taggedalgebraic/source/taggedalgebraic/taggedunion.d
Sönke Ludwig 8f425b37b5 Merge all visit() implementations into a single module.
Avoids template instantiation conflicts introduced by adding the second visit() in taggedalgebraic.taggedalgebraic. A compatibility alias is left in the taggedunion module to avoid breaking backwards compatibility.
2019-12-01 00:03:00 +01:00

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18 KiB
D

/**
* Generic tagged union and algebraic data type implementations.
*
* Copyright: Copyright 2015-2019, Sönke Ludwig.
* License: $(WEB www.boost.org/LICENSE_1_0.txt, Boost License 1.0).
* Authors: Sönke Ludwig
*/
module taggedalgebraic.taggedunion;
// scheduled for deprecation
static import taggedalgebraic.visit;
alias visit = taggedalgebraic.visit.visit;
import std.algorithm.mutation : move, swap;
import std.meta;
import std.range : isOutputRange;
import std.traits : EnumMembers, FieldNameTuple, Unqual, isInstanceOf;
/** Implements a generic tagged union type.
This struct takes a `union` or `struct` declaration as an input and builds
an algebraic data type from its fields, using an automatically generated
`Kind` enumeration to identify which field of the union is currently used.
Multiple fields with the same value are supported.
For each field defined by `U` a number of convenience members are generated.
For a given field "foo", these fields are:
$(UL
$(LI `static foo(value)` - returns a new tagged union with the specified value)
$(LI `isFoo` - equivalent to `kind == Kind.foo`)
$(LI `setFoo(value)` - equivalent to `set!(Kind.foo)(value)`)
$(LI `getFoo` - equivalent to `get!(Kind.foo)`)
)
*/
template TaggedUnion(U) if (is(U == union) || is(U == struct) || is(U == enum)) {
align(commonAlignment!(UnionKindTypes!(UnionFieldEnum!U))) struct TaggedUnion
{
import std.traits : FieldTypeTuple, FieldNameTuple, Largest,
hasElaborateCopyConstructor, hasElaborateDestructor, isCopyable;
import std.ascii : toUpper;
alias FieldDefinitionType = U;
/// A type enum that identifies the type of value currently stored.
alias Kind = UnionFieldEnum!U;
alias FieldTypes = UnionKindTypes!Kind;
alias fieldNames = UnionKindNames!Kind;
static assert(FieldTypes.length > 0, "The TaggedUnions's union type must have at least one field.");
static assert(FieldTypes.length == fieldNames.length);
package alias FieldTypeByName(string name) = FieldTypes[__traits(getMember, Kind, name)];
private {
static if (isUnitType!(FieldTypes[0]) || __VERSION__ < 2072) {
void[Largest!FieldTypes.sizeof] m_data;
} else {
union Dummy {
FieldTypes[0] initField;
void[Largest!FieldTypes.sizeof] data;
alias data this;
}
Dummy m_data = { initField: FieldTypes[0].init };
}
Kind m_kind;
}
this(TaggedUnion other)
{
rawSwap(this, other);
}
void opAssign(TaggedUnion other)
{
rawSwap(this, other);
}
static foreach (ti; UniqueTypes!FieldTypes)
static if(!is(FieldTypes[ti] == void))
{
this(FieldTypes[ti] value)
{
static if (isUnitType!(FieldTypes[ti]))
set!(cast(Kind)ti)();
else
set!(cast(Kind)ti)(move(value));
}
void opAssign(FieldTypes[ti] value)
{
static if (isUnitType!(FieldTypes[ti]))
set!(cast(Kind)ti)();
else
set!(cast(Kind)ti)(move(value));
}
}
// disable default construction if first type is not a null/Void type
static if (!isUnitType!(FieldTypes[0]) && __VERSION__ < 2072) {
@disable this();
}
// postblit constructor
static if (!allSatisfy!(isCopyable, FieldTypes)) {
@disable this(this);
} else static if (anySatisfy!(hasElaborateCopyConstructor, FieldTypes)) {
this(this)
{
switch (m_kind) {
default: break;
foreach (i, tname; fieldNames) {
alias T = FieldTypes[i];
static if (hasElaborateCopyConstructor!T)
{
case __traits(getMember, Kind, tname):
typeid(T).postblit(cast(void*)&trustedGet!T());
return;
}
}
}
}
}
// destructor
static if (anySatisfy!(hasElaborateDestructor, FieldTypes)) {
~this()
{
final switch (m_kind) {
foreach (i, tname; fieldNames) {
alias T = FieldTypes[i];
case __traits(getMember, Kind, tname):
static if (hasElaborateDestructor!T) {
.destroy(trustedGet!T);
}
return;
}
}
}
}
/// Enables conversion or extraction of the stored value.
T opCast(T)()
{
import std.conv : to;
final switch (m_kind) {
foreach (i, FT; FieldTypes) {
case __traits(getMember, Kind, fieldNames[i]):
static if (is(typeof(trustedGet!FT) : T))
return trustedGet!FT;
else static if (is(typeof(to!T(trustedGet!FT)))) {
return to!T(trustedGet!FT);
} else {
assert(false, "Cannot cast a " ~ fieldNames[i]
~ " value of type " ~ FT.stringof ~ " to " ~ T.stringof);
}
}
}
assert(false); // never reached
}
/// ditto
T opCast(T)() const
{
// this method needs to be duplicated because inout doesn't work with to!()
import std.conv : to;
final switch (m_kind) {
foreach (i, FT; FieldTypes) {
case __traits(getMember, Kind, fieldNames[i]):
static if (is(typeof(trustedGet!FT) : T))
return trustedGet!FT;
else static if (is(typeof(to!T(trustedGet!FT)))) {
return to!T(trustedGet!FT);
} else {
assert(false, "Cannot cast a " ~ fieldNames[i]
~ " value of type" ~ FT.stringof ~ " to " ~ T.stringof);
}
}
}
assert(false); // never reached
}
/// Enables equality comparison with the stored value.
bool opEquals()(auto ref inout(TaggedUnion) other)
inout {
if (this.kind != other.kind) return false;
final switch (this.kind) {
foreach (i, fname; TaggedUnion!U.fieldNames)
case __traits(getMember, Kind, fname):
return trustedGet!(FieldTypes[i]) == other.trustedGet!(FieldTypes[i]);
}
assert(false); // never reached
}
/// The type ID of the currently stored value.
@property Kind kind() const { return m_kind; }
static foreach (i, name; fieldNames) {
// NOTE: using getX/setX here because using just x would be prone to
// misuse (attempting to "get" a value for modification when
// a different kind is set instead of assigning a new value)
mixin("alias set"~pascalCase(name)~" = set!(Kind."~name~");");
mixin("@property bool is"~pascalCase(name)~"() const { return m_kind == Kind."~name~"; }");
static if (!isUnitType!(FieldTypes[i])) {
mixin("alias "~name~"Value = value!(Kind."~name~");");
mixin("static TaggedUnion "~name~"(FieldTypes["~i.stringof~"] value)"
~ "{ TaggedUnion tu; tu.set!(Kind."~name~")(move(value)); return tu; }");
// TODO: define assignment operator for unique types
} else {
mixin("static @property TaggedUnion "~name~"() { TaggedUnion tu; tu.set!(Kind."~name~"); return tu; }");
}
}
/** Checks whether the currently stored value has a given type.
*/
@property bool hasType(T)()
const {
static assert(staticIndexOf!(T, FieldTypes) >= 0, "Type "~T.stringof~ " not part of "~FieldTypes.stringof);
final switch (this.kind) {
static foreach (i, n; fieldNames) {
case __traits(getMember, Kind, n):
return is(FieldTypes[i] == T);
}
}
}
/** Accesses the contained value by reference.
The specified `kind` must equal the current value of the `this.kind`
property. Setting a different type must be done with `set` or `opAssign`
instead.
See_Also: `set`, `opAssign`
*/
@property ref inout(FieldTypes[kind]) value(Kind kind)()
inout {
if (this.kind != kind) {
enum msg(.string k_is) = "Attempt to get kind "~kind.stringof~" from tagged union with kind "~k_is;
final switch (this.kind) {
static foreach (i, n; fieldNames)
case __traits(getMember, Kind, n):
assert(false, msg!n);
}
}
//return trustedGet!(FieldTypes[kind]);
return *() @trusted { return cast(const(FieldTypes[kind])*)m_data.ptr; } ();
}
/** Accesses the contained value by reference.
The specified type `T` must equal the type of the currently set value.
Setting a different type must be done with `set` or `opAssign` instead.
See_Also: `set`, `opAssign`
*/
@property ref inout(T) value(T)() inout
{
static assert(staticIndexOf!(T, FieldTypes) >= 0, "Type "~T.stringof~ " not part of "~FieldTypes.stringof);
final switch (this.kind) {
static foreach (i, n; fieldNames) {
case __traits(getMember, Kind, n):
static if (is(FieldTypes[i] == T))
return trustedGet!T;
else assert(false, "Attempting to get type "~T.stringof
~ " from a TaggedUnion with type "
~ FieldTypes[__traits(getMember, Kind, n)].stringof);
}
}
}
/** Sets a new value of the specified `kind`.
*/
ref FieldTypes[kind] set(Kind kind)(FieldTypes[kind] value)
if (!isUnitType!(FieldTypes[kind]))
{
if (m_kind != kind) {
destroy(this);
m_data.rawEmplace(value);
} else {
rawSwap(trustedGet!(FieldTypes[kind]), value);
}
m_kind = kind;
return trustedGet!(FieldTypes[kind]);
}
/** Sets a `void` value of the specified kind.
*/
void set(Kind kind)()
if (isUnitType!(FieldTypes[kind]))
{
if (m_kind != kind) {
destroy(this);
}
m_kind = kind;
}
/** Converts the contained value to a string.
The format output by this method is "(kind: value)", where "kind" is
the enum name of the currently stored type and "value" is the string
representation of the stored value.
*/
void toString(W)(ref W w) const
if (isOutputRange!(W, char))
{
import std.range.primitives : put;
toString(s => put(w, s));
}
/// ditto
void toString(scope void delegate(const(char)[]) sink)
const {
import std.conv : text;
import std.format : FormatSpec, formatValue;
final switch (m_kind) {
foreach (i, v; EnumMembers!Kind) {
case v:
enum vstr = text(v);
static if (isUnitType!(FieldTypes[i])) sink(vstr);
else {
// NOTE: using formatValue instead of formattedWrite
// because formattedWrite does not work for
// non-copyable types
enum prefix = "(" ~ vstr ~ ": ";
enum suffix = ")";
sink(prefix);
FormatSpec!char spec;
sink.formatValue(value!v, spec);
sink(suffix);
}
break;
}
}
}
package @trusted @property ref inout(T) trustedGet(T)() inout { return *cast(inout(T)*)m_data.ptr; }
}
}
///
@safe nothrow unittest {
union Kinds {
int count;
string text;
}
alias TU = TaggedUnion!Kinds;
// default initialized to the first field defined
TU tu;
assert(tu.kind == TU.Kind.count);
assert(tu.isCount); // qequivalent to the line above
assert(!tu.isText);
assert(tu.value!(TU.Kind.count) == int.init);
// set to a specific count
tu.setCount(42);
assert(tu.isCount);
assert(tu.countValue == 42);
assert(tu.value!(TU.Kind.count) == 42);
assert(tu.value!int == 42); // can also get by type
assert(tu.countValue == 42);
// assign a new tagged algebraic value
tu = TU.count(43);
// test equivalence with other tagged unions
assert(tu == TU.count(43));
assert(tu != TU.count(42));
assert(tu != TU.text("hello"));
// modify by reference
tu.countValue++;
assert(tu.countValue == 44);
// set the second field
tu.setText("hello");
assert(!tu.isCount);
assert(tu.isText);
assert(tu.kind == TU.Kind.text);
assert(tu.textValue == "hello");
// unique types can also be directly constructed
tu = TU(12);
assert(tu.countValue == 12);
tu = TU("foo");
assert(tu.textValue == "foo");
}
///
@safe nothrow unittest {
// Enum annotations supported since DMD 2.082.0. The mixin below is
// necessary to keep the parser happy on older versions.
static if (__VERSION__ >= 2082) {
alias myint = int;
// tagged unions can be defined in terms of an annotated enum
mixin(q{enum E {
none,
@string text
}});
alias TU = TaggedUnion!E;
static assert(is(TU.Kind == E));
TU tu;
assert(tu.isNone);
assert(tu.kind == E.none);
tu.setText("foo");
assert(tu.kind == E.text);
assert(tu.textValue == "foo");
}
}
unittest { // test for name clashes
union U { .string string; }
alias TU = TaggedUnion!U;
TU tu;
tu = TU.string("foo");
assert(tu.isString);
assert(tu.stringValue == "foo");
}
unittest { // test woraround for Phobos issue 19696
struct T {
struct F { int num; }
alias Payload = TaggedUnion!F;
Payload payload;
alias payload this;
}
struct U {
T t;
}
alias TU = TaggedUnion!U;
static assert(is(TU.FieldTypes[0] == T));
}
unittest { // non-copyable types
import std.traits : isCopyable;
struct S { @disable this(this); }
struct U {
int i;
S s;
}
alias TU = TaggedUnion!U;
static assert(!isCopyable!TU);
auto tu = TU(42);
tu.setS(S.init);
}
unittest { // alignment
union S1 { int v; }
union S2 { ulong v; }
union S3 { void* v; }
// sanity check for the actual checks - this may differ on non-x86 architectures
static assert(S1.alignof == 4);
static assert(S2.alignof == 8);
version (D_LP64) static assert(S3.alignof == 8);
else static assert(S3.alignof == 4);
// test external struct alignment
static assert(TaggedUnion!S1.alignof == 4);
static assert(TaggedUnion!S2.alignof == 8);
version (D_LP64) static assert(TaggedUnion!S3.alignof == 8);
else static assert(TaggedUnion!S3.alignof == 4);
// test internal struct alignment
TaggedUnion!S1 s1;
assert((cast(ubyte*)&s1.vValue() - cast(ubyte*)&s1) % 4 == 0);
TaggedUnion!S1 s2;
assert((cast(ubyte*)&s2.vValue() - cast(ubyte*)&s2) % 8 == 0);
TaggedUnion!S1 s3;
version (D_LP64) assert((cast(ubyte*)&s3.vValue() - cast(ubyte*)&s3) % 8 == 0);
else assert((cast(ubyte*)&s3.vValue() - cast(ubyte*)&s3) % 4 == 0);
}
unittest { // toString
import std.conv : to;
static struct NoCopy {
@disable this(this);
string toString() const { return "foo"; }
}
union U { Void empty; int i; NoCopy noCopy; }
TaggedUnion!U val;
assert(val.to!string == "empty");
val.setI(42);
assert(val.to!string == "(i: 42)");
val.setNoCopy(NoCopy.init);
assert(val.to!string == "(noCopy: foo)");
}
unittest { // null members should be assignable
union U { int i; typeof(null) Null; }
TaggedUnion!U val;
val = null;
assert(val.kind == val.Kind.Null);
val = TaggedUnion!U(null);
assert(val.kind == val.Kind.Null);
}
enum isUnitType(T) = is(T == Void) || is(T == void) || is(T == typeof(null));
private string pascalCase(string camel_case)
{
if (!__ctfe) assert(false);
import std.ascii : toUpper;
return camel_case[0].toUpper ~ camel_case[1 .. $];
}
/** Maps a kind enumeration value to the corresponding field type.
`kind` must be a value of the `TaggedAlgebraic!T.Kind` enumeration.
*/
template TypeOf(alias kind)
if (is(typeof(kind) == enum))
{
import std.traits : FieldTypeTuple, TemplateArgsOf;
import std.typecons : ReplaceType;
static if (isInstanceOf!(UnionFieldEnum, typeof(kind))) {
alias U = TemplateArgsOf!(typeof(kind));
alias FT = FieldTypeTuple!U[kind];
} else {
alias U = typeof(kind);
alias Types = UnionKindTypes!(typeof(kind));
alias uda = AliasSeq!(__traits(getAttributes, kind));
static if (uda.length == 0) alias FT = void;
else alias FT = uda[0];
}
// NOTE: ReplaceType has issues with certain types, such as a class
// declaration like this: class C : D!C {}
// For this reason, we test first if it compiles and only then use it.
// It also replaces a type with the contained "alias this" type under
// certain conditions, so we make a second check to see heuristically
// if This is actually present in FT
//
// Phobos issues: 19696, 19697
static if (is(ReplaceType!(This, U, FT)) && !is(ReplaceType!(This, void, FT)))
alias TypeOf = ReplaceType!(This, U, FT);
else alias TypeOf = FT;
}
///
unittest {
static struct S {
int a;
string b;
string c;
}
alias TU = TaggedUnion!S;
static assert(is(TypeOf!(TU.Kind.a) == int));
static assert(is(TypeOf!(TU.Kind.b) == string));
static assert(is(TypeOf!(TU.Kind.c) == string));
}
unittest {
struct S {
TaggedUnion!This[] test;
}
alias TU = TaggedUnion!S;
TypeOf!(TU.Kind.test) a;
static assert(is(TypeOf!(TU.Kind.test) == TaggedUnion!S[]));
}
/// Convenience type that can be used for union fields that have no value (`void` is not allowed).
struct Void {}
/** Special type used as a placeholder for `U` within the definition of `U` to
enable self-referential types.
Note that this is recognized only if used as the first argument to a
template type.
*/
struct This { Void nothing; }
///
unittest {
union U {
TaggedUnion!This[] list;
int number;
string text;
}
alias Node = TaggedUnion!U;
auto n = Node([Node(12), Node("foo")]);
assert(n.isList);
assert(n.listValue == [Node(12), Node("foo")]);
}
package template UnionFieldEnum(U)
{
static if (is(U == enum)) alias UnionFieldEnum = U;
else {
import std.array : join;
import std.traits : FieldNameTuple;
mixin("enum UnionFieldEnum { " ~ [FieldNameTuple!U].join(", ") ~ " }");
}
}
deprecated alias TypeEnum(U) = UnionFieldEnum!U;
package alias UnionKindTypes(FieldEnum) = staticMap!(TypeOf, EnumMembers!FieldEnum);
package alias UnionKindNames(FieldEnum) = AliasSeq!(__traits(allMembers, FieldEnum));
package template UniqueTypes(Types...) {
template impl(size_t i) {
static if (i < Types.length) {
alias T = Types[i];
static if (staticIndexOf!(T, Types) == i && staticIndexOf!(T, Types[i+1 .. $]) < 0)
alias impl = AliasSeq!(i, impl!(i+1));
else alias impl = AliasSeq!(impl!(i+1));
} else alias impl = AliasSeq!();
}
alias UniqueTypes = impl!0;
}
package template AmbiguousTypes(Types...) {
template impl(size_t i) {
static if (i < Types.length) {
alias T = Types[i];
static if (staticIndexOf!(T, Types) == i && staticIndexOf!(T, Types[i+1 .. $]) >= 0)
alias impl = AliasSeq!(i, impl!(i+1));
else alias impl = impl!(i+1);
} else alias impl = AliasSeq!();
}
alias AmbiguousTypes = impl!0;
}
/// Computes the minimum alignment necessary to align all types correctly
private size_t commonAlignment(TYPES...)()
{
import std.numeric : gcd;
size_t ret = 1;
foreach (T; TYPES)
ret = (T.alignof * ret) / gcd(T.alignof, ret);
return ret;
}
unittest {
align(2) struct S1 { ubyte x; }
align(4) struct S2 { ubyte x; }
align(8) struct S3 { ubyte x; }
static if (__VERSION__ > 2076) { // DMD 2.076 ignores the alignment
assert(commonAlignment!S1 == 2);
assert(commonAlignment!S2 == 4);
assert(commonAlignment!S3 == 8);
assert(commonAlignment!(S1, S3) == 8);
assert(commonAlignment!(S1, S2, S3) == 8);
assert(commonAlignment!(S2, S2, S1) == 4);
}
}
package void rawEmplace(T)(void[] dst, ref T src)
{
T[] tdst = () @trusted { return cast(T[])dst[0 .. T.sizeof]; } ();
static if (is(T == class)) {
tdst[0] = src;
} else {
import std.conv : emplace;
emplace!T(&tdst[0]);
rawSwap(tdst[0], src);
}
}
// std.algorithm.mutation.swap sometimes fails to compile due to
// internal errors in hasElaborateAssign!T/isAssignable!T. This is probably
// caused by cyclic dependencies. However, there is no reason to do these
// checks in this context, so we just directly move the raw memory.
package void rawSwap(T)(ref T a, ref T b)
@trusted {
void[T.sizeof] tmp = void;
void[] ab = (cast(void*)&a)[0 .. T.sizeof];
void[] bb = (cast(void*)&b)[0 .. T.sizeof];
tmp[] = ab[];
ab[] = bb[];
bb[] = tmp[];
}