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auto generate documentation in constants.d from dd files (#430) 

* make constant.d auto generate from .dd files (fix #428)

* added isDeprecated to constants.d

* add isDeprecated to expected keywords in traits test

* make traits message BARELY FIT into the response buffer

because who wants to increase the message buffer anyway? I certainly don't and this seems like a much better solution long term /s

* undo apply dfmt on constants.d

* use startsWith & canFind with multiple needles

* made completion have dynamic ddoc as input

* Remove debug pragma msg from constants.d

* Move message buffer to heap, increase size to 1MB

* made traits & pragma ddoc generation separate tool
This commit is contained in:
Jan Jurzitza 2018-03-24 05:24:29 +01:00 committed by BBasile
parent 92a85bc7d8
commit a02639a44a
7 changed files with 2620 additions and 874 deletions
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223
constants-gen/generator.d Executable file
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@ -0,0 +1,223 @@
#!/usr/bin/env rdmd
import std.algorithm;
import std.ascii;
import std.file;
import std.regex;
import std.stdio;
import std.string;
struct ConstantCompletion
{
string[] identifiers;
string ddoc;
}
struct SingleConstantCompletion
{
string identifier;
string ddoc;
string toString() const
{
return "ConstantCompletion(\"" ~ identifier ~ "\", `" ~ ddoc.replaceAll(ctRegex!"`+",
"` ~ \"$0\" ~ `") ~ "`)";
}
}
unittest
{
ConstantCompletion completion;
completion.ddoc = "'abc``def'";
assert(completion.toString == q{ConstantCompletion("", `'abc` ~ "``" ~ `def'`)});
}
ConstantCompletion[] parsePragmas(string ddoc)
{
ConstantCompletion[] completions;
bool foundTerminator;
ConstantCompletion current;
bool inInlineCode;
bool seekingToFirst = true;
string indent;
void addCurrent()
{
if (seekingToFirst)
{
current = ConstantCompletion.init;
return;
}
// ret still has `$(DD content)` around it, strip that
if (current.ddoc.startsWith("$(DD"))
{
current.ddoc = current.ddoc["$(DD".length .. $].strip;
if (current.ddoc.endsWith(")"))
current.ddoc = current.ddoc[0 .. $ - 1].stripRight;
}
completions ~= current;
current = ConstantCompletion.init;
}
foreach (line; ddoc.lineSplitter!(KeepTerminator.yes))
{
auto strippedLine = line.stripLeft;
if (strippedLine.startsWith("$(SPEC_SUBNAV_PREV_NEXT"))
{
addCurrent();
// end of macros
foundTerminator = true;
break;
}
else if (strippedLine.startsWith("$(DT $(LNAME2 "))
{
addCurrent();
seekingToFirst = false;
indent = line[0 .. $ - strippedLine.length];
string identifierLine = strippedLine.stripRight; // fully stripped
auto closing = identifierLine.indexOfAny("),");
if (closing == -1)
closing = identifierLine.length;
current.identifiers = [identifierLine["$(DT $(LNAME2".length .. closing].strip];
}
else if (!seekingToFirst)
{
if (line.startsWith("---")) // code blocks aren't indented
inInlineCode = !inInlineCode;
if (inInlineCode)
current.ddoc ~= line;
else
{
if (line.startsWith(indent)) // strip indentation equal to DT (section header)
current.ddoc ~= line[indent.length .. $];
else
current.ddoc ~= line;
}
}
}
if (!foundTerminator)
throw new Exception("Could not find '$(SPEC_SUBNAV_PREV_NEXT' line in pragma.dd, format of the file has changed and code needs to be adjusted.");
return completions;
}
ConstantCompletion[] parseTraits(string ddoc)
{
ConstantCompletion[] completions;
bool foundTerminator;
ConstantCompletion current;
bool inInlineCode;
bool seekingToFirst = true;
string indent;
void addCurrent()
{
current.ddoc = current.ddoc.strip;
if (seekingToFirst || current == ConstantCompletion.init)
{
current = ConstantCompletion.init;
return;
}
completions ~= current;
current = ConstantCompletion.init;
}
foreach (line; ddoc.lineSplitter!(KeepTerminator.yes))
{
if (line.stripLeft.startsWith("$(SPEC_SUBNAV_PREV_NEXT"))
{
addCurrent();
foundTerminator = true;
break;
}
else if (line.canFind("$(GNAME "))
{
addCurrent();
ptrdiff_t i = line.indexOf("$(GNAME ");
while (i != -1)
{
auto closing = line.indexOfAny("),", i);
current.identifiers ~= line[i + "$(GNAME ".length .. closing].strip;
i = line.indexOf("$(GNAME ", closing);
}
seekingToFirst = false;
if (current.identifiers.length == 1 && current.identifiers[0][0].isUpper)
seekingToFirst = true; // not considering capitalized identifiers traits (TraitsKeyword, TraitsExpression, etc.)
}
else if (!seekingToFirst)
{
if (line.startsWith("---"))
inInlineCode = !inInlineCode;
if (inInlineCode)
current.ddoc ~= line;
else
{
if (!current.ddoc.length)
indent = line[0 .. $ - line.stripLeft.length];
if (line.startsWith(indent))
current.ddoc ~= line[indent.length .. $];
else
current.ddoc ~= line;
}
}
}
if (!foundTerminator)
throw new Exception("Could not find '$(SPEC_SUBNAV_PREV_NEXT' line in traits.dd, format of the file has changed and code needs to be adjusted.");
return completions;
}
void main()
{
immutable pragmaDDoc = readText("pragma.dd");
immutable traitsDDoc = readText("traits.dd");
auto pragmas = parsePragmas(pragmaDDoc);
auto traits = parseTraits(traitsDDoc);
string part1 = `//
//
// this file is auto generated by constants-gen/generator.d, do not edit manually.
//
//
module dcd.common.constants2;
import dcd.common.constants : ConstantCompletion;
/**
* Pragma arguments
*/
immutable ConstantCompletion[] pragmas = [
// generated from pragma.dd`;
string part2 = `];
/**
* Traits arguments
*/
immutable ConstantCompletion[] traits = [
// generated from traits.dd`;
string part3 = "];";
auto file = File("../src/dcd/common/constants2.d", "w");
file.writeln(part1);
foreach (pragma_; pragmas.sorted)
file.writeln('\t', pragma_, ",");
file.writeln(part2);
foreach (trait; traits.sorted)
file.writeln('\t', trait, ",");
file.writeln(part3);
}
auto sorted(T)(T range)
{
return range.map!(a => a.identifiers.map!(identifier => SingleConstantCompletion(identifier,
a.ddoc))).join.sort!"a.identifier < b.identifier";
}

190
constants-gen/pragma.dd Normal file
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@ -0,0 +1,190 @@
Ddoc
$(SPEC_S Pragmas,
$(HEADERNAV_TOC)
$(GRAMMAR
$(GNAME Pragma):
$(D pragma) $(D $(LPAREN)) $(I Identifier) $(D $(RPAREN))
$(D pragma) $(D $(LPAREN)) $(I Identifier) $(D ,) $(GLINK2 expression, ArgumentList) $(D $(RPAREN))
)
$(P Pragmas are a way to pass special information to the compiler
and to add vendor specific extensions to D.
Pragmas can be used by themselves terminated with a $(SINGLEQUOTE ;),
they can influence a statement, a block of statements, a declaration, or
a block of declarations.
)
$(P Pragmas can appear as either declarations,
$(I Pragma) $(GLINK2 attribute, DeclarationBlock),
or as statements,
$(GLINK2 statement, PragmaStatement).
)
-----------------
pragma(ident); // just by itself
pragma(ident) declaration; // influence one declaration
pragma(ident): // influence subsequent declarations
declaration;
declaration;
pragma(ident) // influence block of declarations
{
declaration;
declaration;
}
pragma(ident) statement; // influence one statement
pragma(ident) // influence block of statements
{
statement;
statement;
}
-----------------
$(P The kind of pragma it is determined by the $(I Identifier).
$(I ExpressionList) is a comma-separated list of
$(ASSIGNEXPRESSION)s. The $(ASSIGNEXPRESSION)s must be
parsable as expressions, but what they mean semantically
is up to the individual pragma semantics.
)
$(H2 $(LEGACY_LNAME2 Predefined-Pragmas, predefined-pragmas, Predefined Pragmas))
$(P All implementations must support these, even if by just ignoring them:)
$(UL
$(LI $(LINK2 #inline, pragma inline))
$(LI $(LINK2 #lib, pragma lib))
$(LI $(LINK2 #mangle, pragma mangle))
$(LI $(LINK2 #msg, pragma msg))
$(LI $(LINK2 #startaddress, pragma startaddress))
)
$(DL
$(DT $(LNAME2 inline, $(D inline)))
$(DD $(P Affects whether functions are inlined or not. If at the declaration level, it
affects the functions declared in the block it controls. If inside a function, it
affects the function it is enclosed by. If there are multiple pragma inlines in a function,
the lexically last one takes effect.)
$(P It takes three forms:)
$(OL
$(LI
---
pragma(inline)
---
Sets the behavior to match the default behavior set by the compiler switch
$(DDSUBLINK dmd, switch-inline, $(TT -inline)).
)
$(LI
---
pragma(inline, false)
---
Functions are never inlined.
)
$(LI
---
pragma(inline, true)
---
If a function cannot be inlined with the $(DDSUBLINK dmd, switch-inline, $(TT -inline))
switch, an error message is issued. This is expected to be improved in the future to causing
functions to always be inlined regardless of compiler switch settings. Whether a compiler can
inline a particular function or not is implementation defined.
)
)
---
pragma(inline):
int foo(int x) // foo() is never inlined
{
pragma(inline, true);
++x;
pragma(inline, false); // supercedes the others
return x + 3;
}
---
)
$(DT $(LNAME2 lib, $(D lib)))
$(DD Inserts a directive in the object file to link in the library
specified by the $(ASSIGNEXPRESSION).
The $(ASSIGNEXPRESSION)s must be a string literal:
-----------------
pragma(lib, "foo.lib");
-----------------
)
$(DT $(LNAME2 mangle, $(D mangle)))
$(DD Overrides the default mangling for a symbol. It's only effective
when the symbol is a function declaration or a variable declaration.
For example this allows linking to a symbol which is a D keyword, which would normally
be disallowed as a symbol name:
-----------------
pragma(mangle, "body")
extern(C) void body_func();
-----------------
)
$(DT $(LNAME2 msg, $(D msg)))
$(DD Constructs a message from the arguments and prints to the standard error stream while compiling:
-----------------
pragma(msg, "compiling...", 1, 1.0);
-----------------
)
$(DT $(LNAME2 startaddress, $(D startaddress)))
$(DD Puts a directive into the object file saying that the
function specified in the first argument will be the
start address for the program:
-----------------
void foo() { ... }
pragma(startaddress, foo);
-----------------
This is not normally used for application level programming,
but is for specialized systems work.
For applications code, the start address is taken care of
by the runtime library.
)
)
$(H2 $(LNAME2 vendor_specific_pragmas, Vendor Specific Pragmas))
$(P Vendor specific pragma $(I Identifier)s can be defined if they
are prefixed by the vendor's trademarked name, in a similar manner
to version identifiers:
)
-----------------
pragma(DigitalMars_funky_extension) { ... }
-----------------
$(P Compilers must diagnose an error for unrecognized $(I Pragma)s,
even if they are vendor specific ones. This implies that vendor
specific pragmas should be wrapped in version statements:
)
-----------------
version (DigitalMars)
{
pragma(DigitalMars_funky_extension)
{ ... }
}
-----------------
$(SPEC_SUBNAV_PREV_NEXT attribute, Attributes, expression, Expressions)
)
Macros:
CHAPTER=9
TITLE=Pragmas

1127
constants-gen/traits.dd Normal file
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File diff suppressed because it is too large Load Diff

4
constants-gen/update-constants.sh Executable file
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#!/bin/sh
wget https://raw.githubusercontent.com/dlang/dlang.org/master/spec/pragma.dd -O pragma.dd
wget https://raw.githubusercontent.com/dlang/dlang.org/master/spec/traits.dd -O traits.dd
rdmd generator.d

877
src/dcd/common/constants.d
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@ -18,6 +18,8 @@
module dcd.common.constants;
public import dcd.common.constants2;
// The lists in this module should be kept sorted.
struct ConstantCompletion
@ -26,87 +28,12 @@ struct ConstantCompletion
string ddoc;
}
/**
* Pragma arguments
*/
immutable ConstantCompletion[] pragmas = [
// docs from https://github.com/dlang/dlang.org/blob/master/spec/pragma.dd
ConstantCompletion("inline", `$(P Affects whether functions are inlined or not. If at the declaration level, it
affects the functions declared in the block it controls. If inside a function, it
affects the function it is enclosed by. If there are multiple pragma inlines in a function,
the lexically last one takes effect.)
$(P It takes three forms:)
$(OL
$(LI
---
pragma(inline)
---
Sets the behavior to match the default behavior set by the compiler switch
$(DDSUBLINK dmd, switch-inline, $(TT -inline)).
)
$(LI
---
pragma(inline, false)
---
Functions are never inlined.
)
$(LI
---
pragma(inline, true)
---
If a function cannot be inlined with the $(DDSUBLINK dmd, switch-inline, $(TT -inline))
switch, an error message is issued. This is expected to be improved in the future to causing
functions to always be inlined regardless of compiler switch settings. Whether a compiler can
inline a particular function or not is implementation defined.
)
)
---
pragma(inline):
int foo(int x) // foo() is never inlined
{
pragma(inline, true);
++x;
pragma(inline, false); // supercedes the others
return x + 3;
}
---`),
ConstantCompletion("lib", `Inserts a directive in the object file to link in the library
specified by the $(ASSIGNEXPRESSION).
The $(ASSIGNEXPRESSION)s must be a string literal:
-----------------
pragma(lib, "foo.lib");
-----------------`),
ConstantCompletion("mangle", `Overrides the default mangling for a symbol. It's only effective
when the symbol is a function declaration or a variable declaration.
For example this allows linking to a symbol which is a D keyword, which would normally
be disallowed as a symbol name:
-----------------
pragma(mangle, "body")
extern(C) void body_func();
-----------------`),
ConstantCompletion("msg", `Constructs a message from the arguments and prints to the standard error stream while compiling:
-----------------
pragma(msg, "compiling...", 1, 1.0);
-----------------`),
ConstantCompletion("startaddress", `Puts a directive into the object file saying that the
function specified in the first argument will be the
start address for the program:
-----------------
void foo() { ... }
pragma(startaddress, foo);
-----------------
This is not normally used for application level programming,
but is for specialized systems work.
For applications code, the start address is taken care of
by the runtime library.`)
];
/**
* Linkage types
*/
immutable ConstantCompletion[] linkages = [
// https://dlang.org/spec/attribute.html#linkage
// custom typed instead of copied from the docs to fit completions better
ConstantCompletion("C", "Enforces C calling conventions for the function, no mangling."),
ConstantCompletion("C++", "Offers limited compatibility with C++."),
ConstantCompletion("D", "Default D mangling and calling conventions."),
@ -117,804 +44,6 @@ immutable ConstantCompletion[] linkages = [
ConstantCompletion("Windows", "Enforces Win32/`__stdcall` conventions for the function.")
];
private immutable string isLazyDoc = `$(P Takes one argument. If that argument is a declaration,
$(D true) is returned if it is $(D_KEYWORD ref), $(D_KEYWORD out),
or $(D_KEYWORD lazy), otherwise $(D false).
)
---
void fooref(ref int x)
{
static assert(__traits(isRef, x));
static assert(!__traits(isOut, x));
static assert(!__traits(isLazy, x));
}
void fooout(out int x)
{
static assert(!__traits(isRef, x));
static assert(__traits(isOut, x));
static assert(!__traits(isLazy, x));
}
void foolazy(lazy int x)
{
static assert(!__traits(isRef, x));
static assert(!__traits(isOut, x));
static assert(__traits(isLazy, x));
}
---`;
/**
* Traits arguments
*/
immutable ConstantCompletion[] traits = [
// https://github.com/dlang/dlang.org/blob/master/spec/traits.dd
ConstantCompletion("allMembers", `Takes a single argument, which must evaluate to either
a type or an expression of type.
A tuple of string literals is returned, each of which
is the name of a member of that type combined with all
of the members of the base classes (if the type is a class).
No name is repeated.
Builtin properties are not included.`),
ConstantCompletion("classInstanceSize", `Takes a single argument, which must evaluate to either
a class type or an expression of class type.
The result
is of type $(CODE size_t), and the value is the number of
bytes in the runtime instance of the class type.
It is based on the static type of a class, not the
polymorphic type.`),
ConstantCompletion("compiles", `$(P Returns a bool $(D true) if all of the arguments
compile (are semantically correct).
The arguments can be symbols, types, or expressions that
are syntactically correct.
The arguments cannot be statements or declarations.
)
$(P If there are no arguments, the result is $(D false).)
---
import std.stdio;
struct S
{
static int s1;
int s2;
}
int foo();
int bar();
void main()
{
writeln(__traits(compiles)); // false
writeln(__traits(compiles, foo)); // true
writeln(__traits(compiles, foo + 1)); // true
writeln(__traits(compiles, &foo + 1)); // false
writeln(__traits(compiles, typeof(1))); // true
writeln(__traits(compiles, S.s1)); // true
writeln(__traits(compiles, S.s3)); // false
writeln(__traits(compiles, 1,2,3,int,long,std)); // true
writeln(__traits(compiles, 3[1])); // false
writeln(__traits(compiles, 1,2,3,int,long,3[1])); // false
}
---
$(P This is useful for:)
$(UL
$(LI Giving better error messages inside generic code than
the sometimes hard to follow compiler ones.)
$(LI Doing a finer grained specialization than template
partial specialization allows for.)
)`),
ConstantCompletion("derivedMembers", `$(P Takes a single argument, which must evaluate to either
a type or an expression of type.
A tuple of string literals is returned, each of which
is the name of a member of that type.
No name is repeated.
Base class member names are not included.
Builtin properties are not included.
)
---
import std.stdio;
class D
{
this() { }
~this() { }
void foo() { }
int foo(int) { return 0; }
}
void main()
{
auto a = [__traits(derivedMembers, D)];
writeln(a); // ["__ctor", "__dtor", "foo"]
}
---
$(P The order in which the strings appear in the result
is not defined.)`),
ConstantCompletion("getAliasThis", `Takes one argument, a symbol of aggregate type.
If the given aggregate type has $(D alias this), returns a list of
$(D alias this) names, by a tuple of $(D string)s.
Otherwise returns an empty tuple.`),
ConstantCompletion("getAttributes", `$(P
Takes one argument, a symbol. Returns a tuple of all attached user defined attributes.
If no UDA's exist it will return an empty tuple.
)
$(P
For more information, see: $(DDSUBLINK spec/attribute, uda, User Defined Attributes)
)
---
@(3) int a;
@("string", 7) int b;
enum Foo;
@Foo int c;
pragma(msg, __traits(getAttributes, a));
pragma(msg, __traits(getAttributes, b));
pragma(msg, __traits(getAttributes, c));
---
Prints:
$(CONSOLE
tuple(3)
tuple("string", 7)
tuple((Foo))
)`),
ConstantCompletion("getFunctionAttributes", `$(P
Takes one argument which must either be a function symbol, function literal,
or a function pointer. It returns a string tuple of all the attributes of
that function $(B excluding) any user defined attributes (UDAs can be
retrieved with the $(RELATIVE_LINK2 get-attributes, getAttributes) trait).
If no attributes exist it will return an empty tuple.
)
$(B Note:) The order of the attributes in the returned tuple is
implementation-defined and should not be relied upon.
$(P
A list of currently supported attributes are:)
$(UL $(LI $(D pure), $(D nothrow), $(D @nogc), $(D @property), $(D @system), $(D @trusted), $(D @safe), and $(D ref)))
$(B Note:) $(D ref) is a function attribute even though it applies to the return type.
$(P
Additionally the following attributes are only valid for non-static member functions:)
$(UL $(LI $(D const), $(D immutable), $(D inout), $(D shared)))
For example:
---
int sum(int x, int y) pure nothrow { return x + y; }
// prints ("pure", "nothrow", "@system")
pragma(msg, __traits(getFunctionAttributes, sum));
struct S
{
void test() const @system { }
}
// prints ("const", "@system")
pragma(msg, __traits(getFunctionAttributes, S.test));
---
$(P Note that some attributes can be inferred. For example:)
---
// prints ("pure", "nothrow", "@nogc", "@trusted")
pragma(msg, __traits(getFunctionAttributes, (int x) @trusted { return x * 2; }));
---`),
ConstantCompletion("getFunctionVariadicStyle", `$(P
Takes one argument which must either be a function symbol, or a type
that is a function, delegate or a function pointer.
It returns a string identifying the kind of
$(LINK2 function.html#variadic, variadic arguments) that are supported.
)
$(TABLE2 getFunctionVariadicStyle,
$(THEAD string returned, kind, access, example)
$(TROW $(D "none"), not a variadic function, &nbsp;, $(D void foo();))
$(TROW $(D "argptr"), D style variadic function, $(D _argptr) and $(D _arguments), $(D void bar(...)))
$(TROW $(D "stdarg"), C style variadic function, $(LINK2 $(ROOT_DIR)phobos/core_stdc_stdarg.html, $(D core.stdc.stdarg)), $(D extern (C) void abc(int, ...)))
$(TROW $(D "typesafe"), typesafe variadic function, array on stack, $(D void def(int[] ...)))
)
---
import core.stdc.stdarg;
void novar() {}
extern(C) void cstyle(int, ...) {}
extern(C++) void cppstyle(int, ...) {}
void dstyle(...) {}
void typesafe(int[]...) {}
static assert(__traits(getFunctionVariadicStyle, novar) == "none");
static assert(__traits(getFunctionVariadicStyle, cstyle) == "stdarg");
static assert(__traits(getFunctionVariadicStyle, cppstyle) == "stdarg");
static assert(__traits(getFunctionVariadicStyle, dstyle) == "argptr");
static assert(__traits(getFunctionVariadicStyle, typesafe) == "typesafe");
static assert(__traits(getFunctionVariadicStyle, (int[] a...) {}) == "typesafe");
static assert(__traits(getFunctionVariadicStyle, typeof(cstyle)) == "stdarg");
---`),
ConstantCompletion("getLinkage", `$(P Takes one argument, which is a declaration symbol, or the type of a function,
delegate, or pointer to function.
Returns a string representing the $(LINK2 attribute.html#LinkageAttribute, LinkageAttribute)
of the declaration.
The string is one of:
)
$(UL
$(LI $(D "D"))
$(LI $(D "C"))
$(LI $(D "C++"))
$(LI $(D "Windows"))
$(LI $(D "Pascal"))
$(LI $(D "Objective-C"))
$(LI $(D "System"))
)
---
extern (C) int fooc();
alias aliasc = fooc;
static assert(__traits(getLinkage, fooc) == "C");
static assert(__traits(getLinkage, aliasc) == "C");
---`),
ConstantCompletion("getMember", `$(P Takes two arguments, the second must be a string.
The result is an expression formed from the first
argument, followed by a $(SINGLEQUOTE .), followed by the second
argument as an identifier.
)
---
import std.stdio;
struct S
{
int mx;
static int my;
}
void main()
{
S s;
__traits(getMember, s, "mx") = 1; // same as s.mx=1;
writeln(__traits(getMember, s, "m" ~ "x")); // 1
__traits(getMember, S, "mx") = 1; // error, no this for S.mx
__traits(getMember, S, "my") = 2; // ok
}
---`),
ConstantCompletion("getOverloads", `$(P The first argument is an aggregate (e.g. struct/class/module).
The second argument is a string that matches the name of
one of the functions in that aggregate.
The result is a tuple of all the overloads of that function.
)
---
import std.stdio;
class D
{
this() { }
~this() { }
void foo() { }
int foo(int) { return 2; }
}
void main()
{
D d = new D();
foreach (t; __traits(getOverloads, D, "foo"))
writeln(typeid(typeof(t)));
alias b = typeof(__traits(getOverloads, D, "foo"));
foreach (t; b)
writeln(typeid(t));
auto i = __traits(getOverloads, d, "foo")[1](1);
writeln(i);
}
---
Prints:
$(CONSOLE
void()
int()
void()
int()
2
)`),
ConstantCompletion("getParameterStorageClasses", `$(P
Takes two arguments.
The first must either be a function symbol, or a type
that is a function, delegate or a function pointer.
The second is an integer identifying which parameter, where the first parameter is
0.
It returns a tuple of strings representing the storage classes of that parameter.
)
---
ref int foo(return ref const int* p, scope int* a, out int b, lazy int c);
static assert(__traits(getParameterStorageClasses, foo, 0)[0] == "return");
static assert(__traits(getParameterStorageClasses, foo, 0)[1] == "ref");
static assert(__traits(getParameterStorageClasses, foo, 1)[0] == "scope");
static assert(__traits(getParameterStorageClasses, foo, 2)[0] == "out");
static assert(__traits(getParameterStorageClasses, typeof(&foo), 3)[0] == "lazy");
---`),
ConstantCompletion("getPointerBitmap", `$(P The argument is a type.
The result is an array of $(D size_t) describing the memory used by an instance of the given type.
)
$(P The first element of the array is the size of the type (for classes it is
the $(GBLINK classInstanceSize)).)
$(P The following elements describe the locations of GC managed pointers within the
memory occupied by an instance of the type.
For type T, there are $(D T.sizeof / size_t.sizeof) possible pointers represented
by the bits of the array values.)
$(P This array can be used by a precise GC to avoid false pointers.)
---
class C
{
// implicit virtual function table pointer not marked
// implicit monitor field not marked, usually managed manually
C next;
size_t sz;
void* p;
void function () fn; // not a GC managed pointer
}
struct S
{
size_t val1;
void* p;
C c;
byte[] arr; // { length, ptr }
void delegate () dg; // { context, func }
}
static assert (__traits(getPointerBitmap, C) == [6*size_t.sizeof, 0b010100]);
static assert (__traits(getPointerBitmap, S) == [7*size_t.sizeof, 0b0110110]);
---`),
ConstantCompletion("getProtection", `$(P The argument is a symbol.
The result is a string giving its protection level: "public", "private", "protected", "export", or "package".
)
---
import std.stdio;
class D
{
export void foo() { }
public int bar;
}
void main()
{
D d = new D();
auto i = __traits(getProtection, d.foo);
writeln(i);
auto j = __traits(getProtection, d.bar);
writeln(j);
}
---
Prints:
$(CONSOLE
export
public
)`),
ConstantCompletion("getUnitTests", `$(P
Takes one argument, a symbol of an aggregate (e.g. struct/class/module).
The result is a tuple of all the unit test functions of that aggregate.
The functions returned are like normal nested static functions,
$(DDSUBLINK glossary, ctfe, CTFE) will work and
$(DDSUBLINK spec/attribute, uda, UDA's) will be accessible.
)
$(H3 Note:)
$(P
The -unittest flag needs to be passed to the compiler. If the flag
is not passed $(CODE __traits(getUnitTests)) will always return an
empty tuple.
)
---
module foo;
import core.runtime;
import std.stdio;
struct name { string name; }
class Foo
{
unittest
{
writeln("foo.Foo.unittest");
}
}
@name("foo") unittest
{
writeln("foo.unittest");
}
template Tuple (T...)
{
alias Tuple = T;
}
shared static this()
{
// Override the default unit test runner to do nothing. After that, "main" will
// be called.
Runtime.moduleUnitTester = { return true; };
}
void main()
{
writeln("start main");
alias tests = Tuple!(__traits(getUnitTests, foo));
static assert(tests.length == 1);
alias attributes = Tuple!(__traits(getAttributes, tests[0]));
static assert(attributes.length == 1);
foreach (test; tests)
test();
foreach (test; __traits(getUnitTests, Foo))
test();
}
---
$(P By default, the above will print:)
$(CONSOLE
start main
foo.unittest
foo.Foo.unittest
)`),
ConstantCompletion("getVirtualFunctions", `The same as $(GLINK getVirtualMethods), except that
final functions that do not override anything are included.`),
ConstantCompletion("getVirtualIndex", `Takes a single argument which must evaluate to a function.
The result is a $(CODE ptrdiff_t) containing the index
of that function within the vtable of the parent type.
If the function passed in is final and does not override
a virtual function, $(D -1) is returned instead.`),
ConstantCompletion("getVirtualMethods", `$(P The first argument is a class type or an expression of
class type.
The second argument is a string that matches the name of
one of the functions of that class.
The result is a tuple of the virtual overloads of that function.
It does not include final functions that do not override anything.
)
---
import std.stdio;
class D
{
this() { }
~this() { }
void foo() { }
int foo(int) { return 2; }
}
void main()
{
D d = new D();
foreach (t; __traits(getVirtualMethods, D, "foo"))
writeln(typeid(typeof(t)));
alias b = typeof(__traits(getVirtualMethods, D, "foo"));
foreach (t; b)
writeln(typeid(t));
auto i = __traits(getVirtualMethods, d, "foo")[1](1);
writeln(i);
}
---
Prints:
$(CONSOLE
void()
int()
void()
int()
2
)`),
ConstantCompletion("hasMember", `$(P The first argument is a type that has members, or
is an expression of a type that has members.
The second argument is a string.
If the string is a valid property of the type,
$(D true) is returned, otherwise $(D false).
)
---
import std.stdio;
struct S
{
int m;
}
void main()
{
S s;
writeln(__traits(hasMember, S, "m")); // true
writeln(__traits(hasMember, s, "m")); // true
writeln(__traits(hasMember, S, "y")); // false
writeln(__traits(hasMember, int, "sizeof")); // true
}
---`),
ConstantCompletion("identifier", `$(P Takes one argument, a symbol. Returns the identifier
for that symbol as a string literal.
)
---
import std.stdio;
int var = 123;
pragma(msg, typeof(var)); // int
pragma(msg, typeof(__traits(identifier, var))); // string
writeln(var); // 123
writeln(__traits(identifier, var)); // "var"
---`),
ConstantCompletion("isAbstractClass", `$(P If the arguments are all either types that are abstract classes,
or expressions that are typed as abstract classes, then $(D true)
is returned.
Otherwise, $(D false) is returned.
If there are no arguments, $(D false) is returned.)
---
import std.stdio;
abstract class C { int foo(); }
void main()
{
C c;
writeln(__traits(isAbstractClass, C));
writeln(__traits(isAbstractClass, c, C));
writeln(__traits(isAbstractClass));
writeln(__traits(isAbstractClass, int*));
}
---
Prints:
$(CONSOLE
true
true
false
false
)`),
ConstantCompletion("isAbstractFunction", `$(P Takes one argument. If that argument is an abstract function,
$(D true) is returned, otherwise $(D false).
)
---
import std.stdio;
struct S
{
void bar() { }
}
class C
{
void bar() { }
}
class AC
{
abstract void foo();
}
void main()
{
writeln(__traits(isAbstractFunction, C.bar)); // false
writeln(__traits(isAbstractFunction, S.bar)); // false
writeln(__traits(isAbstractFunction, AC.foo)); // true
}
---`),
ConstantCompletion("isArithmetic", `$(P If the arguments are all either types that are arithmetic types,
or expressions that are typed as arithmetic types, then $(D true)
is returned.
Otherwise, $(D false) is returned.
If there are no arguments, $(D false) is returned.)
---
import std.stdio;
void main()
{
int i;
writeln(__traits(isArithmetic, int));
writeln(__traits(isArithmetic, i, i+1, int));
writeln(__traits(isArithmetic));
writeln(__traits(isArithmetic, int*));
}
---
Prints:
$(CONSOLE
true
true
false
false
)`),
ConstantCompletion("isAssociativeArray", `Works like $(D isArithmetic), except it's for associative array types.`),
ConstantCompletion("isDisabled", r"$(P Takes one argument and returns `true` if it's a function declaration
marked with `@disable`.)
---
struct Foo
{
@disable void foo();
void bar(){}
}
static assert(__traits(isDisabled, Foo.foo));
static assert(!__traits(isDisabled, Foo.bar));
---
$(P For any other declaration even if `@disable` is a syntactically valid
attribute `false` is returned because the annotation has no effect.)
---
@disable struct Bar{}
static assert(!__traits(isDisabled, Bar));
---"),
ConstantCompletion("isFinalClass", `Works like $(D isAbstractClass), except it's for final classes.`),
ConstantCompletion("isFinalFunction", `$(P Takes one argument. If that argument is a final function,
$(D true) is returned, otherwise $(D false).
)
---
import std.stdio;
struct S
{
void bar() { }
}
class C
{
void bar() { }
final void foo();
}
final class FC
{
void foo();
}
void main()
{
writeln(__traits(isFinalFunction, C.bar)); // false
writeln(__traits(isFinalFunction, S.bar)); // false
writeln(__traits(isFinalFunction, C.foo)); // true
writeln(__traits(isFinalFunction, FC.foo)); // true
}
---`),
ConstantCompletion("isFloating", `Works like $(D isArithmetic), except it's for floating
point types (including imaginary and complex types).`),
ConstantCompletion("isFuture", "Takes one argument. It returns `true` if the argument is a symbol
marked with the `@future` keyword, otherwise `false`. Currently, only
functions and variable declarations have support for the `@future` keyword."),
ConstantCompletion("isIntegral", `Works like $(D isArithmetic), except it's for integral
types (including character types).`),
ConstantCompletion("isLazy", isLazyDoc),
ConstantCompletion("isNested", `Takes one argument.
It returns $(D true) if the argument is a nested type which internally
stores a context pointer, otherwise it returns $(D false).
Nested types can be $(DDSUBLINK spec/class, nested, classes),
$(DDSUBLINK spec/struct, nested, structs), and
$(DDSUBLINK spec/function, variadicnested, functions).`),
ConstantCompletion("isOut", isLazyDoc),
ConstantCompletion("isOverrideFunction", `$(P Takes one argument. If that argument is a function marked with
$(D_KEYWORD override), $(D true) is returned, otherwise $(D false).
)
---
import std.stdio;
class Base
{
void foo() { }
}
class Foo : Base
{
override void foo() { }
void bar() { }
}
void main()
{
writeln(__traits(isOverrideFunction, Base.foo)); // false
writeln(__traits(isOverrideFunction, Foo.foo)); // true
writeln(__traits(isOverrideFunction, Foo.bar)); // false
}
---`),
ConstantCompletion("isPOD", `$(P Takes one argument, which must be a type. It returns
$(D true) if the type is a $(DDSUBLINK glossary, pod, POD) type, otherwise $(D false).)`),
ConstantCompletion("isRef", isLazyDoc),
ConstantCompletion("isSame", `$(P Takes two arguments and returns bool $(D true) if they
are the same symbol, $(D false) if not.)
---
import std.stdio;
struct S { }
int foo();
int bar();
void main()
{
writeln(__traits(isSame, foo, foo)); // true
writeln(__traits(isSame, foo, bar)); // false
writeln(__traits(isSame, foo, S)); // false
writeln(__traits(isSame, S, S)); // true
writeln(__traits(isSame, std, S)); // false
writeln(__traits(isSame, std, std)); // true
}
---
$(P If the two arguments are expressions made up of literals
or enums that evaluate to the same value, true is returned.)`),
ConstantCompletion("isScalar", `Works like $(D isArithmetic), except it's for scalar types.`),
ConstantCompletion("isStaticArray", `Works like $(D isArithmetic), except it's for static array types.`),
ConstantCompletion("isStaticFunction", `Takes one argument. If that argument is a static function,
meaning it has no context pointer,
$(D true) is returned, otherwise $(D false).`),
ConstantCompletion("isTemplate", `$(P Takes one argument. If that argument is a template then $(D true) is returned,
otherwise $(D false).
)
---
void foo(T)(){}
static assert(__traits(isTemplate,foo));
static assert(!__traits(isTemplate,foo!int()));
static assert(!__traits(isTemplate,"string"));
---`),
ConstantCompletion("isUnsigned", `Works like $(D isArithmetic), except it's for unsigned types.`),
ConstantCompletion("isVirtualFunction", `The same as $(GLINK isVirtualMethod), except
that final functions that don't override anything return true.`),
ConstantCompletion("isVirtualMethod", `Takes one argument. If that argument is a virtual function,
$(D true) is returned, otherwise $(D false).
Final functions that don't override anything return false.`),
ConstantCompletion("parent", `Takes a single argument which must evaluate to a symbol.
The result is the symbol that is the parent of it.`)
];
/**
* Scope conditions
*/

1072
src/dcd/common/constants2.d Normal file
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1
tests/tc_traits/expected.txt
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@ -23,6 +23,7 @@ isAbstractClass k
isAbstractFunction k
isArithmetic k
isAssociativeArray k
isDeprecated k
isDisabled k
isFinalClass k
isFinalFunction k