalNSString) as String" is a forced cast
Swift SVN r25061
These haven't ever been safe in Swift's development because they require
generating thunks, and we currently don't do that. However, we were letting
existential conversions slip through the cracks because we consider them
subtypes, so that /metatype/ conversions work correctly. To be concrete:
"let _: Any.Type = Int.self" is okay.
"let _: (Int) -> Void = { (_: Any) -> Void in return }" is not.
We should implement this some day; that's rdar://problem/19517003.
This produces some lousy error messages, which I intend to fix soon.
Part of rdar://problem/19600325
Swift SVN r24915
- Situations where the type of a return statement's result expression doesn't line up with the function's type annotation.
- Situations where the type of an initializer expression doesn't line up with its declaration's type pattern.
- Situations where we assume a conversion to a built-in protocol must take place, such as in if-statement conditionals.
(Addresses rdar://problem/19224776, rdar://problem/19422107, rdar://problem/19422156, rdar://problem/19547806 and lots of other dupes.)
Swift SVN r24853
Aside from tidying things up, doing this results in some significant benefits:
- Allows for global constraint ordering optimizations over a given expression, not just on a peephole basis.
- Eliminates a set of order-dependent bugs in the solver that have been dogging us for a while. (rdar://problem/19459079)
- Brings another set of tyvar-to-tyvar solving problems out of the realm of the exponential. (rdar://problem/19005271)
- Opens up the possibility of optimizing constraints during later solving phases - not just while generating them.
Swift SVN r24693
Fix diagnostics for 'as' and 'as!' expressions by ensuring that the
conversion constraint used to generate them actually corresponds to the
expression in question. Add tests from 19495142.
Swift SVN r24547
Also, these changes fix the performance regressions that were introduced as a result of September's convertible/init requirement modifications, and allow us to roll back the associated workarounds that were added to the Adventure sample (rdar://problem/18942100).
Swift SVN r24520
Require 'as' when converting from Objective-C type to native type (but
continue to allow implicit conversion from native to Objective-C). This
conversion constraint is called ExplicitConversion; all implicit
conversions are covered by the existing Conversion constraint. Update
standard library and tests to match.
Swift SVN r24496
When dealing with multiple levels of generic parameters, the mapping
from potential archetypes down to actual archetypes did not have
access to the archetypes for outer generic parameters. When same-type
requirements equated a type from the inner generic parameter list with
one from the outer generic parameter list, the reference to the outer
generic parameter list's type would remain dependent. For example,
given:
struct S<A: P> {
init<Q: P where Q.T == A>(_ q: Q) {}
}
we would end up with the dependent type for A (τ_0_0) in the same-type
constraint in the initializer requirement.
Now, notify the ArchetypeBuilder of outer generic signatures (and,
therefore, outer generic parameters), so that it has knowledge of the
mapping from those generic parameters to the corresponding
archetypes. Use that mapping when translating potential archetypes to
real archetypes. Additionally, when a potential archetype is mapped to
a concrete type (via a same-type constraint to a concrete type),
substitute archetypes for any dependent types within the concrete
type.
Remove a bunch of hacks in the compiler that identified dependent
types in "strange" places and tried to map them back to
archetypes. Those hacks handled some narrow cases we saw in the
standard library and some external code, but papered over the
underlying issue and left major gaps.
Sadly, introduce one hack into the type checker to help with the
matching of generic witnesses to generic requirements that follow the
pattern described above. See ConstraintSystem::SelfTypeVar; the proper
implementation for this matching involves substituting the adoptee
type in for Self within the requirement, and synthesizing new
archetypes from the result.
Fixes rdar://18435371, rdar://18803556, rdar://19082500,
rdar://19245317, rdar://19371678 and a half dozen compiler crashers
from the crash suite. There are a few other radars that I suspect this
fixes, but which require more steps to reproduce.
Swift SVN r24460
The archetype opener only needs to perform basic substitutions; let it
do so, avoiding the creation of a pile of type variables that simply
get immediately bound.
Swift SVN r24399
Previously the "as" keyword could either represent coercion or or forced
downcasting. This change separates the two notions. "as" now only means
type conversion, while the new "as!" operator is used to perform forced
downcasting. If a program uses "as" where "as!" is called for, we emit a
diagnostic and fixit.
Internally, this change removes the UnresolvedCheckedCastExpr class, in
favor of directly instantiating CoerceExpr when parsing the "as"
operator, and ForcedCheckedCastExpr when parsing the "as!" operator.
Swift SVN r24253
