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bfad29003640f720964ed52ea97e9e8de19d170c
ldc/interpret.c
Alexey Prokhin f2237662df Squashed 'dmd2/' changes from 10017d5..3443f38 
3443f38 Fix issue 7493  Initialization of void[][N]
0b371da foreach can run semantic again
7216e2a fix Issue 7735 - Functions with variadic void[][]... arguments corrupt passed data
4fb2b2a Merge pull request #850 from 9rnsr/fix7773
9c59931 Merge pull request #851 from donc/ctfe7785pointerToVar
407f7e4 Merge pull request #852 from donc/segfault7639
9370f83 Fix issue 7380 Crash trying to use address of variable in struct constructor at module level
240866b Fix issue 7639 Undefined enum AA key crashes compiler
19b7096 Fix issue 7785 [CTFE] ICE when slicing pointer to variable
d9b11f6 fix Issue 7773 - UCFS syntax on built-in attributes too?
296d812 Merge pull request #846 from donc/ctfe7781segfault
65aca2d Merge pull request #848 from donc/regression7751
5576737 Merge pull request #849 from donc/bug7794
0310838 Merge pull request #828 from 9rnsr/fix7751
4027e4f Fix issue 7794 Sea of errors when calling regex() after compile error
59cc12d Fix issue 7781 [CTFE] Segmentation fault on 'mixin({return;}());'
3430947 fix seg fault in fail91.d
948274e Merge pull request #824 from donc/regression7745
22ac4b1 Merge pull request #826 from 9rnsr/fix6659
1c15841 Merge pull request #823 from redstar/mscclean
5f54752 Merge pull request #827 from 9rnsr/fix7694
399e4a3 Merge pull request #844 from donc/regression7782
516f49b Fix issue 7789 [CTFE] null pointer exception on setting array length
d74b354 Fix issue 7782 Regression: ICE with wrong import syntax
0269194 Fix issue 7751 [ICE] (Regression 2.059head) From auto and forward reference
42ad236 Merge pull request #830 from 9rnsr/fix_ufcs
67bf025 Merge pull request #832 from 9rnsr/fix7608
d13f107 Merge pull request #829 from 9rnsr/fix7754
e25cbe2 Merge pull request #834 from 9rnsr/fix2367
7fac235 merge D2 pull #842
c836773 Merge pull request #836 from 9rnsr/fix7757
a2754c5 Merge pull request #839 from 9rnsr/fix7768
4948836 fix Issue 7694 - Internal error: e2ir.c 1251 when calling member function inside struct via alias param
9f23335 Merge pull request #838 from 9rnsr/fix7621
92eba60 Merge pull request #840 from 9rnsr/fix7769
8fae3c2 fix issue 7742 - 'More initializers than fields' error with correct number of fields
6c2d706 to enum
35e4f08 fix Issue 7769 - relax inout rule doesn't work for template function
96a0105 fix Issue 7768 - More readable template error messages
8012d58 Merge pull request #831 from 9rnsr/fix7743
9c0cbdd fix Issue 7621 - Immutable type equivalence problem
f67f313 Merge pull request #833 from 9rnsr/fix7731
29754dd Merge pull request #837 from braddr/cleanup-backend2
374109a restore original binary() function and re-fix the new version
78c04aa fix Issue 7757 - Inout function with lazy inout parameter doesn't compile
50c34e9 fix Issue 7754 - static this() in template is stripped during header gen
11acdff Fix auto tester breaking.
f0b7157 fix Issue 7755 - regression(2.059head): ICE in glue.c
cfceb77 fix Issue 7751 - [ICE] From auto and forward reference
7a86807 fix Issue 2367 - Overloading error with string literals
6039c40 fix Issue 7731 - Assertion failure: 't' on line 7911 in file 'mtype.c'
aea3a39 fix Issue 7608 - __traits(allMembers) is broken
f46f07a fix Issue 7743 - Parsing problem with nothrow delegate
fa9d29f Revert "Revert "Refactor for UFCS property getter/setter resolution.""
d9698d8 Revert "Revert "fix Issue 7722 - Refuse normal functions to be used as properties""
0fbc772 Revert "Revert "Allow property function has two arguments""
07a3b09 fix Issue 6659 - Destructor in range foreach called after initialization
e499d4d Fix issue 7745 Regression(2.059beta) Methods defined in external object files when a pointer to it is taken
79a74e1 Fixes an unknown pragma warning.
2b12052 Fix issue 176 [module] message "module and package have the same name"
90e89a4 Merge pull request #814 from 9rnsr/fix7713
3ab0e79 Merge pull request #818 from donc/assoc7732
b3360e9 Fix issue 7732 [CTFE] wrong code for a struct called AssociativeArray
05f0b08 Merge pull request #779 from 9rnsr/fix7534
867e567 Revert "Allow property function has two arguments"
9171aeb Revert "fix Issue 7722 - Refuse normal functions to be used as properties"
989ced7 Revert "Refactor for UFCS property getter/setter resolution."
e9b5292 Refactor for UFCS property getter/setter resolution.
761d000 fix Issue 7722 - Refuse normal functions to be used as properties
9f5956b Allow property function has two arguments
1a11862 Revert "Allow property function has two arguments"
32f57e5 Revert "fix Issue 7722 - Refuse normal functions to be used as properties"
6489bb4 Revert "Refactor for UFCS property getter/setter resolution."
214296f Merge pull request #817 from 9rnsr/fix_ufcs
c3c7f2a Merge pull request #816 from donc/voidctfe6438
185d031 Refactor for UFCS property getter/setter resolution.
08bf89d fix Issue 7722 - Refuse normal functions to be used as properties
f0e3433 Allow property function has two arguments
1b67ac9 Direct check by Type::reliesOnTident
a3cd7d9 fix Issue 7713 - lambda inference doesn't work on template function argument
1762112 Fix issue 6438 - [CTFE] wrong error "value used before set" when slicing =void array
ace1eca fix complex constant folding
76f9b22 Consider return type covariance.
f700dbc fix Issue 7534 - Allow attribute-overloading of an overridden method
cba8f5c Merge pull request #763 from 9rnsr/fix7578
392d93f Merge pull request #815 from dawgfoto/fixSegFault
e48aba2 merge part of pull #769
d72a17e revert dd5a543
24d860b error(Loc loc,) doesn't abort program
4c79117 Use correct opcodes for moving cfloat from st->xmm and xmm->st
af875ff Merge pull request #785 from braddr/cleanup-backend2
9d3021a remove debugging printfs
b3df5ee Merge pull request #807 from dawgfoto/fix7698
f005537 Merge pull request #802 from dawgfoto/fixVC
65a145d Merge pull request #803 from donc/ctfeunion6681yebblies
1cf39ca Merge pull request #812 from 9rnsr/fix_ufcs
d846c3c Merge pull request #808 from 9rnsr/fix7702
fd0a492 fix Issue 7670 - UFCS problem with @property and structs
1ad35b2 Fix for UFCS with property syntax, and add exhaustive test
96f15a1 Resolve broken build after merging
4712aab fix regression
4e05482 Merge pull request #805 from donc/regression7681
245a107 dt_ functions aren't x86 specific
b35f43a another missing loc in an error() call
001addb minor cleanups
2fb1e46 make util_assert take a const string
907da39 cleanup whitespace in binary(), add binary() that takes the length of the string to search for
59d0425 Merge pull request #804 from braddr/nearsighted
d725eed Merge pull request #806 from donc/ctfe7633equalmsg
12a5c26 Merge pull request #811 from donc/bug7699
4279d5e revert the revert
c895c3b revert pull #809
865fb20 fix Issue 5733 - Calling opDispatch As Template Results in Compiler Infinite Loop
96e16d3 fix Issue 7702 - opDispatch goes into infinite loop
5e343c0 Remove special case for DotIdExp and opDispatch semantic, it isn't need anymore
1a9d607 Fix issue 7699 - Cannot get frame pointer to in contract when compiling with -inline
d1476eb Merge pull request #809 from 9rnsr/fix_funclit
afc7c60 allow out-of-order semantic analysis of fields
17da3a0 fix Issue 7705 - lambda syntax doesn't allow some valid signatures
e29d06d fix issue 7698
911d053 Fix issue 7633 - Missing CTFE error message
3802dde Fix issue 7681 Regression(2.059head):ICE:opCatAssign(delegate) to undefined identifier
8da4121 near-ectomy
cd6dc83 fix Library::error()s format string to take a const char*
f3f03c6 switch to apply()
faf873a fix Issue 3510 - Cannot forward reference a templated type from within a template mixin
23aa2be fix Issue 3509 - Cannot forward reference a template mixin's members in a compile-time context
e81309b Add missing 'loc' to error message.
b6898e3 Fix issue 6681 - struct constructor call is converted to struct literal that breaks union initialization
b79afba long double => longdouble
e48c319 Merge pull request #742 from yebblies/issue5879
d74485a Merge pull request #787 from eco/ddoc-srcfilename
3038cb9 Merge pull request #795 from dawgfoto/fixComment
89a039a Merge pull request #801 from dawgfoto/fix4507
c17c2d8 fix issue 4507
dd86c72 Merge pull request #796 from dawgfoto/fixVC
a516588 Merge pull request #797 from 9rnsr/fix7682
1b9839a Merge pull request #799 from 9rnsr/fix6982
4596774 Merge pull request #800 from 9rnsr/fix_type_deduction
b68d546 forgot about @system
bfe1083 add attributes to toHash
8f819d6 Stop special case in mutableOf/makeMutable with inout type.
319b1a3 Fix the lacks of type merging in Type::mutableOf() and uhSharedOf()
cfe7450 fix Issue 7671 - Broken inout deduction of shared(inout(T[n])) from immutable(int[3])
aca5c37 Stop too eager call of TypeAArray::getImpl() When implicitConvTo(non aa Tstruct => Taarray)
50b2a97 fix Issue 6982 - immutability isn't respected on associative array assignment
a5daa5e fix Issue 7684 - IFTI and shared overload doesn't work
e43fbac fix Issue 7682 - shared array type and "cast() is not an lvalue" error
8191801 cpp_prettyident only needed for C++
4487f75 fix ldval
525647c tparam is the specialization
f893925 fix issue 7592 d847c1c2dd
108b25d Merge pull request #780 from 9rnsr/fix7641
105a51f Merge pull request #784 from 9rnsr/fix7110
8b5b67f Merge pull request #792 from donc/bug7667
f72f237 fix Issue 3682 - Regression(2.038) is expression fails to match types
436b711 Fix issue 7667. ICE(interpret.c): 'ctfeStack.stackPointer() == 0'
9005276 Merge pull request #679 from yebblies/issue783
350a3ce Merge pull request #582 from 9rnsr/fix3382_ufcs
5f020c3 Merge pull request #788 from braddr/cleanup-backend3
6aa91cf Merge pull request #790 from p0nce/master
351d595 remove tls bracketing
a137d72 Fix bug #6391
6ce219c remove some of the bracketing
aec4c13 fix Issue 7578 - ICE on indexing result of vararg opDispatch
95e3dc1 Fix unintended infinite loop in Phobos build
b66196a fix Issue 3382 - [tdpl] Implement uniform function call syntax
ee2fe6c Fix 977 is with counting end-of-lines towards msot advanced lexer peeking
7790b16 fix Issue 7650 - Bad lambda inference in associative array literal
c03484e fix Issue 7649 - Bad lambda inference in default function argument
f293a10 fix Issue 7499 - [ICE] ('cast.c line 1495) with lambda array
9f0622c Expression::inferType() and remove FuncExp::setType()
cfc67b7 refactor lambda inference process
6d49586 more de-TX86'ing in relation to a bunch of OP codes
2efbf6a TX86-ectomy in evalu8.c
953f6d7 rip TX86 conditionals out of el.c
d5663c7 fix Issue 7595 - Data being overwritten.
449c165 Add predefined Ddoc macro SRCFILENAME
5c5da66 fix uninitialized field
29cde54 Merge pull request #783 from 9rnsr/fix7038
06d65ab fix Issue 7038 - Type mismatch with const struct
b77e2c9 fix Issue 7110 - opSlice() & opIndex functions works unstable as template arguments
a65f02f Merge pull request #781 from braddr/fix
08d6cd5 Merge pull request #782 from braddr/fixiasm
2492332 fix latent bug with Lexer::peek and recently introduced bug in Lexer::scan
ec1888e initialize popndTmp rather than rely on carefulness when usNumops == 0 and emitting a vector instruction, popndTmp is left uninitialized and is later dereferenced.
1d4a742 Merge pull request #766 from 9rnsr/fix7563
e1cd535 refactor
90f8dcf fix Issue 7641 - std.typecons.Proxy incorrectly allows implicit conversion to class
83a93cf Merge pull request #778 from dawgfoto/MoreSpellCorrection
7f0bcde 2nd go at fix issue 5590
567d7df fix Issue 5590 - Regression(2.036) ICE(e2ir.c): when using .values on enum which is associative array
48ea951 fix Issue 4820 - Regression(1.058, 2.044) in DStress caused by changeset 452
e8f9f3b more spell correction
afd9a45 fix Issue 7618 - delegate/function pointer call bypass parameter storage class
dabcdfb Merge pull request #773 from 9rnsr/fix7583
9846bb2 Merge pull request #774 from donc/ctfe7568
8c20445 Merge pull request #775 from donc/_error6785
d41e58e Avoiding shallow copy is more better.
cccef09 Revert "fix Issue 7585 - functions in templates inferred as delegate"
fc8dfc0 6785 Wrong error message from pragma(msg) of failed instantiation
61ec04d 7568 pragma(msg) segfaults with an aggregate including a class.
4d86d39 Merge pull request #767 from 9rnsr/fix7585
207d351 fix Issue 7583 - [CTFE] ICE with tuple and alias this
53bafa2 fix Issue 7411 - Deduce base type from vector types in templates
5ab1bd9 fix Issue 7518 - std.array.empty doesn't work for shared arrays
a1030d3 fix Issue 7554 - Immutable function pointer arguments too
5e96900 Merge pull request #771 from donc/bug7589
2287ebc fix Issue 7547 - -deps output lists object as a top level module
e611781 7589 __traits(compiles) does not work with a template that fails to compile
0113cde fix Issue 7585 - functions in templates inferred as delegate
4b978d5 fix Issue 7563 - Class members with default template arguments have no type
4d68981 fix Issue 7500 - [ICE] (template.c line 5287) with immutable lambda function
1a39c3c missed a line
6dd89ca Merge pull request #765 from 9rnsr/fix7525
8d6dcac fix Issue 7502 - 2.056 regression: Assigning .init takes forever to compile for large structs
042096e fix Issue 7525 - Broken return type inference for delegate returns
c5affa5 fix Issue 7582 - Untyped nested delegate literals don't compile
121677c fix Issue 7580 - Identity assignment of Nullable crashes dmd
adc0502 Small refactoring to resolve alias this.
1f52383 Merge pull request #671 from yebblies/issue4958
2a12345 fix build breakage
8755819 fix build
ba86204 fix vcbuild
464c664 fix linux build
31197c8 tweaked command line moved some inline asm to C-function to not interfere with optimizations build with VS2011
4dcdc9c increase stack size for win64 build
77262aa add missing include to root
56afe3f batch to build through win32.mak
5a0fd30 build through win32.mak
a5b5190 long_double -> longdouble remove C99 printf add Win64 support
9640110 vcbuild
b619171 Merge pull request #761 from donc/ctfe7473structref
7756328 Merge pull request #725 from kennytm/bug7399-import-too-fatal
bbac9e4 Merge pull request #759 from yebblies/issue1149
d1ff23b 7473 [CTFE] Non-ref argument behaves as if it's a ref argument
ab5cb18 Fix OPmsw codegen - integer only is too restrictive.
a00833b Merge pull request #743 from yebblies/issue3354
b006e11 Merge pull request #757 from 9rnsr/fix7562
3bccbb0 fix Issue 7562 - DMD crashes by using TemplateThisParameter
a7dc50e Merge pull request #749 from yebblies/issue1149
a873c5f Merge pull request #758 from 9rnsr/fix5525
5d639ec fix Issue 5525 - Eponymous templates should allow for overloaded eponymous members
f50852c Merge pull request #729 from donc/gag4269
de02523 fix Issue 3927 - array.length++; is an error, but ++array.length compiles
1dc5bfd Merge pull request #680 from yebblies/issue3812
cf887ba move errors to Dsymbol
fc4acf5 Merge pull request #755 from donc/seaOfErrors7557
be2f3a9 7557b soldier on through dottemplate expressions
8cec825 7557 Sea of errors after template failure
37ec6d6 A small fixup to call Type::defaultInitLiteral
7b5e2cb Revert "Revert "Merge pull request #41 from 9rnsr/rvalue-struct-literal""
3d8f09a Merge branch 'master' of github.com:D-Programming-Language/dmd
7dfb4cc Merge pull request #752 from braddr/cleanup-backend2
1b28f51 Merge branch 'master' of github.com:D-Programming-Language/dmd
31ad73c Merge pull request #746 from yebblies/issue5554
25f770d Change lexer to support # as a token, preserving #line's original behavior
dd8d20a Revert "Merge pull request #41 from 9rnsr/rvalue-struct-literal"
ee2fdf9 Merge pull request #41 from 9rnsr/rvalue-struct-literal
f94fdbf Merge pull request #750 from yebblies/issue3630
61f5fcf Improve codegen for OPmsw
05a3fa4 Merge pull request #744 from Safety0ff/avx-fix
0231d6a Merge pull request #748 from 9rnsr/fix7552
9a97979 Merge pull request #751 from donc/ctfe7536
e091e6e 7536 ctfeAdrOnStack triggered
c9edaf4 fix Issue 7552 - Cannot get and combine a part of overloaded functions
1edeba9 Fix Issue 3630 - bad error location in "has no effect in expression" error
7d0fb72 Fix Issue 5554 - [qtd] Covariance detection failure
4f36aca fix Issue 7550 - Missing AVX instruction VPMULDQ
0b82dfe Fix Issue 5879 - Not all frontend errors use stderr
963a41a Merge pull request #695 from yebblies/refactor_expression
3f06690 Fix Issue 3354 - asm fld x, ST(6); accepted
713f69f Merge pull request #677 from yebblies/issue4241
cf22ce3 Merge pull request #711 from yebblies/issue3559
56ca73c Merge pull request #700 from kennytm/bug7452_lazy_safe
c4dc723 Merge pull request #736 from ibuclaw/in_gcc
121c9b9 Merge pull request #737 from yebblies/issue7544
cedcb3c Merge pull request #740 from yebblies/issue7545
fb3e8f2 Merge pull request #741 from dawgfoto/DMCWarning
5d26c1e Merge pull request #735 from 9rnsr/fix7105
734a921 dmc warning
1e1cfbc Fix Issue 7545 - ICE(cast.c) Merge integral types through alias this
6b135be Fix Issue 7544 - ICE(interpret.c) Catching an exception with a null catch block
c5336f9 Update already existing gdc-specific code, harmonise headers.
44b8d59 Merge pull request #703 from kennytm/bug435_template_ctor
6b368e1 Merge pull request #707 from yebblies/issue3822
8439e07 Merge pull request #717 from yebblies/issue6611
2b4502e fix Issue 7105 - relax inout rules
ac4463a wildsubparam isn't need anymore, because it works properly.
f77879a Issue 6611 - better error message for array post increment/decrement
7393395 Merge pull request #716 from yebblies/issue6685
77568f0 Merge pull request #719 from yebblies/issue4536
9accb04 tired of tdata()
5fbd5a2 Merge pull request #732 from dawgfoto/fix5412
41a901a Revert "hide private/package module level symbols"
23d5e14 Merge pull request #733 from dawgfoto/HideModuleMembers
e2f8a23 hide private/package module level symbols
ae75287 detect collisions with renamed imports
75a2442 fix Dsymbol::search_correct
50e122a Merge pull request #723 from kennytm/bug7504_null_array
c5b7601 Revert "fix 7494 - selective imports in function scope"
aa6f4d9 Revert "fix Protection"
5be660e Revert "fix Imports"
040371b Revert "detect collisions with renamed imports"
0159818 Revert "find private symbols during spell correction"
0c95c45 find private symbols during spell correction
ca22fb2 detect collisions with renamed imports
0dca0af fix Imports
37d4fda fix Protection
16a2e7e fix 7494 - selective imports in function scope
c16f5b2 Merge pull request #667 from 9rnsr/fix7406
f776617 explanatory comments belong in the code, not bugzilla
bfa2060 Merge pull request #704 from donc/_error6699
f46705c fix fail222 regression
28d9635 Merge pull request #708 from donc/soldieron7481
2c2a7af Merge pull request #715 from 9rnsr/fix6738
98cfa64 Merge pull request #722 from 9rnsr/fix7353
b040567 revert pull 724
0e84f63 revert part of pull 724
400f702 Merge pull request #724 from yebblies/issue3632
d82cc74 Merge pull request #720 from yebblies/issue3279
2da3bed Merge pull request #718 from yebblies/fixdebugmsg
f6627ec 7527 [CTFE] Segfault when slicing a pointer at compile time
c8f09bf 4269a Regression(2.031): invalid type accepted if evaluated while errors are gagged
d10fba0 implement const/purity/nothrow/@safe inheritance
ad689fb Fix bug 7399: Broken import statement in trySemantic() causes silent compiler error
eb0c643 Add global.speculativeGag
c18220a Refactor isSpeculativeFunction into Dsymbol
f5c56d8 Issue 3632 - modify float is float to do a bitwise compare
af1cab4 Issue 7353 - NRVO not properly working with inferred return type
03ee438 Fix bug 7504: Cannot assign an object of type 'typeof(null)' to an array
dfb941c Remove debug printing in code that generates errors.
62118e3 Issue 4536 - Typetuples (T...) should have an .init member
989da7b Issue 3279 - Confusing error message when comparing types
36e8045 Issue 6685 - Allow using "with" with rvalues
60cbc6f fix issue 6738 revisited
4e20e7d Issue 3822 - Invalid optimization of alloca called with constant size
b37bf8c Fixes bug 435: Constructors should be templatized
ad8157d Issue 3559 - DMD 1.048+ fails to take function pointer from overloaded member functions
838cd06 7481 Compiler should 'soldier on' after template errors
673063e Simplify fix for 6699
1a0b199 6699a __error when instantiating function template
b6d072d 6699b __error in alias expression
df16ffa 6699c __error in synchronized error message
338f804 7462 Error message with _error_ in overridden function
0f60bd3 7463 Duplicated error message with bad template value parameter
f43e93a 6699E: _error inside error msg for bad base class
5109a5a Fixes bug 7452.
04d888f Refactor XxxAssignExp semantic
73973d6 Issue 3812 - Missing line number for implicit cast of variadic function to array
f0bbf18 Issue 3927 - array.length++; is an error, but ++array.length compiles
24576c2 Issue 783 - Cannot use an array w/ const or variable index as new[] size argument.
7e4cd4b Issue 4241 - duplicate union initialization error doesn't give a file location
9987127 Issue 4958 - Floating point enums should check for total loss of precision
60287fd Issue 7406 - tuple foreach doesn't work with mixed tuples
633d88e Issue 5889 - Struct literal/construction should be rvalue
5d5f78a Now function overloading with ref and non-ref parameter is legal for struct type

git-subtree-dir: dmd2
git-subtree-split: 3443f38fc4c17807a0f36005a05d598cfc7301db
2012-04-05 11:45:25 +04:00

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// Compiler implementation of the D programming language
// Copyright (c) 1999-2011 by Digital Mars
// All Rights Reserved
// written by Walter Bright
// http://www.digitalmars.com
// License for redistribution is by either the Artistic License
// in artistic.txt, or the GNU General Public License in gnu.txt.
// See the included readme.txt for details.
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include "rmem.h"
#include "statement.h"
#include "expression.h"
#include "cond.h"
#include "init.h"
#include "staticassert.h"
#include "mtype.h"
#include "scope.h"
#include "declaration.h"
#include "aggregate.h"
#include "id.h"
#include "utf.h"
#include "attrib.h" // for AttribDeclaration
#include "template.h"
#define LOG 0
#define LOGASSIGN 0
#define SHOWPERFORMANCE 0
// Maximum allowable recursive function calls in CTFE
#define CTFE_RECURSION_LIMIT 1000
// The values of all CTFE variables.
struct CtfeStack
{
private:
/* The stack. Every declaration we encounter is pushed here,
together with the VarDeclaration, and the previous
stack address of that variable, so that we can restore it
when we leave the stack frame.
Note that when a function is forward referenced, the interpreter must
run semantic3, and that may start CTFE again with a NULL istate. Thus
the stack might not be empty when CTFE begins.
Ctfe Stack addresses are just 0-based integers, but we save
them as 'void *' because ArrayBase can only do pointers.
*/
Expressions values; // values on the stack
VarDeclarations vars; // corresponding variables
ArrayBase<void> savedId; // id of the previous state of that var
/* Global constants get saved here after evaluation, so we never
* have to redo them. This saves a lot of time and memory.
*/
Expressions globalValues; // values of global constants
size_t framepointer; // current frame pointer
size_t maxStackPointer; // most stack we've ever used
public:
CtfeStack() : framepointer(0)
{
}
size_t stackPointer()
{
return values.dim;
}
// Largest number of stack positions we've used
size_t maxStackUsage()
{
return maxStackPointer;
}
// return the previous frame
size_t startFrame()
{
size_t oldframe = framepointer;
framepointer = stackPointer();
return oldframe;
}
void endFrame(size_t oldframe)
{
popAll(framepointer);
framepointer = oldframe;
}
Expression *getValue(VarDeclaration *v)
{
if (v->isDataseg() && !v->isCTFE())
{
assert(v->ctfeAdrOnStack >= 0 &&
v->ctfeAdrOnStack < globalValues.dim);
return globalValues.tdata()[v->ctfeAdrOnStack];
}
assert(v->ctfeAdrOnStack >= 0 && v->ctfeAdrOnStack < stackPointer());
return values.tdata()[v->ctfeAdrOnStack];
}
void setValue(VarDeclaration *v, Expression *e)
{
assert(!v->isDataseg() || v->isCTFE());
assert(v->ctfeAdrOnStack >= 0 && v->ctfeAdrOnStack < stackPointer());
values.tdata()[v->ctfeAdrOnStack] = e;
}
void push(VarDeclaration *v)
{
assert(!v->isDataseg() || v->isCTFE());
if (v->ctfeAdrOnStack!= (size_t)-1
&& v->ctfeAdrOnStack >= framepointer)
{ // Already exists in this frame, reuse it.
values.tdata()[v->ctfeAdrOnStack] = NULL;
return;
}
savedId.push((void *)(v->ctfeAdrOnStack));
v->ctfeAdrOnStack = values.dim;
vars.push(v);
values.push(NULL);
}
void pop(VarDeclaration *v)
{
assert(!v->isDataseg() || v->isCTFE());
assert(!(v->storage_class & (STCref | STCout)));
int oldid = v->ctfeAdrOnStack;
v->ctfeAdrOnStack = (size_t)(savedId.tdata()[oldid]);
if (v->ctfeAdrOnStack == values.dim - 1)
{
values.pop();
vars.pop();
savedId.pop();
}
}
void popAll(size_t stackpointer)
{
if (stackPointer() > maxStackPointer)
maxStackPointer = stackPointer();
assert(values.dim >= stackpointer && stackpointer >= 0);
for (size_t i = stackpointer; i < values.dim; ++i)
{
VarDeclaration *v = vars.tdata()[i];
v->ctfeAdrOnStack = (size_t)(savedId.tdata()[i]);
}
values.setDim(stackpointer);
vars.setDim(stackpointer);
savedId.setDim(stackpointer);
}
void saveGlobalConstant(VarDeclaration *v, Expression *e)
{
#if DMDV2
assert( v->init && (v->isConst() || v->isImmutable()) && !v->isCTFE());
#else
assert( v->init && v->isConst() && !v->isCTFE());
#endif
v->ctfeAdrOnStack = globalValues.dim;
globalValues.push(e);
}
};
CtfeStack ctfeStack;
struct InterState
{
InterState *caller; // calling function's InterState
FuncDeclaration *fd; // function being interpreted
size_t framepointer; // frame pointer of previous frame
Statement *start; // if !=NULL, start execution at this statement
Statement *gotoTarget; /* target of EXP_GOTO_INTERPRET result; also
* target of labelled EXP_BREAK_INTERPRET or
* EXP_CONTINUE_INTERPRET. (NULL if no label).
*/
Expression *localThis; // value of 'this', or NULL if none
bool awaitingLvalueReturn; // Support for ref return values:
// Any return to this function should return an lvalue.
InterState();
};
InterState::InterState()
{
memset(this, 0, sizeof(InterState));
}
// Global status of the CTFE engine
struct CtfeStatus
{
static int callDepth; // current number of recursive calls
static int stackTraceCallsToSuppress; /* When printing a stack trace,
* suppress this number of calls
*/
static int maxCallDepth; // highest number of recursive calls
static int numArrayAllocs; // Number of allocated arrays
static int numAssignments; // total number of assignments executed
};
int CtfeStatus::callDepth = 0;
int CtfeStatus::stackTraceCallsToSuppress = 0;
int CtfeStatus::maxCallDepth = 0;
int CtfeStatus::numArrayAllocs = 0;
int CtfeStatus::numAssignments = 0;
// CTFE diagnostic information
void printCtfePerformanceStats()
{
#if SHOWPERFORMANCE
printf(" ---- CTFE Performance ----\n");
printf("max call depth = %d\tmax stack = %d\n", CtfeStatus::maxCallDepth, ctfeStack.maxStackUsage());
printf("array allocs = %d\tassignments = %d\n\n", CtfeStatus::numArrayAllocs, CtfeStatus::numAssignments);
#endif
}
Expression * resolveReferences(Expression *e, Expression *thisval);
Expression *getVarExp(Loc loc, InterState *istate, Declaration *d, CtfeGoal goal);
VarDeclaration *findParentVar(Expression *e, Expression *thisval);
bool needToCopyLiteral(Expression *expr);
Expression *copyLiteral(Expression *e);
Expression *paintTypeOntoLiteral(Type *type, Expression *lit);
Expression *findKeyInAA(Loc loc, AssocArrayLiteralExp *ae, Expression *e2);
Expression *evaluateIfBuiltin(InterState *istate, Loc loc,
FuncDeclaration *fd, Expressions *arguments, Expression *pthis);
Expression *scrubReturnValue(Loc loc, Expression *e);
bool isAssocArray(Type *t);
bool isPointer(Type *t);
// CTFE only expressions
#define TOKclassreference ((TOK)(TOKMAX+1))
#define TOKthrownexception ((TOK)(TOKMAX+2))
// Reference to a class, or an interface. We need this when we
// point to a base class (we must record what the type is).
struct ClassReferenceExp : Expression
{
StructLiteralExp *value;
ClassReferenceExp(Loc loc, StructLiteralExp *lit, Type *type) : Expression(loc, TOKclassreference, sizeof(ClassReferenceExp))
{
assert(lit && lit->sd && lit->sd->isClassDeclaration());
this->value = lit;
this->type = type;
}
Expression *interpret(InterState *istate, CtfeGoal goal = ctfeNeedRvalue)
{
//printf("ClassReferenceExp::interpret() %s\n", value->toChars());
return this;
}
char *toChars()
{
return value->toChars();
}
ClassDeclaration *originalClass()
{
return value->sd->isClassDeclaration();
}
VarDeclaration *getFieldAt(int index)
{
ClassDeclaration *cd = originalClass();
size_t fieldsSoFar = 0;
while (index - fieldsSoFar >= cd->fields.dim)
{ fieldsSoFar += cd->fields.dim;
cd = cd->baseClass;
}
return cd->fields.tdata()[index - fieldsSoFar];
}
// Return index of the field, or -1 if not found
int getFieldIndex(Type *fieldtype, size_t fieldoffset)
{
ClassDeclaration *cd = originalClass();
size_t fieldsSoFar = 0;
for (size_t j = 0; j < value->elements->dim; j++)
{ while (j - fieldsSoFar >= cd->fields.dim)
{ fieldsSoFar += cd->fields.dim;
cd = cd->baseClass;
}
Dsymbol *s = cd->fields.tdata()[j - fieldsSoFar];
VarDeclaration *v2 = s->isVarDeclaration();
if (fieldoffset == v2->offset &&
fieldtype->size() == v2->type->size())
{ return value->elements->dim - fieldsSoFar - cd->fields.dim + (j-fieldsSoFar);
}
}
return -1;
}
// Return index of the field, or -1 if not found
// Same as getFieldIndex, but checks for a direct match with the VarDeclaration
int findFieldIndexByName(VarDeclaration *v)
{
ClassDeclaration *cd = originalClass();
size_t fieldsSoFar = 0;
for (size_t j = 0; j < value->elements->dim; j++)
{ while (j - fieldsSoFar >= cd->fields.dim)
{ fieldsSoFar += cd->fields.dim;
cd = cd->baseClass;
}
Dsymbol *s = cd->fields.tdata()[j - fieldsSoFar];
VarDeclaration *v2 = s->isVarDeclaration();
if (v == v2)
{ return value->elements->dim - fieldsSoFar - cd->fields.dim + (j-fieldsSoFar);
}
}
return -1;
}
};
struct VoidInitExp : Expression
{
VarDeclaration *var;
VoidInitExp(VarDeclaration *var, Type *type)
: Expression(var->loc, TOKvoid, sizeof(VoidInitExp))
{
this->var = var;
this->type = var->type;
}
char *toChars()
{
return (char *)"void";
}
Expression *interpret(InterState *istate, CtfeGoal goal = ctfeNeedRvalue)
{
error("CTFE internal error: trying to read uninitialized variable");
assert(0);
return EXP_CANT_INTERPRET;
}
};
// Return index of the field, or -1 if not found
// Same as getFieldIndex, but checks for a direct match with the VarDeclaration
int findFieldIndexByName(StructDeclaration *sd, VarDeclaration *v)
{
for (int i = 0; i < sd->fields.dim; ++i)
{
if (sd->fields.tdata()[i] == v)
return i;
}
return -1;
}
// Fake class which holds the thrown exception. Used for implementing exception handling.
struct ThrownExceptionExp : Expression
{
ClassReferenceExp *thrown; // the thing being tossed
ThrownExceptionExp(Loc loc, ClassReferenceExp *victim) : Expression(loc, TOKthrownexception, sizeof(ThrownExceptionExp))
{
this->thrown = victim;
this->type = type;
}
Expression *interpret(InterState *istate, CtfeGoal goal = ctfeNeedRvalue)
{
assert(0); // This should never be interpreted
return this;
}
char *toChars()
{
return (char *)"CTFE ThrownException";
}
// Generate an error message when this exception is not caught
void generateUncaughtError()
{
thrown->error("Uncaught CTFE exception %s(%s)", thrown->type->toChars(),
thrown->value->elements->tdata()[0]->toChars());
/* Also give the line where the throw statement was. We won't have it
* in the case where the ThrowStatement is generated internally
* (eg, in ScopeStatement)
*/
if (loc.filename && !loc.equals(thrown->loc))
errorSupplemental(loc, "thrown from here");
}
};
// True if 'e' is EXP_CANT_INTERPRET, or an exception
bool exceptionOrCantInterpret(Expression *e)
{
if (e == EXP_CANT_INTERPRET) return true;
if (!e || e == EXP_GOTO_INTERPRET || e == EXP_VOID_INTERPRET
|| e == EXP_BREAK_INTERPRET || e == EXP_CONTINUE_INTERPRET)
return false;
return e->op == TOKthrownexception;
}
// Used for debugging only
void showCtfeExpr(Expression *e, int level = 0)
{
for (int i = level; i>0; --i) printf(" ");
Expressions *elements = NULL;
// We need the struct definition to detect block assignment
StructDeclaration *sd = NULL;
ClassDeclaration *cd = NULL;
if (e->op == TOKstructliteral)
{ elements = ((StructLiteralExp *)e)->elements;
sd = ((StructLiteralExp *)e)->sd;
printf("STRUCT type = %s %p:\n", e->type->toChars(),
e);
}
else if (e->op == TOKclassreference)
{ elements = ((ClassReferenceExp *)e)->value->elements;
cd = ((ClassReferenceExp *)e)->originalClass();
printf("CLASS type = %s %p:\n", e->type->toChars(),
((ClassReferenceExp *)e)->value);
}
else if (e->op == TOKarrayliteral)
{
elements = ((ArrayLiteralExp *)e)->elements;
printf("ARRAY LITERAL type=%s %p:\n", e->type->toChars(),
e);
}
else if (e->op == TOKassocarrayliteral)
{
printf("AA LITERAL type=%s %p:\n", e->type->toChars(),
e);
}
else if (e->op == TOKstring)
{
printf("STRING %s %p\n", e->toChars(),
((StringExp *)e)->string);
}
else if (e->op == TOKslice)
{
printf("SLICE %p: %s\n", e, e->toChars());
showCtfeExpr(((SliceExp *)e)->e1, level + 1);
}
else if (e->op == TOKvar)
{
printf("VAR %p %s\n", e, e->toChars());
VarDeclaration *v = ((VarExp *)e)->var->isVarDeclaration();
if (v && v->getValue())
showCtfeExpr(v->getValue(), level + 1);
}
else if (isPointer(e->type))
{
// This is potentially recursive. We mustn't try to print the thing we're pointing to.
if (e->op == TOKindex)
printf("POINTER %p into %p [%s]\n", e, ((IndexExp *)e)->e1, ((IndexExp *)e)->e2->toChars());
else if (e->op == TOKdotvar)
printf("POINTER %p to %p .%s\n", e, ((DotVarExp *)e)->e1, ((DotVarExp *)e)->var->toChars());
else
printf("POINTER %p: %s\n", e, e->toChars());
}
else
printf("VALUE %p: %s\n", e, e->toChars());
if (elements)
{
size_t fieldsSoFar = 0;
for (size_t i = 0; i < elements->dim; i++)
{ Expression *z = NULL;
Dsymbol *s = NULL;
if (i > 15) {
printf("...(total %d elements)\n", elements->dim);
return;
}
if (sd)
{ s = sd->fields.tdata()[i];
z = elements->tdata()[i];
}
else if (cd)
{ while (i - fieldsSoFar >= cd->fields.dim)
{ fieldsSoFar += cd->fields.dim;
cd = cd->baseClass;
for (int j = level; j>0; --j) printf(" ");
printf(" BASE CLASS: %s\n", cd->toChars());
}
s = cd->fields.tdata()[i - fieldsSoFar];
size_t indx = (elements->dim - fieldsSoFar)- cd->fields.dim + i;
assert(indx >= 0);
assert(indx < elements->dim);
z = elements->tdata()[indx];
}
if (!z) {
for (int j = level; j>0; --j) printf(" ");
printf(" void\n");
continue;
}
if (s)
{
VarDeclaration *v = s->isVarDeclaration();
assert(v);
// If it is a void assignment, use the default initializer
if ((v->type->ty != z->type->ty) && v->type->ty == Tsarray)
{
for (int j = level; --j;) printf(" ");
printf(" field: block initalized static array\n");
continue;
}
}
showCtfeExpr(z, level + 1);
}
}
}
/*************************************
* Attempt to interpret a function given the arguments.
* Input:
* istate state for calling function (NULL if none)
* arguments function arguments
* thisarg 'this', if a needThis() function, NULL if not.
*
* Return result expression if successful, EXP_CANT_INTERPRET if not,
* or EXP_VOID_INTERPRET if function returned void.
*/
Expression *FuncDeclaration::interpret(InterState *istate, Expressions *arguments, Expression *thisarg)
{
#if LOG
printf("\n********\nFuncDeclaration::interpret(istate = %p) %s\n", istate, toChars());
#endif
if (semanticRun == PASSsemantic3)
return EXP_CANT_INTERPRET;
if (semanticRun < PASSsemantic3 && scope)
{
/* Forward reference - we need to run semantic3 on this function.
* If errors are gagged, and it's not part of a speculative
* template instance, we need to temporarily ungag errors.
*/
int olderrors = global.errors;
int oldgag = global.gag;
TemplateInstance *spec = isSpeculative();
if (global.gag && !spec)
global.gag = 0;
semantic3(scope);
global.gag = oldgag; // regag errors
// If it is a speculatively-instantiated template, and errors occur,
// we need to mark the template as having errors.
if (spec && global.errors != olderrors)
spec->errors = global.errors - olderrors;
if (olderrors != global.errors) // if errors compiling this function
return EXP_CANT_INTERPRET;
}
if (semanticRun < PASSsemantic3done)
return EXP_CANT_INTERPRET;
Type *tb = type->toBasetype();
assert(tb->ty == Tfunction);
TypeFunction *tf = (TypeFunction *)tb;
Type *tret = tf->next->toBasetype();
if (tf->varargs && arguments &&
((parameters && arguments->dim != parameters->dim) || (!parameters && arguments->dim)))
{
error("C-style variadic functions are not yet implemented in CTFE");
return EXP_CANT_INTERPRET;
}
// Nested functions always inherit the 'this' pointer from the parent,
// except for delegates. (Note that the 'this' pointer may be null).
// Func literals report isNested() even if they are in global scope,
// so we need to check that the parent is a function.
if (isNested() && toParent2()->isFuncDeclaration() && !thisarg && istate)
thisarg = istate->localThis;
InterState istatex;
istatex.caller = istate;
istatex.fd = this;
istatex.localThis = thisarg;
istatex.framepointer = ctfeStack.startFrame();
Expressions vsave; // place to save previous parameter values
size_t dim = 0;
if (needThis() && !thisarg)
{ // error, no this. Prevent segfault.
error("need 'this' to access member %s", toChars());
return EXP_CANT_INTERPRET;
}
if (thisarg && !istate)
{ // Check that 'this' aleady has a value
if (thisarg->interpret(istate) == EXP_CANT_INTERPRET)
return EXP_CANT_INTERPRET;
}
static int evaluatingArgs = 0;
if (arguments)
{
dim = arguments->dim;
assert(!dim || (parameters && (parameters->dim == dim)));
vsave.setDim(dim);
/* Evaluate all the arguments to the function,
* store the results in eargs[]
*/
Expressions eargs;
eargs.setDim(dim);
for (size_t i = 0; i < dim; i++)
{ Expression *earg = arguments->tdata()[i];
Parameter *arg = Parameter::getNth(tf->parameters, i);
if (arg->storageClass & (STCout | STCref))
{
if (!istate && (arg->storageClass & STCout))
{ // initializing an out parameter involves writing to it.
earg->error("global %s cannot be passed as an 'out' parameter at compile time", earg->toChars());
return EXP_CANT_INTERPRET;
}
// Convert all reference arguments into lvalue references
++evaluatingArgs;
earg = earg->interpret(istate, ctfeNeedLvalueRef);
--evaluatingArgs;
if (earg == EXP_CANT_INTERPRET)
return earg;
}
else if (arg->storageClass & STClazy)
{
}
else
{ /* Value parameters
*/
Type *ta = arg->type->toBasetype();
if (ta->ty == Tsarray && earg->op == TOKaddress)
{
/* Static arrays are passed by a simple pointer.
* Skip past this to get at the actual arg.
*/
earg = ((AddrExp *)earg)->e1;
}
++evaluatingArgs;
earg = earg->interpret(istate);
--evaluatingArgs;
if (earg == EXP_CANT_INTERPRET)
return earg;
/* Struct literals are passed by value, but we don't need to
* copy them if they are passed as const
*/
if (earg->op == TOKstructliteral
#if DMDV2
&& !(arg->storageClass & (STCconst | STCimmutable))
#endif
)
earg = copyLiteral(earg);
}
if (earg->op == TOKthrownexception)
{
if (istate)
return earg;
((ThrownExceptionExp *)earg)->generateUncaughtError();
return EXP_CANT_INTERPRET;
}
eargs.tdata()[i] = earg;
}
for (size_t i = 0; i < dim; i++)
{ Expression *earg = eargs.tdata()[i];
Parameter *arg = Parameter::getNth(tf->parameters, i);
VarDeclaration *v = parameters->tdata()[i];
#if LOG
printf("arg[%d] = %s\n", i, earg->toChars());
#endif
if (arg->storageClass & (STCout | STCref) && earg->op == TOKvar)
{
VarExp *ve = (VarExp *)earg;
VarDeclaration *v2 = ve->var->isVarDeclaration();
if (!v2)
{
error("cannot interpret %s as a ref parameter", ve->toChars());
return EXP_CANT_INTERPRET;
}
/* The push() isn't a variable we'll use, it's just a place
* to save the old value of v.
* Note that v might be v2! So we need to save v2's index
* before pushing.
*/
size_t oldadr = v2->ctfeAdrOnStack;
ctfeStack.push(v);
v->ctfeAdrOnStack = oldadr;
assert(v2->hasValue());
}
else
{ // Value parameters and non-trivial references
ctfeStack.push(v);
v->setValueWithoutChecking(earg);
}
#if LOG || LOGASSIGN
printf("interpreted arg[%d] = %s\n", i, earg->toChars());
showCtfeExpr(earg);
#endif
}
}
if (vresult)
ctfeStack.push(vresult);
// Enter the function
++CtfeStatus::callDepth;
if (CtfeStatus::callDepth > CtfeStatus::maxCallDepth)
CtfeStatus::maxCallDepth = CtfeStatus::callDepth;
Expression *e = NULL;
while (1)
{
if (CtfeStatus::callDepth > CTFE_RECURSION_LIMIT)
{ // This is a compiler error. It must not be suppressed.
global.gag = 0;
error("CTFE recursion limit exceeded");
e = EXP_CANT_INTERPRET;
break;
}
e = fbody->interpret(&istatex);
if (e == EXP_CANT_INTERPRET)
{
#if LOG
printf("function body failed to interpret\n");
#endif
}
/* This is how we deal with a recursive statement AST
* that has arbitrary goto statements in it.
* Bubble up a 'result' which is the target of the goto
* statement, then go recursively down the AST looking
* for that statement, then execute starting there.
*/
if (e == EXP_GOTO_INTERPRET)
{
istatex.start = istatex.gotoTarget; // set starting statement
istatex.gotoTarget = NULL;
}
else
break;
}
assert(e != EXP_CONTINUE_INTERPRET && e != EXP_BREAK_INTERPRET);
// Leave the function
--CtfeStatus::callDepth;
ctfeStack.endFrame(istatex.framepointer);
// If fell off the end of a void function, return void
if (!e && type->toBasetype()->nextOf()->ty == Tvoid)
return EXP_VOID_INTERPRET;
// If result is void, return void
if (e == EXP_VOID_INTERPRET)
return e;
// If it generated an exception, return it
if (exceptionOrCantInterpret(e))
{
if (istate || e == EXP_CANT_INTERPRET)
return e;
((ThrownExceptionExp *)e)->generateUncaughtError();
return EXP_CANT_INTERPRET;
}
// If we're about to leave CTFE, make sure we don't crash the
// compiler by returning a CTFE-internal expression.
if (!istate && !evaluatingArgs)
{
e = scrubReturnValue(loc, e);
}
return e;
}
/******************************** Statement ***************************/
#define START() \
if (istate->start) \
{ if (istate->start != this) \
return NULL; \
istate->start = NULL; \
}
/***********************************
* Interpret the statement.
* Returns:
* NULL continue to next statement
* EXP_CANT_INTERPRET cannot interpret statement at compile time
* !NULL expression from return statement, or thrown exception
*/
Expression *Statement::interpret(InterState *istate)
{
#if LOG
printf("Statement::interpret()\n");
#endif
START()
error("Statement %s cannot be interpreted at compile time", this->toChars());
return EXP_CANT_INTERPRET;
}
Expression *ExpStatement::interpret(InterState *istate)
{
#if LOG
printf("ExpStatement::interpret(%s)\n", exp ? exp->toChars() : "");
#endif
START()
if (exp)
{
Expression *e = exp->interpret(istate, ctfeNeedNothing);
if (e == EXP_CANT_INTERPRET)
{
//printf("-ExpStatement::interpret(): %p\n", e);
return EXP_CANT_INTERPRET;
}
if (e && e!= EXP_VOID_INTERPRET && e->op == TOKthrownexception)
return e;
}
return NULL;
}
Expression *CompoundStatement::interpret(InterState *istate)
{ Expression *e = NULL;
#if LOG
printf("CompoundStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
if (statements)
{
for (size_t i = 0; i < statements->dim; i++)
{ Statement *s = statements->tdata()[i];
if (s)
{
e = s->interpret(istate);
if (e)
break;
}
}
}
#if LOG
printf("-CompoundStatement::interpret() %p\n", e);
#endif
return e;
}
Expression *UnrolledLoopStatement::interpret(InterState *istate)
{ Expression *e = NULL;
#if LOG
printf("UnrolledLoopStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
if (statements)
{
for (size_t i = 0; i < statements->dim; i++)
{ Statement *s = statements->tdata()[i];
e = s->interpret(istate);
if (e == EXP_CANT_INTERPRET)
break;
if (e == EXP_CONTINUE_INTERPRET)
{
if (istate->gotoTarget && istate->gotoTarget != this)
break; // continue at higher level
istate->gotoTarget = NULL;
e = NULL;
continue;
}
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
e = NULL;
} // else break at a higher level
break;
}
if (e)
break;
}
}
return e;
}
// For CTFE only. Returns true if 'e' is TRUE or a non-null pointer.
int isTrueBool(Expression *e)
{
return e->isBool(TRUE) || ((e->type->ty == Tpointer || e->type->ty == Tclass)
&& e->op != TOKnull);
}
Expression *IfStatement::interpret(InterState *istate)
{
#if LOG
printf("IfStatement::interpret(%s)\n", condition->toChars());
#endif
if (istate->start == this)
istate->start = NULL;
if (istate->start)
{
Expression *e = NULL;
if (ifbody)
e = ifbody->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (istate->start && elsebody)
e = elsebody->interpret(istate);
return e;
}
Expression *e = condition->interpret(istate);
assert(e);
//if (e == EXP_CANT_INTERPRET) printf("cannot interpret\n");
if (e != EXP_CANT_INTERPRET && (e && e->op != TOKthrownexception))
{
if (isTrueBool(e))
e = ifbody ? ifbody->interpret(istate) : NULL;
else if (e->isBool(FALSE))
e = elsebody ? elsebody->interpret(istate) : NULL;
else
{
e = EXP_CANT_INTERPRET;
}
}
return e;
}
Expression *ScopeStatement::interpret(InterState *istate)
{
#if LOG
printf("ScopeStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
return statement ? statement->interpret(istate) : NULL;
}
Expression *resolveSlice(Expression *e)
{
if ( ((SliceExp *)e)->e1->op == TOKnull)
return ((SliceExp *)e)->e1;
return Slice(e->type, ((SliceExp *)e)->e1,
((SliceExp *)e)->lwr, ((SliceExp *)e)->upr);
}
/* Determine the array length, without interpreting it.
* e must be an array literal, or a slice
* It's very wasteful to resolve the slice when we only
* need the length.
*/
uinteger_t resolveArrayLength(Expression *e)
{
if (e->op == TOKnull)
return 0;
if (e->op == TOKslice)
{ uinteger_t ilo = ((SliceExp *)e)->lwr->toInteger();
uinteger_t iup = ((SliceExp *)e)->upr->toInteger();
return iup - ilo;
}
if (e->op == TOKstring)
{ return ((StringExp *)e)->len;
}
if (e->op == TOKarrayliteral)
{ ArrayLiteralExp *ale = (ArrayLiteralExp *)e;
return ale->elements ? ale->elements->dim : 0;
}
if (e->op == TOKassocarrayliteral)
{ AssocArrayLiteralExp *ale = (AssocArrayLiteralExp *)e;
return ale->keys->dim;
}
assert(0);
return 0;
}
// As Equal, but resolves slices before comparing
Expression *ctfeEqual(Loc loc, enum TOK op, Type *type, Expression *e1, Expression *e2)
{
if (e1->op == TOKslice)
e1 = resolveSlice(e1);
if (e2->op == TOKslice)
e2 = resolveSlice(e2);
Expression *e = Equal(op, type, e1, e2);
if (e == EXP_CANT_INTERPRET)
error(loc, "cannot evaluate %s==%s at compile time", e1->toChars(), e2->toChars());
return e;
}
Expression *ctfeCat(Type *type, Expression *e1, Expression *e2)
{
Loc loc = e1->loc;
Type *t1 = e1->type->toBasetype();
Type *t2 = e2->type->toBasetype();
Expression *e;
if (e2->op == TOKstring && e1->op == TOKarrayliteral &&
t1->nextOf()->isintegral())
{
// [chars] ~ string => string (only valid for CTFE)
StringExp *es1 = (StringExp *)e2;
ArrayLiteralExp *es2 = (ArrayLiteralExp *)e1;
size_t len = es1->len + es2->elements->dim;
int sz = es1->sz;
void *s = mem.malloc((len + 1) * sz);
memcpy((char *)s + sz * es2->elements->dim, es1->string, es1->len * sz);
for (size_t i = 0; i < es2->elements->dim; i++)
{ Expression *es2e = es2->elements->tdata()[i];
if (es2e->op != TOKint64)
return EXP_CANT_INTERPRET;
dinteger_t v = es2e->toInteger();
memcpy((unsigned char *)s + i * sz, &v, sz);
}
// Add terminating 0
memset((unsigned char *)s + len * sz, 0, sz);
StringExp *es = new StringExp(loc, s, len);
es->sz = sz;
es->committed = 0;
es->type = type;
e = es;
return e;
}
else if (e1->op == TOKstring && e2->op == TOKarrayliteral &&
t2->nextOf()->isintegral())
{
// string ~ [chars] => string (only valid for CTFE)
// Concatenate the strings
StringExp *es1 = (StringExp *)e1;
ArrayLiteralExp *es2 = (ArrayLiteralExp *)e2;
size_t len = es1->len + es2->elements->dim;
int sz = es1->sz;
void *s = mem.malloc((len + 1) * sz);
memcpy(s, es1->string, es1->len * sz);
for (size_t i = 0; i < es2->elements->dim; i++)
{ Expression *es2e = es2->elements->tdata()[i];
if (es2e->op != TOKint64)
return EXP_CANT_INTERPRET;
dinteger_t v = es2e->toInteger();
memcpy((unsigned char *)s + (es1->len + i) * sz, &v, sz);
}
// Add terminating 0
memset((unsigned char *)s + len * sz, 0, sz);
StringExp *es = new StringExp(loc, s, len);
es->sz = sz;
es->committed = 0; //es1->committed;
es->type = type;
e = es;
return e;
}
return Cat(type, e1, e2);
}
bool scrubArray(Loc loc, Expressions *elems, bool structlit = false);
/* All results destined for use outside of CTFE need to have their CTFE-specific
* features removed.
* In particular, all slices must be resolved.
*/
Expression *scrubReturnValue(Loc loc, Expression *e)
{
if (e->op == TOKclassreference)
{
error(loc, "%s class literals cannot be returned from CTFE", ((ClassReferenceExp*)e)->originalClass()->toChars());
return EXP_CANT_INTERPRET;
}
if (e->op == TOKvoid)
{
error(loc, "uninitialized variable '%s' cannot be returned from CTFE", ((VoidInitExp *)e)->var->toChars());
e = new ErrorExp();
}
if (e->op == TOKslice)
{
e = resolveSlice(e);
}
if (e->op == TOKstructliteral)
{
StructLiteralExp *se = (StructLiteralExp *)e;
se->ownedByCtfe = false;
if (!scrubArray(loc, se->elements, true))
return EXP_CANT_INTERPRET;
}
if (e->op == TOKstring)
{
((StringExp *)e)->ownedByCtfe = false;
}
if (e->op == TOKarrayliteral)
{
((ArrayLiteralExp *)e)->ownedByCtfe = false;
if (!scrubArray(loc, ((ArrayLiteralExp *)e)->elements))
return EXP_CANT_INTERPRET;
}
if (e->op == TOKassocarrayliteral)
{
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)e;
aae->ownedByCtfe = false;
if (!scrubArray(loc, aae->keys))
return EXP_CANT_INTERPRET;
if (!scrubArray(loc, aae->values))
return EXP_CANT_INTERPRET;
}
return e;
}
// Scrub all members of an array. Return false if error
bool scrubArray(Loc loc, Expressions *elems, bool structlit)
{
for (size_t i = 0; i < elems->dim; i++)
{
Expression *m = elems->tdata()[i];
if (!m)
continue;
if (m && m->op == TOKvoid && structlit)
m = NULL;
if (m)
m = scrubReturnValue(loc, m);
if (m == EXP_CANT_INTERPRET)
return false;
elems->tdata()[i] = m;
}
return true;
}
Expression *ReturnStatement::interpret(InterState *istate)
{
#if LOG
printf("ReturnStatement::interpret(%s)\n", exp ? exp->toChars() : "");
#endif
START()
if (!exp)
return EXP_VOID_INTERPRET;
assert(istate && istate->fd && istate->fd->type);
#if DMDV2
/* If the function returns a ref AND it's been called from an assignment,
* we need to return an lvalue. Otherwise, just do an (rvalue) interpret.
*/
if (istate->fd->type && istate->fd->type->ty==Tfunction)
{
TypeFunction *tf = (TypeFunction *)istate->fd->type;
if (tf->isref && istate->caller && istate->caller->awaitingLvalueReturn)
{ // We need to return an lvalue
Expression *e = exp->interpret(istate, ctfeNeedLvalue);
if (e == EXP_CANT_INTERPRET)
error("ref return %s is not yet supported in CTFE", exp->toChars());
return e;
}
if (tf->next && (tf->next->ty == Tdelegate) && istate->fd->closureVars.dim > 0)
{
// To support this, we need to copy all the closure vars
// into the delegate literal.
error("closures are not yet supported in CTFE");
return EXP_CANT_INTERPRET;
}
}
#endif
// We need to treat pointers specially, because TOKsymoff can be used to
// return a value OR a pointer
Expression *e;
if ( isPointer(exp->type) )
e = exp->interpret(istate, ctfeNeedLvalue);
else
e = exp->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (needToCopyLiteral(e))
e = copyLiteral(e);
#if LOGASSIGN
printf("RETURN %s\n", loc.toChars());
showCtfeExpr(e);
#endif
return e;
}
Expression *BreakStatement::interpret(InterState *istate)
{
#if LOG
printf("BreakStatement::interpret()\n");
#endif
START()
if (ident)
{ LabelDsymbol *label = istate->fd->searchLabel(ident);
assert(label && label->statement);
Statement *s = label->statement;
if (s->isLabelStatement())
s = s->isLabelStatement()->statement;
if (s->isScopeStatement())
s = s->isScopeStatement()->statement;
istate->gotoTarget = s;
return EXP_BREAK_INTERPRET;
}
else
{
istate->gotoTarget = NULL;
return EXP_BREAK_INTERPRET;
}
}
Expression *ContinueStatement::interpret(InterState *istate)
{
#if LOG
printf("ContinueStatement::interpret()\n");
#endif
START()
if (ident)
{ LabelDsymbol *label = istate->fd->searchLabel(ident);
assert(label && label->statement);
Statement *s = label->statement;
if (s->isLabelStatement())
s = s->isLabelStatement()->statement;
if (s->isScopeStatement())
s = s->isScopeStatement()->statement;
istate->gotoTarget = s;
return EXP_CONTINUE_INTERPRET;
}
else
return EXP_CONTINUE_INTERPRET;
}
Expression *WhileStatement::interpret(InterState *istate)
{
#if LOG
printf("WhileStatement::interpret()\n");
#endif
assert(0); // rewritten to ForStatement
return NULL;
}
Expression *DoStatement::interpret(InterState *istate)
{
#if LOG
printf("DoStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
Expression *e;
if (istate->start)
{
e = body ? body->interpret(istate) : NULL;
if (istate->start)
return NULL;
if (e == EXP_CANT_INTERPRET)
return e;
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
e = NULL;
} // else break at a higher level
return e;
}
if (e == EXP_CONTINUE_INTERPRET)
if (!istate->gotoTarget || istate->gotoTarget == this)
{
goto Lcontinue;
}
else // else continue at a higher level
return e;
if (e)
return e;
}
while (1)
{
e = body ? body->interpret(istate) : NULL;
if (e == EXP_CANT_INTERPRET)
break;
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
e = NULL;
} // else break at a higher level
break;
}
if (e && e != EXP_CONTINUE_INTERPRET)
break;
if (istate->gotoTarget && istate->gotoTarget != this)
break; // continue at a higher level
Lcontinue:
istate->gotoTarget = NULL;
e = condition->interpret(istate);
if (exceptionOrCantInterpret(e))
break;
if (!e->isConst())
{ e = EXP_CANT_INTERPRET;
break;
}
if (isTrueBool(e))
{
}
else if (e->isBool(FALSE))
{ e = NULL;
break;
}
else
assert(0);
}
return e;
}
Expression *ForStatement::interpret(InterState *istate)
{
#if LOG
printf("ForStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
Expression *e;
if (init)
{
e = init->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
assert(!e);
}
if (istate->start)
{
e = body ? body->interpret(istate) : NULL;
if (istate->start)
return NULL;
if (e == EXP_CANT_INTERPRET)
return e;
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
return NULL;
} // else break at a higher level
}
if (e == EXP_CONTINUE_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
goto Lcontinue;
} // else continue at a higher level
}
if (e)
return e;
}
while (1)
{
if (!condition)
goto Lhead;
e = condition->interpret(istate);
if (exceptionOrCantInterpret(e))
break;
if (!e->isConst())
{ e = EXP_CANT_INTERPRET;
break;
}
if (isTrueBool(e))
{
Lhead:
e = body ? body->interpret(istate) : NULL;
if (e == EXP_CANT_INTERPRET)
break;
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
e = NULL;
} // else break at a higher level
break;
}
if (e && e != EXP_CONTINUE_INTERPRET)
break;
if (istate->gotoTarget && istate->gotoTarget != this)
break; // continue at a higher level
Lcontinue:
istate->gotoTarget = NULL;
if (increment)
{
e = increment->interpret(istate);
if (e == EXP_CANT_INTERPRET)
break;
}
}
else if (e->isBool(FALSE))
{ e = NULL;
break;
}
else
assert(0);
}
return e;
}
Expression *ForeachStatement::interpret(InterState *istate)
{
assert(0); // rewritten to ForStatement
return NULL;
}
#if DMDV2
Expression *ForeachRangeStatement::interpret(InterState *istate)
{
assert(0); // rewritten to ForStatement
return NULL;
}
#endif
Expression *SwitchStatement::interpret(InterState *istate)
{
#if LOG
printf("SwitchStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
Expression *e = NULL;
if (istate->start)
{
e = body ? body->interpret(istate) : NULL;
if (istate->start)
return NULL;
if (e == EXP_CANT_INTERPRET)
return e;
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
return NULL;
} // else break at a higher level
}
return e;
}
Expression *econdition = condition->interpret(istate);
if (exceptionOrCantInterpret(econdition))
return econdition;
if (econdition->op == TOKslice)
econdition = resolveSlice(econdition);
Statement *s = NULL;
if (cases)
{
for (size_t i = 0; i < cases->dim; i++)
{
CaseStatement *cs = cases->tdata()[i];
Expression * caseExp = cs->exp->interpret(istate);
if (exceptionOrCantInterpret(caseExp))
return caseExp;
e = ctfeEqual(caseExp->loc, TOKequal, Type::tint32, econdition, caseExp);
if (exceptionOrCantInterpret(e))
return e;
if (e->isBool(TRUE))
{ s = cs;
break;
}
}
}
if (!s)
{ if (hasNoDefault)
error("no default or case for %s in switch statement", econdition->toChars());
s = sdefault;
}
assert(s);
istate->start = s;
e = body ? body->interpret(istate) : NULL;
assert(!istate->start);
if (e == EXP_BREAK_INTERPRET)
{
if (!istate->gotoTarget || istate->gotoTarget == this)
{
istate->gotoTarget = NULL;
e = NULL;
} // else break at a higher level
}
return e;
}
Expression *CaseStatement::interpret(InterState *istate)
{
#if LOG
printf("CaseStatement::interpret(%s) this = %p\n", exp->toChars(), this);
#endif
if (istate->start == this)
istate->start = NULL;
if (statement)
return statement->interpret(istate);
else
return NULL;
}
Expression *DefaultStatement::interpret(InterState *istate)
{
#if LOG
printf("DefaultStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
if (statement)
return statement->interpret(istate);
else
return NULL;
}
Expression *GotoStatement::interpret(InterState *istate)
{
#if LOG
printf("GotoStatement::interpret()\n");
#endif
START()
assert(label && label->statement);
istate->gotoTarget = label->statement;
return EXP_GOTO_INTERPRET;
}
Expression *GotoCaseStatement::interpret(InterState *istate)
{
#if LOG
printf("GotoCaseStatement::interpret()\n");
#endif
START()
assert(cs);
istate->gotoTarget = cs;
return EXP_GOTO_INTERPRET;
}
Expression *GotoDefaultStatement::interpret(InterState *istate)
{
#if LOG
printf("GotoDefaultStatement::interpret()\n");
#endif
START()
assert(sw && sw->sdefault);
istate->gotoTarget = sw->sdefault;
return EXP_GOTO_INTERPRET;
}
Expression *LabelStatement::interpret(InterState *istate)
{
#if LOG
printf("LabelStatement::interpret()\n");
#endif
if (istate->start == this)
istate->start = NULL;
return statement ? statement->interpret(istate) : NULL;
}
Expression *TryCatchStatement::interpret(InterState *istate)
{
#if LOG
printf("TryCatchStatement::interpret()\n");
#endif
START()
Expression *e = body ? body->interpret(istate) : NULL;
if (e == EXP_CANT_INTERPRET)
return e;
if (!exceptionOrCantInterpret(e))
return e;
// An exception was thrown
ThrownExceptionExp *ex = (ThrownExceptionExp *)e;
Type *extype = ex->thrown->originalClass()->type;
// Search for an appropriate catch clause.
for (size_t i = 0; i < catches->dim; i++)
{
#if DMDV1
Catch *ca = (Catch *)catches->data[i];
#else
Catch *ca = catches->tdata()[i];
#endif
Type *catype = ca->type;
if (catype->equals(extype) || catype->isBaseOf(extype, NULL))
{ // Execute the handler
if (ca->var)
{
ctfeStack.push(ca->var);
ca->var->setValue(ex->thrown);
}
return ca->handler ? ca->handler->interpret(istate) : NULL;
}
}
return e;
}
bool isAnErrorException(ClassDeclaration *cd)
{
return cd == ClassDeclaration::errorException || ClassDeclaration::errorException->isBaseOf(cd, NULL);
}
ThrownExceptionExp *chainExceptions(ThrownExceptionExp *oldest, ThrownExceptionExp *newest)
{
#if LOG
printf("Collided exceptions %s %s\n", oldest->thrown->toChars(), newest->thrown->toChars());
#endif
#if DMDV2
// Little sanity check to make sure it's really a Throwable
ClassReferenceExp *boss = oldest->thrown;
assert(boss->value->elements->tdata()[4]->type->ty == Tclass);
ClassReferenceExp *collateral = newest->thrown;
if (isAnErrorException(collateral->originalClass())
&& !isAnErrorException(boss->originalClass()))
{ // The new exception bypass the existing chain
assert(collateral->value->elements->tdata()[5]->type->ty == Tclass);
collateral->value->elements->tdata()[5] = boss;
return newest;
}
while (boss->value->elements->tdata()[4]->op == TOKclassreference)
{
boss = (ClassReferenceExp *)(boss->value->elements->tdata()[4]);
}
boss->value->elements->tdata()[4] = collateral;
return oldest;
#else
// for D1, the newest exception just clobbers the older one
return newest;
#endif
}
Expression *TryFinallyStatement::interpret(InterState *istate)
{
#if LOG
printf("TryFinallyStatement::interpret()\n");
#endif
START()
Expression *e = body ? body->interpret(istate) : NULL;
if (e == EXP_CANT_INTERPRET)
return e;
Expression *second = finalbody ? finalbody->interpret(istate) : NULL;
if (second == EXP_CANT_INTERPRET)
return second;
if (exceptionOrCantInterpret(second))
{ // Check for collided exceptions
if (exceptionOrCantInterpret(e))
e = chainExceptions((ThrownExceptionExp *)e, (ThrownExceptionExp *)second);
else
e = second;
}
return e;
}
Expression *ThrowStatement::interpret(InterState *istate)
{
#if LOG
printf("ThrowStatement::interpret()\n");
#endif
START()
Expression *e = exp->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
assert(e->op == TOKclassreference);
return new ThrownExceptionExp(loc, (ClassReferenceExp *)e);
}
Expression *OnScopeStatement::interpret(InterState *istate)
{
assert(0);
return EXP_CANT_INTERPRET;
}
Expression *WithStatement::interpret(InterState *istate)
{
#if LOG
printf("WithStatement::interpret()\n");
#endif
START()
Expression *e = exp->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (wthis->type->ty == Tpointer && exp->type->ty != Tpointer)
{
e = new AddrExp(loc, e);
e->type = wthis->type;
}
ctfeStack.push(wthis);
wthis->setValue(e);
e = body ? body->interpret(istate) : EXP_VOID_INTERPRET;
ctfeStack.pop(wthis);
return e;
}
Expression *AsmStatement::interpret(InterState *istate)
{
#if LOG
printf("AsmStatement::interpret()\n");
#endif
START()
error("asm statements cannot be interpreted at compile time");
return EXP_CANT_INTERPRET;
}
#if DMDV2
Expression *ImportStatement::interpret(InterState *istate)
{
#if LOG
printf("ImportStatement::interpret()\n");
#endif
START();
return NULL;
}
#endif
/******************************** Expression ***************************/
Expression *Expression::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("Expression::interpret() %s\n", toChars());
printf("type = %s\n", type->toChars());
dump(0);
#endif
error("Cannot interpret %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
Expression *ThisExp::interpret(InterState *istate, CtfeGoal goal)
{
while (istate && !istate->localThis)
istate = istate->caller;
if (istate && istate->localThis && istate->localThis->op == TOKstructliteral)
return istate->localThis;
if (istate && istate->localThis)
return istate->localThis->interpret(istate, goal);
error("value of 'this' is not known at compile time");
return EXP_CANT_INTERPRET;
}
Expression *NullExp::interpret(InterState *istate, CtfeGoal goal)
{
return this;
}
Expression *IntegerExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("IntegerExp::interpret() %s\n", toChars());
#endif
return this;
}
Expression *RealExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("RealExp::interpret() %s\n", toChars());
#endif
return this;
}
Expression *ComplexExp::interpret(InterState *istate, CtfeGoal goal)
{
return this;
}
Expression *StringExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("StringExp::interpret() %s\n", toChars());
#endif
/* In both D1 and D2, attempts to modify string literals are prevented
* in BinExp::interpretAssignCommon.
* In D2, we also disallow casts of read-only literals to mutable,
* though it isn't strictly necessary.
*/
#if DMDV2
// Fixed-length char arrays always get duped later anyway.
if (type->ty == Tsarray)
return this;
if (!(((TypeNext *)type)->next->mod & (MODconst | MODimmutable)))
{ // It seems this happens only when there has been an explicit cast
error("cannot cast a read-only string literal to mutable in CTFE");
return EXP_CANT_INTERPRET;
}
#endif
return this;
}
Expression *FuncExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("FuncExp::interpret() %s\n", toChars());
#endif
return this;
}
/* Is it safe to convert from srcPointee* to destPointee* ?
* srcPointee is the genuine type (never void).
* destPointee may be void.
*/
bool isSafePointerCast(Type *srcPointee, Type *destPointee)
{ // It's OK if both are the same (modulo const)
#if DMDV2
if (srcPointee->castMod(0) == destPointee->castMod(0))
return true;
#else
if (srcPointee == destPointee)
return true;
#endif
// it's OK to cast to void*
if (destPointee->ty == Tvoid)
return true;
// It's OK if they are the same size integers, eg int* and uint*
return srcPointee->isintegral() && destPointee->isintegral()
&& srcPointee->size() == destPointee->size();
}
Expression *SymOffExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("SymOffExp::interpret() %s\n", toChars());
#endif
if (var->isFuncDeclaration() && offset == 0)
{
return this;
}
if (type->ty != Tpointer)
{ // Probably impossible
error("Cannot interpret %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
Type *pointee = ((TypePointer *)type)->next;
Expression *val = getVarExp(loc, istate, var, goal);
if (val == EXP_CANT_INTERPRET)
return val;
if (val->type->ty == Tarray || val->type->ty == Tsarray)
{
// Check for unsupported type painting operations
Type *elemtype = ((TypeArray *)(val->type))->next;
// It's OK to cast from fixed length to dynamic array, eg &int[3] to int[]*
if (val->type->ty == Tsarray && pointee->ty == Tarray
&& elemtype->size() == pointee->nextOf()->size())
{
Expression *e = new AddrExp(loc, val);
e->type = type;
return e;
}
if ( !isSafePointerCast(elemtype, pointee) )
{ // It's also OK to cast from &string to string*.
if ( offset == 0 && isSafePointerCast(var->type, pointee) )
{
VarExp *ve = new VarExp(loc, var);
ve->type = type;
return ve;
}
error("reinterpreting cast from %s to %s is not supported in CTFE",
val->type->toChars(), type->toChars());
return EXP_CANT_INTERPRET;
}
TypeArray *tar = (TypeArray *)val->type;
dinteger_t sz = pointee->size();
dinteger_t indx = offset/sz;
assert(sz * indx == offset);
Expression *aggregate = NULL;
if (val->op == TOKarrayliteral || val->op == TOKstring)
aggregate = val;
else if (val->op == TOKslice)
{
aggregate = ((SliceExp *)val)->e1;
Expression *lwr = ((SliceExp *)val)->lwr->interpret(istate);
indx += lwr->toInteger();
}
if (aggregate)
{
IntegerExp *ofs = new IntegerExp(loc, indx, Type::tsize_t);
IndexExp *ie = new IndexExp(loc, aggregate, ofs);
ie->type = type;
return ie;
}
}
else if ( offset == 0 && isSafePointerCast(var->type, pointee) )
{
VarExp *ve = new VarExp(loc, var);
ve->type = type;
return ve;
}
error("Cannot convert &%s to %s at compile time", var->type->toChars(), type->toChars());
return EXP_CANT_INTERPRET;
}
Expression *AddrExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("AddrExp::interpret() %s\n", toChars());
#endif
// For reference types, we need to return an lvalue ref.
TY tb = e1->type->toBasetype()->ty;
bool needRef = (tb == Tarray || tb == Taarray || tb == Tclass);
Expression *e = e1->interpret(istate, needRef ? ctfeNeedLvalueRef : ctfeNeedLvalue);
if (exceptionOrCantInterpret(e))
return e;
// Return a simplified address expression
e = new AddrExp(loc, e);
e->type = type;
return e;
}
Expression *DelegateExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("DelegateExp::interpret() %s\n", toChars());
#endif
return this;
}
// -------------------------------------------------------------
// Remove out, ref, and this
// -------------------------------------------------------------
// The variable used in a dotvar, index, or slice expression,
// after 'out', 'ref', and 'this' have been removed.
Expression * resolveReferences(Expression *e, Expression *thisval)
{
for(;;)
{
if (e->op == TOKthis)
{
assert(thisval);
assert(e != thisval);
e = thisval;
continue;
}
if (e->op == TOKvar)
{
VarExp *ve = (VarExp *)e;
VarDeclaration *v = ve->var->isVarDeclaration();
if (v->type->ty == Tpointer)
break;
if (v->ctfeAdrOnStack == (size_t)-1) // If not on the stack, can't possibly be a ref.
break;
if (v && v->getValue() && (v->getValue()->op == TOKslice))
{
SliceExp *se = (SliceExp *)v->getValue();
if (se->e1->op == TOKarrayliteral || se->e1->op == TOKassocarrayliteral || se->e1->op == TOKstring)
break;
e = v->getValue();
continue;
}
else if (v && v->getValue() && (v->getValue()->op==TOKindex || v->getValue()->op == TOKdotvar
|| v->getValue()->op == TOKthis ))
{
e = v->getValue();
continue;
}
}
break;
}
return e;
}
Expression *getVarExp(Loc loc, InterState *istate, Declaration *d, CtfeGoal goal)
{
Expression *e = EXP_CANT_INTERPRET;
VarDeclaration *v = d->isVarDeclaration();
SymbolDeclaration *s = d->isSymbolDeclaration();
if (v)
{
#if DMDV2
/* Magic variable __ctfe always returns true when interpreting
*/
if (v->ident == Id::ctfe)
return new IntegerExp(loc, 1, Type::tbool);
if ((v->isConst() || v->isImmutable() || v->storage_class & STCmanifest) && v->init && !v->hasValue())
#else
if (v->isConst() && v->init)
#endif
{ e = v->init->toExpression();
if (e && (e->op == TOKconstruct || e->op == TOKblit))
{ AssignExp *ae = (AssignExp *)e;
e = ae->e2;
v->inuse++;
e = e->interpret(istate, ctfeNeedAnyValue);
v->inuse--;
if (e == EXP_CANT_INTERPRET && !global.gag && !CtfeStatus::stackTraceCallsToSuppress)
errorSupplemental(loc, "while evaluating %s.init", v->toChars());
if (exceptionOrCantInterpret(e))
return e;
e->type = v->type;
}
else
{
if (e && !e->type)
e->type = v->type;
if (e)
e = e->interpret(istate, ctfeNeedAnyValue);
if (e == EXP_CANT_INTERPRET && !global.gag && !CtfeStatus::stackTraceCallsToSuppress)
errorSupplemental(loc, "while evaluating %s.init", v->toChars());
}
if (e && e != EXP_CANT_INTERPRET && e->op != TOKthrownexception)
{
e = copyLiteral(e);
ctfeStack.saveGlobalConstant(v, e);
}
}
else if (v->isCTFE() && !v->hasValue())
{
if (v->init && v->type->size() != 0)
{
if (v->init->isVoidInitializer())
{
// var should have been initialized when it was created
error(loc, "CTFE internal error - trying to access uninitialized var");
assert(0);
e = EXP_CANT_INTERPRET;
}
else
{
e = v->init->toExpression();
e = e->interpret(istate);
}
}
else
e = v->type->defaultInitLiteral(loc);
}
else if (!v->isDataseg() && !v->isCTFE() && !istate)
{ error(loc, "variable %s cannot be read at compile time", v->toChars());
return EXP_CANT_INTERPRET;
}
else
{ e = v->hasValue() ? v->getValue() : NULL;
if (!e && !v->isCTFE() && v->isDataseg())
{ error(loc, "static variable %s cannot be read at compile time", v->toChars());
e = EXP_CANT_INTERPRET;
}
else if (!e)
{
assert(0);
assert(v->init && v->init->isVoidInitializer());
e = v->type->voidInitLiteral(v);
}
else if (exceptionOrCantInterpret(e))
return e;
else if (goal == ctfeNeedLvalue && v->isRef() && e->op == TOKindex)
{ // If it is a foreach ref, resolve the index into a constant
IndexExp *ie = (IndexExp *)e;
Expression *w = ie->e2->interpret(istate);
if (w != ie->e2)
{
e = new IndexExp(ie->loc, ie->e1, w);
e->type = ie->type;
}
return e;
}
else if ((goal == ctfeNeedLvalue)
|| e->op == TOKstring || e->op == TOKstructliteral || e->op == TOKarrayliteral
|| e->op == TOKassocarrayliteral || e->op == TOKslice
|| e->type->toBasetype()->ty == Tpointer)
return e; // it's already an Lvalue
else if (e->op == TOKvoid)
{
VoidInitExp *ve = (VoidInitExp *)e;
error(loc, "cannot read uninitialized variable %s in ctfe", v->toPrettyChars());
errorSupplemental(ve->var->loc, "%s was uninitialized and used before set", ve->var->toChars());
e = EXP_CANT_INTERPRET;
}
else
e = e->interpret(istate, goal);
}
if (!e)
e = EXP_CANT_INTERPRET;
}
else if (s)
{ // Struct static initializers, for example
if (s->dsym->toInitializer() == s->sym)
{ e = s->dsym->type->defaultInitLiteral(loc);
e = e->semantic(NULL);
if (e->op == TOKerror)
e = EXP_CANT_INTERPRET;
else // Convert NULL to VoidExp
e = e->interpret(istate, goal);
}
else
error(loc, "cannot interpret symbol %s at compile time", v->toChars());
}
else
error(loc, "cannot interpret declaration %s at compile time", d->toChars());
return e;
}
Expression *VarExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("VarExp::interpret() %s\n", toChars());
#endif
if (goal == ctfeNeedLvalueRef)
{
VarDeclaration *v = var->isVarDeclaration();
if (v && !v->isDataseg() && !v->isCTFE() && !istate)
{ error("variable %s cannot be referenced at compile time", v->toChars());
return EXP_CANT_INTERPRET;
}
else if (v && !v->hasValue() && !v->isCTFE() && v->isDataseg())
{ error("static variable %s cannot be referenced at compile time", v->toChars());
return EXP_CANT_INTERPRET;
}
return this;
}
Expression *e = getVarExp(loc, istate, var, goal);
// A VarExp may include an implicit cast. It must be done explicitly.
if (e != EXP_CANT_INTERPRET && e->op != TOKthrownexception)
e = paintTypeOntoLiteral(type, e);
return e;
}
Expression *DeclarationExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("DeclarationExp::interpret() %s\n", toChars());
#endif
Expression *e;
VarDeclaration *v = declaration->isVarDeclaration();
if (v)
{
if (v->toAlias()->isTupleDeclaration())
{ // Reserve stack space for all tuple members
TupleDeclaration *td =v->toAlias()->isTupleDeclaration();
if (!td->objects)
return NULL;
for(int i= 0; i < td->objects->dim; ++i)
{
Object * o = td->objects->tdata()[i];
Expression *ex = isExpression(o);
DsymbolExp *s = (ex && ex->op == TOKdsymbol) ? (DsymbolExp *)ex : NULL;
VarDeclaration *v2 = s ? s->s->isVarDeclaration() : NULL;
assert(v2);
if (!v2->isDataseg() || v2->isCTFE())
ctfeStack.push(v2);
}
}
if (!v->isDataseg() || v->isCTFE())
ctfeStack.push(v);
Dsymbol *s = v->toAlias();
if (s == v && !v->isStatic() && v->init)
{
ExpInitializer *ie = v->init->isExpInitializer();
if (ie)
e = ie->exp->interpret(istate);
else if (v->init->isVoidInitializer())
{
e = v->type->voidInitLiteral(v);
// There is no AssignExp for void initializers,
// so set it here.
v->setValue(e);
}
else
{
error("Declaration %s is not yet implemented in CTFE", toChars());
e = EXP_CANT_INTERPRET;
}
}
else if (s == v && !v->init && v->type->size()==0)
{ // Zero-length arrays don't need an initializer
e = v->type->defaultInitLiteral(loc);
}
#if DMDV2
else if (s == v && (v->isConst() || v->isImmutable()) && v->init)
#else
else if (s == v && v->isConst() && v->init)
#endif
{ e = v->init->toExpression();
if (!e)
e = EXP_CANT_INTERPRET;
else if (!e->type)
e->type = v->type;
}
else if (s->isTupleDeclaration() && !v->init)
e = NULL;
else if (v->isStatic() && !v->init)
e = NULL; // Just ignore static variables which aren't read or written yet
else
{
error("Static variable %s cannot be modified at compile time", v->toChars());
e = EXP_CANT_INTERPRET;
}
}
else if (declaration->isAttribDeclaration() ||
declaration->isTemplateMixin() ||
declaration->isTupleDeclaration())
{ // Check for static struct declarations, which aren't executable
AttribDeclaration *ad = declaration->isAttribDeclaration();
if (ad && ad->decl && ad->decl->dim == 1
&& ad->decl->tdata()[0]->isAggregateDeclaration())
return NULL; // static struct declaration. Nothing to do.
// These can be made to work, too lazy now
error("Declaration %s is not yet implemented in CTFE", toChars());
e = EXP_CANT_INTERPRET;
}
else
{ // Others should not contain executable code, so are trivial to evaluate
e = NULL;
}
#if LOG
printf("-DeclarationExp::interpret(%s): %p\n", toChars(), e);
#endif
return e;
}
Expression *TupleExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("TupleExp::interpret() %s\n", toChars());
#endif
Expressions *expsx = NULL;
for (size_t i = 0; i < exps->dim; i++)
{ Expression *e = exps->tdata()[i];
Expression *ex;
ex = e->interpret(istate);
if (exceptionOrCantInterpret(ex))
{ delete expsx;
return ex;
}
// A tuple of assignments can contain void (Bug 5676).
if (goal == ctfeNeedNothing)
continue;
if (ex == EXP_VOID_INTERPRET)
{
error("ICE: void element %s in tuple", e->toChars());
assert(0);
}
/* If any changes, do Copy On Write
*/
if (ex != e)
{
if (!expsx)
{ expsx = new Expressions();
++CtfeStatus::numArrayAllocs;
expsx->setDim(exps->dim);
for (size_t j = 0; j < i; j++)
{
expsx->tdata()[j] = exps->tdata()[j];
}
}
expsx->tdata()[i] = ex;
}
}
if (expsx)
{ TupleExp *te = new TupleExp(loc, expsx);
expandTuples(te->exps);
te->type = new TypeTuple(te->exps);
return te;
}
return this;
}
Expression *ArrayLiteralExp::interpret(InterState *istate, CtfeGoal goal)
{ Expressions *expsx = NULL;
#if LOG
printf("ArrayLiteralExp::interpret() %s\n", toChars());
#endif
if (ownedByCtfe) // We've already interpreted all the elements
return copyLiteral(this);
if (elements)
{
for (size_t i = 0; i < elements->dim; i++)
{ Expression *e = elements->tdata()[i];
Expression *ex;
if (e->op == TOKindex) // segfault bug 6250
assert( ((IndexExp*)e)->e1 != this);
ex = e->interpret(istate);
if (ex == EXP_CANT_INTERPRET)
goto Lerror;
if (ex->op == TOKthrownexception)
return ex;
/* If any changes, do Copy On Write
*/
if (ex != e)
{
if (!expsx)
{ expsx = new Expressions();
++CtfeStatus::numArrayAllocs;
expsx->setDim(elements->dim);
for (size_t j = 0; j < elements->dim; j++)
{
expsx->tdata()[j] = elements->tdata()[j];
}
}
expsx->tdata()[i] = ex;
}
}
}
if (elements && expsx)
{
expandTuples(expsx);
if (expsx->dim != elements->dim)
goto Lerror;
ArrayLiteralExp *ae = new ArrayLiteralExp(loc, expsx);
ae->type = type;
return copyLiteral(ae);
}
#if DMDV2
if (((TypeNext *)type)->next->mod & (MODconst | MODimmutable))
{ // If it's immutable, we don't need to dup it
return this;
}
#endif
return copyLiteral(this);
Lerror:
if (expsx)
delete expsx;
error("cannot interpret array literal");
return EXP_CANT_INTERPRET;
}
Expression *AssocArrayLiteralExp::interpret(InterState *istate, CtfeGoal goal)
{ Expressions *keysx = keys;
Expressions *valuesx = values;
#if LOG
printf("AssocArrayLiteralExp::interpret() %s\n", toChars());
#endif
if (ownedByCtfe) // We've already interpreted all the elements
return copyLiteral(this);
for (size_t i = 0; i < keys->dim; i++)
{ Expression *ekey = keys->tdata()[i];
Expression *evalue = values->tdata()[i];
Expression *ex;
ex = ekey->interpret(istate);
if (ex == EXP_CANT_INTERPRET)
goto Lerr;
if (ex->op == TOKthrownexception)
return ex;
/* If any changes, do Copy On Write
*/
if (ex != ekey)
{
if (keysx == keys)
keysx = (Expressions *)keys->copy();
keysx->tdata()[i] = ex;
}
ex = evalue->interpret(istate);
if (ex == EXP_CANT_INTERPRET)
goto Lerr;
if (ex->op == TOKthrownexception)
return ex;
/* If any changes, do Copy On Write
*/
if (ex != evalue)
{
if (valuesx == values)
valuesx = (Expressions *)values->copy();
valuesx->tdata()[i] = ex;
}
}
if (keysx != keys)
expandTuples(keysx);
if (valuesx != values)
expandTuples(valuesx);
if (keysx->dim != valuesx->dim)
goto Lerr;
/* Remove duplicate keys
*/
for (size_t i = 1; i < keysx->dim; i++)
{ Expression *ekey = keysx->tdata()[i - 1];
if (ekey->op == TOKslice)
ekey = resolveSlice(ekey);
for (size_t j = i; j < keysx->dim; j++)
{ Expression *ekey2 = keysx->tdata()[j];
Expression *ex = ctfeEqual(loc, TOKequal, Type::tbool, ekey, ekey2);
if (ex == EXP_CANT_INTERPRET)
goto Lerr;
if (ex->isBool(TRUE)) // if a match
{
// Remove ekey
if (keysx == keys)
keysx = (Expressions *)keys->copy();
if (valuesx == values)
valuesx = (Expressions *)values->copy();
keysx->remove(i - 1);
valuesx->remove(i - 1);
i -= 1; // redo the i'th iteration
break;
}
}
}
if (keysx != keys || valuesx != values)
{
AssocArrayLiteralExp *ae;
ae = new AssocArrayLiteralExp(loc, keysx, valuesx);
ae->type = type;
ae->ownedByCtfe = true;
return ae;
}
return this;
Lerr:
if (keysx != keys)
delete keysx;
if (valuesx != values)
delete values;
return EXP_CANT_INTERPRET;
}
Expression *StructLiteralExp::interpret(InterState *istate, CtfeGoal goal)
{ Expressions *expsx = NULL;
#if LOG
printf("StructLiteralExp::interpret() %s\n", toChars());
#endif
/* We don't know how to deal with overlapping fields
*/
if (sd->hasUnions)
{ error("Unions with overlapping fields are not yet supported in CTFE");
return EXP_CANT_INTERPRET;
}
if (ownedByCtfe)
return copyLiteral(this);
if (elements)
{
for (size_t i = 0; i < elements->dim; i++)
{ Expression *e = elements->tdata()[i];
if (!e)
continue;
Expression *ex = e->interpret(istate);
if (exceptionOrCantInterpret(ex))
{ delete expsx;
return ex;
}
/* If any changes, do Copy On Write
*/
if (ex != e)
{
if (!expsx)
{ expsx = new Expressions();
++CtfeStatus::numArrayAllocs;
expsx->setDim(elements->dim);
for (size_t j = 0; j < elements->dim; j++)
{
expsx->tdata()[j] = elements->tdata()[j];
}
}
expsx->tdata()[i] = ex;
}
}
}
if (elements && expsx)
{
expandTuples(expsx);
if (expsx->dim != elements->dim)
{ delete expsx;
return EXP_CANT_INTERPRET;
}
StructLiteralExp *se = new StructLiteralExp(loc, sd, expsx);
se->type = type;
se->ownedByCtfe = true;
return se;
}
return copyLiteral(this);
}
/******************************
* Helper for NewExp
* Create an array literal consisting of 'elem' duplicated 'dim' times.
*/
ArrayLiteralExp *createBlockDuplicatedArrayLiteral(Loc loc, Type *type,
Expression *elem, size_t dim)
{
Expressions *elements = new Expressions();
elements->setDim(dim);
bool mustCopy = needToCopyLiteral(elem);
for (size_t i = 0; i < dim; i++)
{ if (mustCopy)
elem = copyLiteral(elem);
elements->tdata()[i] = elem;
}
ArrayLiteralExp *ae = new ArrayLiteralExp(loc, elements);
ae->type = type;
ae->ownedByCtfe = true;
return ae;
}
/******************************
* Helper for NewExp
* Create a string literal consisting of 'value' duplicated 'dim' times.
*/
StringExp *createBlockDuplicatedStringLiteral(Loc loc, Type *type,
unsigned value, size_t dim, int sz)
{
unsigned char *s;
s = (unsigned char *)mem.calloc(dim + 1, sz);
for (size_t elemi=0; elemi<dim; ++elemi)
{
switch (sz)
{
case 1: s[elemi] = value; break;
case 2: ((unsigned short *)s)[elemi] = value; break;
case 4: ((unsigned *)s)[elemi] = value; break;
default: assert(0);
}
}
StringExp *se = new StringExp(loc, s, dim);
se->type = type;
se->sz = sz;
se->committed = true;
se->ownedByCtfe = true;
return se;
}
// Create an array literal of type 'newtype' with dimensions given by
// 'arguments'[argnum..$]
Expression *recursivelyCreateArrayLiteral(Loc loc, Type *newtype, InterState *istate,
Expressions *arguments, int argnum)
{
Expression *lenExpr = ((arguments->tdata()[argnum]))->interpret(istate);
if (exceptionOrCantInterpret(lenExpr))
return lenExpr;
size_t len = (size_t)(lenExpr->toInteger());
Type *elemType = ((TypeArray *)newtype)->next;
if (elemType->ty == Tarray && argnum < arguments->dim - 1)
{
Expression *elem = recursivelyCreateArrayLiteral(loc, elemType, istate,
arguments, argnum + 1);
if (exceptionOrCantInterpret(elem))
return elem;
Expressions *elements = new Expressions();
elements->setDim(len);
for (size_t i = 0; i < len; i++)
elements->tdata()[i] = copyLiteral(elem);
ArrayLiteralExp *ae = new ArrayLiteralExp(loc, elements);
ae->type = newtype;
ae->ownedByCtfe = true;
return ae;
}
assert(argnum == arguments->dim - 1);
if (elemType->ty == Tchar || elemType->ty == Twchar
|| elemType->ty == Tdchar)
return createBlockDuplicatedStringLiteral(loc, newtype,
(unsigned)(elemType->defaultInitLiteral(loc)->toInteger()),
len, elemType->size());
return createBlockDuplicatedArrayLiteral(loc, newtype,
elemType->defaultInitLiteral(loc),
len);
}
Expression *NewExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("NewExp::interpret() %s\n", toChars());
#endif
if (newtype->ty == Tarray && arguments)
return recursivelyCreateArrayLiteral(loc, newtype, istate, arguments, 0);
if (newtype->toBasetype()->ty == Tstruct)
{
Expression *se = newtype->defaultInitLiteral(loc);
#if DMDV2
if (member)
{
int olderrors = global.errors;
member->interpret(istate, arguments, se);
if (olderrors != global.errors)
{
error("cannot evaluate %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
}
#else // The above code would fail on D1 because it doesn't use STRUCTTHISREF,
// but that's OK because D1 doesn't have struct constructors anyway.
assert(!member);
#endif
Expression *e = new AddrExp(loc, copyLiteral(se));
e->type = type;
return e;
}
if (newtype->toBasetype()->ty == Tclass)
{
ClassDeclaration *cd = ((TypeClass *)newtype->toBasetype())->sym;
size_t totalFieldCount = 0;
for (ClassDeclaration *c = cd; c; c = c->baseClass)
totalFieldCount += c->fields.dim;
Expressions *elems = new Expressions;
elems->setDim(totalFieldCount);
size_t fieldsSoFar = totalFieldCount;
for (ClassDeclaration *c = cd; c; c = c->baseClass)
{
fieldsSoFar -= c->fields.dim;
for (size_t i = 0; i < c->fields.dim; i++)
{
Dsymbol *s = c->fields.tdata()[i];
VarDeclaration *v = s->isVarDeclaration();
assert(v);
Expression *m = v->init ? v->init->toExpression() : v->type->defaultInitLiteral(loc);
if (exceptionOrCantInterpret(m))
return m;
elems->tdata()[fieldsSoFar+i] = copyLiteral(m);
}
}
// Hack: we store a ClassDeclaration instead of a StructDeclaration.
// We probably won't get away with this.
StructLiteralExp *se = new StructLiteralExp(loc, (StructDeclaration *)cd, elems, newtype);
se->ownedByCtfe = true;
Expression *e = new ClassReferenceExp(loc, se, type);
if (member)
{ // Call constructor
if (!member->fbody)
{
Expression *ctorfail = evaluateIfBuiltin(istate, loc, member, arguments, e);
if (ctorfail && exceptionOrCantInterpret(ctorfail))
return ctorfail;
if (ctorfail)
return e;
member->error("%s cannot be constructed at compile time, because the constructor has no available source code", newtype->toChars());
return EXP_CANT_INTERPRET;
}
Expression * ctorfail = member->interpret(istate, arguments, e);
if (exceptionOrCantInterpret(ctorfail))
return ctorfail;
}
return e;
}
error("Cannot interpret %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
Expression *UnaExp::interpretCommon(InterState *istate, CtfeGoal goal, Expression *(*fp)(Type *, Expression *))
{ Expression *e;
Expression *e1;
#if LOG
printf("UnaExp::interpretCommon() %s\n", toChars());
#endif
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
e = (*fp)(type, e1);
return e;
}
#define UNA_INTERPRET(op) \
Expression *op##Exp::interpret(InterState *istate, CtfeGoal goal) \
{ \
return interpretCommon(istate, goal, &op); \
}
UNA_INTERPRET(Neg)
UNA_INTERPRET(Com)
UNA_INTERPRET(Not)
UNA_INTERPRET(Bool)
Expression *getAggregateFromPointer(Expression *e, dinteger_t *ofs)
{
*ofs = 0;
if (e->op == TOKaddress)
e = ((AddrExp *)e)->e1;
if (e->op == TOKdotvar)
{
Expression *ex = ((DotVarExp *)e)->e1;
VarDeclaration *v = ((DotVarExp *)e)->var->isVarDeclaration();
assert(v);
StructLiteralExp *se = ex->op == TOKclassreference ? ((ClassReferenceExp *)ex)->value : (StructLiteralExp *)ex;
// We can't use getField, because it makes a copy
int i = -1;
if (ex->op == TOKclassreference)
i = ((ClassReferenceExp *)ex)->getFieldIndex(e->type, v->offset);
else
i = se->getFieldIndex(e->type, v->offset);
assert(i != -1);
e = se->elements->tdata()[i];
}
if (e->op == TOKindex)
{
IndexExp *ie = (IndexExp *)e;
// Note that each AA element is part of its own memory block
if ((ie->e1->type->ty == Tarray || ie->e1->type->ty == Tsarray
|| ie->e1->op == TOKstring || ie->e1->op==TOKarrayliteral) &&
ie->e2->op == TOKint64)
{
*ofs = ie->e2->toInteger();
return ie->e1;
}
}
return e;
}
// return e1 - e2 as an integer, or error if not possible
Expression *pointerDifference(Loc loc, Type *type, Expression *e1, Expression *e2)
{
dinteger_t ofs1, ofs2;
Expression *agg1 = getAggregateFromPointer(e1, &ofs1);
Expression *agg2 = getAggregateFromPointer(e2, &ofs2);
if (agg1 == agg2)
{
Type *pointee = ((TypePointer *)agg1->type)->next;
dinteger_t sz = pointee->size();
return new IntegerExp(loc, (ofs1-ofs2)*sz, type);
}
else if (agg1->op == TOKstring && agg2->op == TOKstring)
{
if (((StringExp *)agg1)->string == ((StringExp *)agg2)->string)
{
Type *pointee = ((TypePointer *)agg1->type)->next;
dinteger_t sz = pointee->size();
return new IntegerExp(loc, (ofs1-ofs2)*sz, type);
}
}
#if LOGASSIGN
printf("FAILED POINTER DIFF\n");
showCtfeExpr(agg1);
showCtfeExpr(agg2);
#endif
error(loc, "%s - %s cannot be interpreted at compile time: cannot subtract "
"pointers to two different memory blocks",
e1->toChars(), e2->toChars());
return EXP_CANT_INTERPRET;
}
// Return eptr op e2, where eptr is a pointer, e2 is an integer,
// and op is TOKadd or TOKmin
Expression *pointerArithmetic(Loc loc, enum TOK op, Type *type,
Expression *eptr, Expression *e2)
{
if (eptr->type->nextOf()->ty == Tvoid)
{
error(loc, "cannot perform arithmetic on void* pointers at compile time");
return EXP_CANT_INTERPRET;
}
dinteger_t ofs1, ofs2;
if (eptr->op == TOKaddress)
eptr = ((AddrExp *)eptr)->e1;
Expression *agg1 = getAggregateFromPointer(eptr, &ofs1);
if (agg1->op != TOKstring && agg1->op != TOKarrayliteral)
{
error(loc, "cannot perform pointer arithmetic on non-arrays at compile time");
return EXP_CANT_INTERPRET;
}
ofs2 = e2->toInteger();
Type *pointee = ((TypePointer *)agg1->type)->next;
dinteger_t sz = pointee->size();
Expression *dollar = ArrayLength(Type::tsize_t, agg1);
assert(dollar != EXP_CANT_INTERPRET);
dinteger_t len = dollar->toInteger();
Expression *val = agg1;
TypeArray *tar = (TypeArray *)val->type;
dinteger_t indx = ofs1;
if (op == TOKadd || op == TOKaddass || op == TOKplusplus)
indx = indx + ofs2/sz;
else if (op == TOKmin || op == TOKminass || op == TOKminusminus)
indx -= ofs2/sz;
else
{
error(loc, "CTFE Internal compiler error: bad pointer operation");
return EXP_CANT_INTERPRET;
}
if (val->op != TOKarrayliteral && val->op != TOKstring)
{
error(loc, "CTFE Internal compiler error: pointer arithmetic %s", val->toChars());
return EXP_CANT_INTERPRET;
}
if (indx < 0 || indx > len)
{
error(loc, "cannot assign pointer to index %lld inside memory block [0..%lld]", indx, len);
return EXP_CANT_INTERPRET;
}
IntegerExp *ofs = new IntegerExp(loc, indx, Type::tsize_t);
IndexExp *ie = new IndexExp(loc, val, ofs);
ie->type = type;
return ie;
}
typedef Expression *(*fp_t)(Type *, Expression *, Expression *);
Expression *BinExp::interpretCommon(InterState *istate, CtfeGoal goal, fp_t fp)
{ Expression *e;
Expression *e1;
Expression *e2;
#if LOG
printf("BinExp::interpretCommon() %s\n", toChars());
#endif
if (this->e1->type->ty == Tpointer && this->e2->type->ty == Tpointer && op == TOKmin)
{
e1 = this->e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
e2 = this->e2->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e2))
return e2;
return pointerDifference(loc, type, e1, e2);
}
if (this->e1->type->ty == Tpointer && this->e2->type->isintegral())
{
e1 = this->e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
return pointerArithmetic(loc, op, type, e1, e2);
}
if (this->e2->type->ty == Tpointer && this->e1->type->isintegral() && op==TOKadd)
{
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
e2 = this->e2->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e2))
return e1;
return pointerArithmetic(loc, op, type, e2, e1);
}
if (this->e1->type->ty == Tpointer || this->e2->type->ty == Tpointer)
{
error("pointer expression %s cannot be interpreted at compile time", toChars());
return EXP_CANT_INTERPRET;
}
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->isConst() != 1)
goto Lcant;
e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
if (e2->isConst() != 1)
goto Lcant;
e = (*fp)(type, e1, e2);
if (e == EXP_CANT_INTERPRET)
error("%s cannot be interpreted at compile time", toChars());
return e;
Lcant:
return EXP_CANT_INTERPRET;
}
#define BIN_INTERPRET(op) \
Expression *op##Exp::interpret(InterState *istate, CtfeGoal goal) \
{ \
return interpretCommon(istate, goal, &op); \
}
BIN_INTERPRET(Add)
BIN_INTERPRET(Min)
BIN_INTERPRET(Mul)
BIN_INTERPRET(Div)
BIN_INTERPRET(Mod)
BIN_INTERPRET(Shl)
BIN_INTERPRET(Shr)
BIN_INTERPRET(Ushr)
BIN_INTERPRET(And)
BIN_INTERPRET(Or)
BIN_INTERPRET(Xor)
#if DMDV2
BIN_INTERPRET(Pow)
#endif
typedef Expression *(*fp2_t)(enum TOK, Type *, Expression *, Expression *);
// Return EXP_CANT_INTERPRET if they point to independent memory blocks
Expression *comparePointers(Loc loc, enum TOK op, Type *type, Expression *e1, Expression *e2)
{
dinteger_t ofs1, ofs2;
Expression *agg1 = getAggregateFromPointer(e1, &ofs1);
Expression *agg2 = getAggregateFromPointer(e2, &ofs2);
// Note that type painting can occur with VarExp, so we
// must compare the variables being pointed to.
if (agg1 == agg2 ||
(agg1->op == TOKvar && agg2->op == TOKvar &&
((VarExp *)agg1)->var == ((VarExp *)agg2)->var)
)
{
dinteger_t cm = ofs1 - ofs2;
dinteger_t n;
dinteger_t zero = 0;
switch(op)
{
case TOKlt: n = (ofs1 < ofs2); break;
case TOKle: n = (ofs1 <= ofs2); break;
case TOKgt: n = (ofs1 > ofs2); break;
case TOKge: n = (ofs1 >= ofs2); break;
case TOKidentity:
case TOKequal: n = (ofs1 == ofs2); break;
case TOKnotidentity:
case TOKnotequal: n = (ofs1 != ofs2); break;
default:
assert(0);
}
return new IntegerExp(loc, n, type);
}
int cmp;
if (agg1->op == TOKnull)
{
cmp = (agg2->op == TOKnull);
}
else if (agg2->op == TOKnull)
{
cmp = 0;
}
else
{
switch(op)
{
case TOKidentity:
case TOKequal:
case TOKnotidentity: // 'cmp' gets inverted below
case TOKnotequal:
cmp = 0;
break;
default:
return EXP_CANT_INTERPRET;
}
}
if (op == TOKnotidentity || op == TOKnotequal)
cmp ^= 1;
return new IntegerExp(loc, cmp, type);
}
Expression *ctfeIdentity(enum TOK op, Type *type, Expression *e1, Expression *e2)
{
if (e1->op == TOKclassreference || e2->op == TOKclassreference)
{
int cmp = 0;
if (e1->op == TOKclassreference && e2->op == TOKclassreference &&
((ClassReferenceExp *)e1)->value == ((ClassReferenceExp *)e2)->value)
cmp = 1;
if (op == TOKnotidentity || op == TOKnotequal)
cmp ^= 1;
return new IntegerExp(e1->loc, cmp, type);
}
return Identity(op, type, e1, e2);
}
Expression *BinExp::interpretCommon2(InterState *istate, CtfeGoal goal, fp2_t fp)
{ Expression *e;
Expression *e1;
Expression *e2;
#if LOG
printf("BinExp::interpretCommon2() %s\n", toChars());
#endif
if (this->e1->type->ty == Tpointer && this->e2->type->ty == Tpointer)
{
e1 = this->e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
e2 = this->e2->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e2))
return e2;
e = comparePointers(loc, op, type, e1, e2);
if (e == EXP_CANT_INTERPRET)
{
error("%s and %s point to independent memory blocks and "
"cannot be compared at compile time", this->e1->toChars(),
this->e2->toChars());
}
return e;
}
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKslice)
e1 = resolveSlice(e1);
if (e1->isConst() != 1 &&
e1->op != TOKnull &&
e1->op != TOKstring &&
e1->op != TOKarrayliteral &&
e1->op != TOKstructliteral &&
e1->op != TOKclassreference)
{
error("cannot compare %s at compile time", e1->toChars());
goto Lcant;
}
e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
if (e2->op == TOKslice)
e2 = resolveSlice(e2);
if (e2->isConst() != 1 &&
e2->op != TOKnull &&
e2->op != TOKstring &&
e2->op != TOKarrayliteral &&
e2->op != TOKstructliteral &&
e2->op != TOKclassreference)
{
error("cannot compare %s at compile time", e2->toChars());
goto Lcant;
}
e = (*fp)(op, type, e1, e2);
if (e == EXP_CANT_INTERPRET)
error("%s cannot be interpreted at compile time", toChars());
return e;
Lcant:
return EXP_CANT_INTERPRET;
}
#define BIN_INTERPRET2(op, opfunc) \
Expression *op##Exp::interpret(InterState *istate, CtfeGoal goal) \
{ \
return interpretCommon2(istate, goal, &opfunc); \
}
BIN_INTERPRET2(Equal, Equal)
BIN_INTERPRET2(Identity, ctfeIdentity)
BIN_INTERPRET2(Cmp, Cmp)
/* Helper functions for BinExp::interpretAssignCommon
*/
/***************************************
* Duplicate the elements array, then set field 'indexToChange' = newelem.
*/
Expressions *changeOneElement(Expressions *oldelems, size_t indexToChange, Expression *newelem)
{
Expressions *expsx = new Expressions();
++CtfeStatus::numArrayAllocs;
expsx->setDim(oldelems->dim);
for (size_t j = 0; j < expsx->dim; j++)
{
if (j == indexToChange)
expsx->tdata()[j] = newelem;
else
expsx->tdata()[j] = oldelems->tdata()[j];
}
return expsx;
}
// Create a new struct literal, which is the same as se except that se.field[offset] = elem
Expression * modifyStructField(Type *type, StructLiteralExp *se, size_t offset, Expression *newval)
{
int fieldi = se->getFieldIndex(newval->type, offset);
if (fieldi == -1)
return EXP_CANT_INTERPRET;
/* Create new struct literal reflecting updated fieldi
*/
Expressions *expsx = changeOneElement(se->elements, fieldi, newval);
StructLiteralExp * ee = new StructLiteralExp(se->loc, se->sd, expsx);
ee->type = se->type;
ee->ownedByCtfe = 1;
return ee;
}
/********************************
* Given an array literal arr (either arrayliteral, stringliteral, or assocArrayLiteral),
* set arr[index] = newval and return the new array.
*
*/
Expression *assignAssocArrayElement(Loc loc, AssocArrayLiteralExp *aae, Expression *index, Expression *newval)
{
/* Create new associative array literal reflecting updated key/value
*/
Expressions *keysx = aae->keys;
Expressions *valuesx = aae->values;
int updated = 0;
for (size_t j = valuesx->dim; j; )
{ j--;
Expression *ekey = aae->keys->tdata()[j];
Expression *ex = ctfeEqual(loc, TOKequal, Type::tbool, ekey, index);
if (exceptionOrCantInterpret(ex))
return ex;
if (ex->isBool(TRUE))
{ valuesx->tdata()[j] = newval;
updated = 1;
}
}
if (!updated)
{ // Append index/newval to keysx[]/valuesx[]
valuesx->push(newval);
keysx->push(index);
}
return newval;
}
// Return true if e is derived from UnaryExp.
// Consider moving this function into Expression.
UnaExp *isUnaExp(Expression *e)
{
switch (e->op)
{
case TOKdotvar:
case TOKindex:
case TOKslice:
case TOKcall:
case TOKdot:
case TOKdotti:
case TOKdottype:
case TOKcast:
return (UnaExp *)e;
default:
break;
}
return NULL;
}
// Returns the variable which is eventually modified, or NULL if an rvalue.
// thisval is the current value of 'this'.
VarDeclaration * findParentVar(Expression *e, Expression *thisval)
{
for (;;)
{
e = resolveReferences(e, thisval);
if (e->op == TOKvar)
break;
if (e->op == TOKindex)
e = ((IndexExp*)e)->e1;
else if (e->op == TOKdotvar)
e = ((DotVarExp *)e)->e1;
else if (e->op == TOKdotti)
e = ((DotTemplateInstanceExp *)e)->e1;
else if (e->op == TOKslice)
e = ((SliceExp*)e)->e1;
else
return NULL;
}
VarDeclaration *v = ((VarExp *)e)->var->isVarDeclaration();
assert(v);
return v;
}
// Given expr, which evaluates to an array/AA/string literal,
// return true if it needs to be copied
bool needToCopyLiteral(Expression *expr)
{
for (;;)
{
switch (expr->op)
{
case TOKarrayliteral:
return !((ArrayLiteralExp *)expr)->ownedByCtfe;
case TOKassocarrayliteral:
return !((AssocArrayLiteralExp *)expr)->ownedByCtfe;
case TOKstructliteral:
return !((StructLiteralExp *)expr)->ownedByCtfe;
case TOKstring:
case TOKthis:
case TOKvar:
return false;
case TOKassign:
return false;
case TOKindex:
case TOKdotvar:
case TOKslice:
case TOKcast:
expr = ((UnaExp *)expr)->e1;
continue;
case TOKcat:
return needToCopyLiteral(((BinExp *)expr)->e1) ||
needToCopyLiteral(((BinExp *)expr)->e2);
case TOKcatass:
expr = ((BinExp *)expr)->e2;
continue;
default:
return false;
}
}
}
Expressions *copyLiteralArray(Expressions *oldelems)
{
if (!oldelems)
return oldelems;
CtfeStatus::numArrayAllocs++;
Expressions *newelems = new Expressions();
newelems->setDim(oldelems->dim);
for (size_t i = 0; i < oldelems->dim; i++)
newelems->tdata()[i] = copyLiteral(oldelems->tdata()[i]);
return newelems;
}
// Make a copy of the ArrayLiteral, AALiteral, String, or StructLiteral.
// This value will be used for in-place modification.
Expression *copyLiteral(Expression *e)
{
if (e->op == TOKstring) // syntaxCopy doesn't make a copy for StringExp!
{
StringExp *se = (StringExp *)e;
unsigned char *s;
s = (unsigned char *)mem.calloc(se->len + 1, se->sz);
memcpy(s, se->string, se->len * se->sz);
StringExp *se2 = new StringExp(se->loc, s, se->len);
se2->committed = se->committed;
se2->postfix = se->postfix;
se2->type = se->type;
se2->sz = se->sz;
se2->ownedByCtfe = true;
return se2;
}
else if (e->op == TOKarrayliteral)
{
ArrayLiteralExp *ae = (ArrayLiteralExp *)e;
ArrayLiteralExp *r = new ArrayLiteralExp(e->loc,
copyLiteralArray(ae->elements));
r->type = e->type;
r->ownedByCtfe = true;
return r;
}
else if (e->op == TOKassocarrayliteral)
{
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)e;
AssocArrayLiteralExp *r = new AssocArrayLiteralExp(e->loc,
copyLiteralArray(aae->keys), copyLiteralArray(aae->values));
r->type = e->type;
r->ownedByCtfe = true;
return r;
}
/* syntaxCopy doesn't work for struct literals, because of a nasty special
* case: block assignment is permitted inside struct literals, eg,
* an int[4] array can be initialized with a single int.
*/
else if (e->op == TOKstructliteral)
{
StructLiteralExp *se = (StructLiteralExp *)e;
Expressions *oldelems = se->elements;
Expressions * newelems = new Expressions();
newelems->setDim(oldelems->dim);
for (size_t i = 0; i < newelems->dim; i++)
{
Expression *m = oldelems->tdata()[i];
// We need the struct definition to detect block assignment
AggregateDeclaration *sd = se->sd;
Dsymbol *s = sd->fields.tdata()[i];
VarDeclaration *v = s->isVarDeclaration();
assert(v);
// If it is a void assignment, use the default initializer
if (!m)
m = v->type->voidInitLiteral(v);
if (m->op == TOKslice)
m = resolveSlice(m);
if ((v->type->ty != m->type->ty) && v->type->ty == Tsarray)
{
// Block assignment from inside struct literals
TypeSArray *tsa = (TypeSArray *)v->type;
uinteger_t length = tsa->dim->toInteger();
m = createBlockDuplicatedArrayLiteral(e->loc, v->type, m, (size_t)length);
}
else if (v->type->ty != Tarray && v->type->ty!=Taarray) // NOTE: do not copy array references
m = copyLiteral(m);
newelems->tdata()[i] = m;
}
#if DMDV2
StructLiteralExp *r = new StructLiteralExp(e->loc, se->sd, newelems, se->stype);
#else
StructLiteralExp *r = new StructLiteralExp(e->loc, se->sd, newelems);
#endif
r->type = e->type;
r->ownedByCtfe = true;
return r;
}
else if (e->op == TOKfunction || e->op == TOKdelegate
|| e->op == TOKsymoff || e->op == TOKnull
|| e->op == TOKvar
|| e->op == TOKint64 || e->op == TOKfloat64
|| e->op == TOKchar || e->op == TOKcomplex80
|| e->op == TOKvoid)
{ // Simple value types
Expression *r = e->syntaxCopy();
r->type = e->type;
return r;
}
else if ( isPointer(e->type) )
{ // For pointers, we only do a shallow copy.
Expression *r;
if (e->op == TOKaddress)
r = new AddrExp(e->loc, ((AddrExp *)e)->e1);
else if (e->op == TOKindex)
r = new IndexExp(e->loc, ((IndexExp *)e)->e1, ((IndexExp *)e)->e2);
else if (e->op == TOKdotvar)
r = new DotVarExp(e->loc, ((DotVarExp *)e)->e1,
((DotVarExp *)e)->var
#if DMDV2
, ((DotVarExp *)e)->hasOverloads
#endif
);
else
assert(0);
r->type = e->type;
return r;
}
else if (e->op == TOKslice)
{ // Array slices only do a shallow copy
Expression *r = new SliceExp(e->loc, ((SliceExp *)e)->e1,
((SliceExp *)e)->lwr, ((SliceExp *)e)->upr);
r->type = e->type;
return r;
}
else if (e->op == TOKclassreference)
return new ClassReferenceExp(e->loc, ((ClassReferenceExp *)e)->value, e->type);
else
{
e->error("Internal Compiler Error: CTFE literal %s", e->toChars());
assert(0);
return e;
}
}
/* Deal with type painting.
* Type painting is a major nuisance: we can't just set
* e->type = type, because that would change the original literal.
* But, we can't simply copy the literal either, because that would change
* the values of any pointers.
*/
Expression *paintTypeOntoLiteral(Type *type, Expression *lit)
{
if (lit->type == type)
return lit;
Expression *e;
if (lit->op == TOKslice)
{
SliceExp *se = (SliceExp *)lit;
e = new SliceExp(lit->loc, se->e1, se->lwr, se->upr);
}
else if (lit->op == TOKindex)
{
IndexExp *ie = (IndexExp *)lit;
e = new IndexExp(lit->loc, ie->e1, ie->e2);
}
else if (lit->op == TOKarrayliteral)
{
e = new SliceExp(lit->loc, lit,
new IntegerExp(0, 0, Type::tsize_t), ArrayLength(Type::tsize_t, lit));
}
else if (lit->op == TOKstring)
{
// For strings, we need to introduce another level of indirection
e = new SliceExp(lit->loc, lit,
new IntegerExp(0, 0, Type::tsize_t), ArrayLength(Type::tsize_t, lit));
}
else if (lit->op == TOKassocarrayliteral)
{
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)lit;
// TODO: we should be creating a reference to this AAExp, not
// just a ref to the keys and values.
bool wasOwned = aae->ownedByCtfe;
aae = new AssocArrayLiteralExp(lit->loc, aae->keys, aae->values);
aae->ownedByCtfe = wasOwned;
e = aae;
}
else
{ // Can't type paint from struct to struct*; this needs another
// level of indirection
if (lit->op == TOKstructliteral && isPointer(type) )
lit->error("CTFE internal error painting %s", type->toChars());
e = copyLiteral(lit);
}
e->type = type;
return e;
}
Expression *ctfeCast(Loc loc, Type *type, Type *to, Expression *e)
{
if (e->op == TOKnull)
return paintTypeOntoLiteral(to, e);
if (e->op == TOKclassreference)
{ // Disallow reinterpreting class casts. Do this by ensuring that
// the original class can implicitly convert to the target class
ClassDeclaration *originalClass = ((ClassReferenceExp *)e)->originalClass();
if (originalClass->type->implicitConvTo(to))
return paintTypeOntoLiteral(to, e);
else
return new NullExp(loc, to);
}
Expression *r = Cast(type, to, e);
if (r == EXP_CANT_INTERPRET)
error(loc, "cannot cast %s to %s at compile time", e->toChars(), to->toChars());
if (e->op == TOKarrayliteral)
((ArrayLiteralExp *)e)->ownedByCtfe = true;
if (e->op == TOKstring)
((StringExp *)e)->ownedByCtfe = true;
return r;
}
/* Set dest = src, where both dest and src are container value literals
* (ie, struct literals, or static arrays (can be an array literal or a string)
* Assignment is recursively in-place.
* Purpose: any reference to a member of 'dest' will remain valid after the
* assignment.
*/
void assignInPlace(Expression *dest, Expression *src)
{
assert(dest->op == TOKstructliteral || dest->op == TOKarrayliteral ||
dest->op == TOKstring);
Expressions *oldelems;
Expressions *newelems;
if (dest->op == TOKstructliteral)
{
assert(dest->op == src->op);
oldelems = ((StructLiteralExp *)dest)->elements;
newelems = ((StructLiteralExp *)src)->elements;
}
else if (dest->op == TOKarrayliteral && src->op==TOKarrayliteral)
{
oldelems = ((ArrayLiteralExp *)dest)->elements;
newelems = ((ArrayLiteralExp *)src)->elements;
}
else if (dest->op == TOKstring && src->op == TOKstring)
{
sliceAssignStringFromString((StringExp *)dest, (StringExp *)src, 0);
return;
}
else if (dest->op == TOKarrayliteral && src->op == TOKstring)
{
sliceAssignArrayLiteralFromString((ArrayLiteralExp *)dest, (StringExp *)src, 0);
return;
}
else if (src->op == TOKarrayliteral && dest->op == TOKstring)
{
sliceAssignStringFromArrayLiteral((StringExp *)dest, (ArrayLiteralExp *)src, 0);
return;
}
else assert(0);
assert(oldelems->dim == newelems->dim);
for (size_t i= 0; i < oldelems->dim; ++i)
{
Expression *e = newelems->tdata()[i];
Expression *o = oldelems->tdata()[i];
if (e->op == TOKstructliteral)
{
assert(o->op == e->op);
assignInPlace(o, e);
}
else if (e->type->ty == Tsarray && o->type->ty == Tsarray && e->op != TOKvoid)
{
assignInPlace(o, e);
}
else
{
oldelems->tdata()[i] = newelems->tdata()[i];
}
}
}
void recursiveBlockAssign(ArrayLiteralExp *ae, Expression *val, bool wantRef)
{
assert( ae->type->ty == Tsarray || ae->type->ty == Tarray);
#if DMDV2
Type *desttype = ((TypeArray *)ae->type)->next->castMod(0);
bool directblk = (val->type->toBasetype()->castMod(0)) == desttype;
#else
Type *desttype = ((TypeArray *)ae->type)->next;
bool directblk = (val->type->toBasetype()) == desttype;
#endif
bool cow = !(val->op == TOKstructliteral || val->op == TOKarrayliteral
|| val->op == TOKstring);
for (size_t k = 0; k < ae->elements->dim; k++)
{
if (!directblk && ae->elements->tdata()[k]->op == TOKarrayliteral)
{
recursiveBlockAssign((ArrayLiteralExp *)ae->elements->tdata()[k], val, wantRef);
}
else
{
if (wantRef || cow)
ae->elements->tdata()[k] = val;
else
assignInPlace(ae->elements->tdata()[k], val);
}
}
}
Expression *BinExp::interpretAssignCommon(InterState *istate, CtfeGoal goal, fp_t fp, int post)
{
#if LOG
printf("BinExp::interpretAssignCommon() %s\n", toChars());
#endif
Expression *returnValue = EXP_CANT_INTERPRET;
Expression *e1 = this->e1;
if (!istate)
{
error("value of %s is not known at compile time", e1->toChars());
return returnValue;
}
++CtfeStatus::numAssignments;
/* Before we begin, we need to know if this is a reference assignment
* (dynamic array, AA, or class) or a value assignment.
* Determining this for slice assignments are tricky: we need to know
* if it is a block assignment (a[] = e) rather than a direct slice
* assignment (a[] = b[]). Note that initializers of multi-dimensional
* static arrays can have 2D block assignments (eg, int[7][7] x = 6;).
* So we need to recurse to determine if it is a block assignment.
*/
bool isBlockAssignment = false;
if (e1->op == TOKslice)
{
// a[] = e can have const e. So we compare the naked types.
Type *desttype = e1->type->toBasetype();
#if DMDV2
Type *srctype = e2->type->toBasetype()->castMod(0);
#else
Type *srctype = e2->type->toBasetype();
#endif
while ( desttype->ty == Tsarray || desttype->ty == Tarray)
{
desttype = ((TypeArray *)desttype)->next;
#if DMDV2
if (srctype == desttype->castMod(0))
#else
if (srctype == desttype)
#endif
{
isBlockAssignment = true;
break;
}
}
}
bool wantRef = false;
if (!fp && this->e1->type->toBasetype() == this->e2->type->toBasetype() &&
(e1->type->toBasetype()->ty == Tarray || isAssocArray(e1->type))
// e = *x is never a reference, because *x is always a value
&& this->e2->op != TOKstar
)
{
#if DMDV2
wantRef = true;
#else
/* D1 doesn't have const in the type system. But there is still a
* vestigal const in the form of static const variables.
* Problematic code like:
* const int [] x = [1,2,3];
* int [] y = x;
* can be dealt with by making this a non-ref assign (y = x.dup).
* Otherwise it's a big mess.
*/
VarDeclaration * targetVar = findParentVar(e2, istate->localThis);
if (!(targetVar && targetVar->isConst()))
wantRef = true;
// slice assignment of static arrays is not reference assignment
if ((e1->op==TOKslice) && ((SliceExp *)e1)->e1->type->ty == Tsarray)
wantRef = false;
#endif
// If it is assignment from a ref parameter, it's not a ref assignment
if (this->e2->op == TOKvar)
{
VarDeclaration *v = ((VarExp *)this->e2)->var->isVarDeclaration();
if (v && (v->storage_class & (STCref | STCout)))
wantRef = false;
}
}
if (isBlockAssignment && (e2->type->toBasetype()->ty == Tarray || e2->type->toBasetype()->ty == Tsarray))
{
wantRef = true;
}
// If it is a construction of a ref variable, it is a ref assignment
if (op == TOKconstruct && this->e1->op==TOKvar
&& ((VarExp*)this->e1)->var->storage_class & STCref)
{
wantRef = true;
}
if (fp)
{
while (e1->op == TOKcast)
{ CastExp *ce = (CastExp *)e1;
e1 = ce->e1;
}
}
if (exceptionOrCantInterpret(e1))
return e1;
// First, deal with this = e; and call() = e;
if (e1->op == TOKthis)
{
e1 = istate->localThis;
}
if (e1->op == TOKcall)
{
bool oldWaiting = istate->awaitingLvalueReturn;
istate->awaitingLvalueReturn = true;
e1 = e1->interpret(istate);
istate->awaitingLvalueReturn = oldWaiting;
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKarrayliteral || e1->op == TOKstring)
{
// f() = e2, when f returns an array, is always a slice assignment.
// Convert into arr[0..arr.length] = e2
e1 = new SliceExp(loc, e1,
new IntegerExp(0, 0, Type::tsize_t),
ArrayLength(Type::tsize_t, e1));
e1->type = type;
}
}
if (e1->op == TOKstar)
{
e1 = e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
if (!(e1->op == TOKvar || e1->op == TOKdotvar || e1->op == TOKindex
|| e1->op == TOKslice))
{
error("cannot dereference invalid pointer %s",
this->e1->toChars());
return EXP_CANT_INTERPRET;
}
}
if (!(e1->op == TOKarraylength || e1->op == TOKvar || e1->op == TOKdotvar
|| e1->op == TOKindex || e1->op == TOKslice))
{
error("CTFE internal error: unsupported assignment %s", toChars());
return EXP_CANT_INTERPRET;
}
Expression * newval = NULL;
if (!wantRef)
{ // We need to treat pointers specially, because TOKsymoff can be used to
// return a value OR a pointer
assert(e1);
assert(e1->type);
if ( isPointer(e1->type) && (e2->op == TOKsymoff || e2->op==TOKaddress || e2->op==TOKvar))
newval = this->e2->interpret(istate, ctfeNeedLvalue);
else
newval = this->e2->interpret(istate);
if (exceptionOrCantInterpret(newval))
return newval;
}
// ----------------------------------------------------
// Deal with read-modify-write assignments.
// Set 'newval' to the final assignment value
// Also determine the return value (except for slice
// assignments, which are more complicated)
// ----------------------------------------------------
if (fp || e1->op == TOKarraylength)
{
// If it isn't a simple assignment, we need the existing value
Expression * oldval = e1->interpret(istate);
if (exceptionOrCantInterpret(oldval))
return oldval;
while (oldval->op == TOKvar)
{
oldval = resolveReferences(oldval, istate->localThis);
oldval = oldval->interpret(istate);
if (exceptionOrCantInterpret(oldval))
return oldval;
}
if (fp)
{
// ~= can create new values (see bug 6052)
if (op == TOKcatass)
{
// We need to dup it. We can skip this if it's a dynamic array,
// because it gets copied later anyway
if (newval->type->ty != Tarray)
newval = copyLiteral(newval);
if (newval->op == TOKslice)
newval = resolveSlice(newval);
// It becomes a reference assignment
wantRef = true;
}
if (oldval->op == TOKslice)
oldval = resolveSlice(oldval);
if (this->e1->type->ty == Tpointer && this->e2->type->isintegral()
&& (op==TOKaddass || op == TOKminass ||
op == TOKplusplus || op == TOKminusminus))
{
oldval = this->e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(oldval))
return oldval;
newval = this->e2->interpret(istate);
if (exceptionOrCantInterpret(newval))
return newval;
newval = pointerArithmetic(loc, op, type, oldval, newval);
}
else if (this->e1->type->ty == Tpointer)
{
error("pointer expression %s cannot be interpreted at compile time", toChars());
return EXP_CANT_INTERPRET;
}
else
{
newval = (*fp)(type, oldval, newval);
}
if (newval == EXP_CANT_INTERPRET)
{
error("Cannot interpret %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
if (exceptionOrCantInterpret(newval))
return newval;
// Determine the return value
returnValue = ctfeCast(loc, type, type, post ? oldval : newval);
if (exceptionOrCantInterpret(returnValue))
return returnValue;
}
else
returnValue = newval;
if (e1->op == TOKarraylength)
{
size_t oldlen = oldval->toInteger();
size_t newlen = newval->toInteger();
if (oldlen == newlen) // no change required -- we're done!
return returnValue;
// Now change the assignment from arr.length = n into arr = newval
e1 = ((ArrayLengthExp *)e1)->e1;
if (oldlen != 0)
{ // Get the old array literal.
oldval = e1->interpret(istate);
while (oldval->op == TOKvar)
{ oldval = resolveReferences(oldval, istate->localThis);
oldval = oldval->interpret(istate);
}
}
if (oldval->op == TOKslice)
oldval = resolveSlice(oldval);
Type *t = e1->type->toBasetype();
if (t->ty == Tarray)
{
Type *elemType= NULL;
elemType = ((TypeArray *)t)->next;
assert(elemType);
Expression *defaultElem = elemType->defaultInitLiteral(loc);
Expressions *elements = new Expressions();
elements->setDim(newlen);
size_t copylen = oldlen < newlen ? oldlen : newlen;
if (oldval->op == TOKstring)
{
StringExp *oldse = (StringExp *)oldval;
unsigned char *s = (unsigned char *)mem.calloc(newlen + 1, oldse->sz);
memcpy(s, oldse->string, copylen * oldse->sz);
unsigned defaultValue = (unsigned)(defaultElem->toInteger());
for (size_t elemi = copylen; elemi < newlen; ++elemi)
{
switch (oldse->sz)
{
case 1: s[elemi] = defaultValue; break;
case 2: ((unsigned short *)s)[elemi] = defaultValue; break;
case 4: ((unsigned *)s)[elemi] = defaultValue; break;
default: assert(0);
}
}
StringExp *se = new StringExp(loc, s, newlen);
se->type = t;
se->sz = oldse->sz;
se->committed = oldse->committed;
se->ownedByCtfe = true;
newval = se;
}
else
{
if (oldlen !=0)
assert(oldval->op == TOKarrayliteral);
ArrayLiteralExp *ae = (ArrayLiteralExp *)oldval;
for (size_t i = 0; i < copylen; i++)
elements->tdata()[i] = ae->elements->tdata()[i];
if (elemType->ty == Tstruct || elemType->ty == Tsarray)
{ /* If it is an aggregate literal representing a value type,
* we need to create a unique copy for each element
*/
for (size_t i = copylen; i < newlen; i++)
elements->tdata()[i] = copyLiteral(defaultElem);
}
else
{
for (size_t i = copylen; i < newlen; i++)
elements->tdata()[i] = defaultElem;
}
ArrayLiteralExp *aae = new ArrayLiteralExp(0, elements);
aae->type = t;
newval = aae;
aae->ownedByCtfe = true;
}
// We have changed it into a reference assignment
// Note that returnValue is still the new length.
wantRef = true;
if (e1->op == TOKstar)
{ // arr.length+=n becomes (t=&arr, *(t).length=*(t).length+n);
e1 = e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
}
}
else
{
error("%s is not yet supported at compile time", toChars());
return EXP_CANT_INTERPRET;
}
}
}
else if (!wantRef && e1->op != TOKslice)
{ /* Look for special case of struct being initialized with 0.
*/
if (type->toBasetype()->ty == Tstruct && newval->op == TOKint64)
{
newval = type->defaultInitLiteral(loc);
if (newval->op != TOKstructliteral)
{
error("nested structs with constructors are not yet supported in CTFE (Bug 6419)");
return EXP_CANT_INTERPRET;
}
}
newval = ctfeCast(loc, type, type, newval);
if (exceptionOrCantInterpret(newval))
return newval;
returnValue = newval;
}
if (exceptionOrCantInterpret(newval))
return newval;
// -------------------------------------------------
// Make sure destination can be modified
// -------------------------------------------------
// Make sure we're not trying to modify a global or static variable
// We do this by locating the ultimate parent variable which gets modified.
VarDeclaration * ultimateVar = findParentVar(e1, istate->localThis);
if (ultimateVar && ultimateVar->isDataseg() && !ultimateVar->isCTFE())
{ // Can't modify global or static data
error("%s cannot be modified at compile time", ultimateVar->toChars());
return EXP_CANT_INTERPRET;
}
e1 = resolveReferences(e1, istate->localThis);
// Unless we have a simple var assignment, we're
// only modifying part of the variable. So we need to make sure
// that the parent variable exists.
if (e1->op != TOKvar && ultimateVar && !ultimateVar->getValue())
ultimateVar->setValue(copyLiteral(ultimateVar->type->defaultInitLiteral(loc)));
// ---------------------------------------
// Deal with reference assignment
// (We already have 'newval' for arraylength operations)
// ---------------------------------------
if (wantRef && !fp && this->e1->op != TOKarraylength)
{
newval = this->e2->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(newval))
return newval;
// If it is an assignment from a array function parameter passed by
// reference, resolve the reference. (This should NOT happen for
// non-reference types).
if (newval->op == TOKvar && (newval->type->ty == Tarray ||
newval->type->ty == Tclass))
{
newval = newval->interpret(istate);
}
if (newval->op == TOKassocarrayliteral || newval->op == TOKstring ||
newval->op==TOKarrayliteral)
{
if (needToCopyLiteral(newval))
newval = copyLiteral(newval);
}
returnValue = newval;
}
// ---------------------------------------
// Deal with AA index assignment
// ---------------------------------------
/* This needs special treatment if the AA doesn't exist yet.
* There are two special cases:
* (1) If the AA is itself an index of another AA, we may need to create
* multiple nested AA literals before we can insert the new value.
* (2) If the ultimate AA is null, no insertion happens at all. Instead, we
* create nested AA literals, and change it into a assignment.
*/
if (e1->op == TOKindex && ((IndexExp *)e1)->e1->type->toBasetype()->ty == Taarray)
{
IndexExp *ie = (IndexExp *)e1;
int depth = 0; // how many nested AA indices are there?
while (ie->e1->op == TOKindex && ((IndexExp *)ie->e1)->e1->type->toBasetype()->ty == Taarray)
{
ie = (IndexExp *)ie->e1;
++depth;
}
Expression *aggregate = resolveReferences(ie->e1, istate->localThis);
Expression *oldagg = aggregate;
// Get the AA to be modified. (We do an LvalueRef interpret, unless it
// is a simple ref parameter -- in which case, we just want the value)
aggregate = aggregate->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(aggregate))
return aggregate;
if (aggregate->op == TOKassocarrayliteral)
{ // Normal case, ultimate parent AA already exists
// We need to walk from the deepest index up, checking that an AA literal
// already exists on each level.
Expression *index = ((IndexExp *)e1)->e2->interpret(istate);
if (exceptionOrCantInterpret(index))
return index;
if (index->op == TOKslice) // only happens with AA assignment
index = resolveSlice(index);
AssocArrayLiteralExp *existingAA = (AssocArrayLiteralExp *)aggregate;
while (depth > 0)
{ // Walk the syntax tree to find the indexExp at this depth
IndexExp *xe = (IndexExp *)e1;
for (int d= 0; d < depth; ++d)
xe = (IndexExp *)xe->e1;
Expression *indx = xe->e2->interpret(istate);
if (exceptionOrCantInterpret(indx))
return indx;
if (indx->op == TOKslice) // only happens with AA assignment
indx = resolveSlice(indx);
// Look up this index in it up in the existing AA, to get the next level of AA.
AssocArrayLiteralExp *newAA = (AssocArrayLiteralExp *)findKeyInAA(loc, existingAA, indx);
if (exceptionOrCantInterpret(newAA))
return newAA;
if (!newAA)
{ // Doesn't exist yet, create an empty AA...
Expressions *valuesx = new Expressions();
Expressions *keysx = new Expressions();
newAA = new AssocArrayLiteralExp(loc, keysx, valuesx);
newAA->type = xe->type;
newAA->ownedByCtfe = true;
//... and insert it into the existing AA.
existingAA->keys->push(indx);
existingAA->values->push(newAA);
}
existingAA = newAA;
--depth;
}
if (assignAssocArrayElement(loc, existingAA, index, newval) == EXP_CANT_INTERPRET)
return EXP_CANT_INTERPRET;
return returnValue;
}
else
{ /* The AA is currently null. 'aggregate' is actually a reference to
* whatever contains it. It could be anything: var, dotvarexp, ...
* We rewrite the assignment from: aggregate[i][j] = newval;
* into: aggregate = [i:[j: newval]];
*/
while (e1->op == TOKindex && ((IndexExp *)e1)->e1->type->toBasetype()->ty == Taarray)
{
Expression *index = ((IndexExp *)e1)->e2->interpret(istate);
if (exceptionOrCantInterpret(index))
return index;
if (index->op == TOKslice) // only happens with AA assignment
index = resolveSlice(index);
Expressions *valuesx = new Expressions();
Expressions *keysx = new Expressions();
valuesx->push(newval);
keysx->push(index);
AssocArrayLiteralExp *newaae = new AssocArrayLiteralExp(loc, keysx, valuesx);
newaae->ownedByCtfe = true;
newaae->type = e1->type;
newval = newaae;
e1 = ((IndexExp *)e1)->e1;
}
// We must return to the original aggregate, in case it was a reference
wantRef = true;
e1 = oldagg;
// fall through -- let the normal assignment logic take care of it
}
}
// ---------------------------------------
// Deal with dotvar expressions
// ---------------------------------------
// Because structs are not reference types, dotvar expressions can be
// collapsed into a single assignment.
if (!wantRef && e1->op == TOKdotvar)
{
// Strip of all of the leading dotvars, unless we started with a call
// or a ref parameter
// (in which case, we already have the lvalue).
if (this->e1->op != TOKcall && !(this->e1->op==TOKvar
&& ((VarExp*)this->e1)->var->storage_class & (STCref | STCout)))
e1 = e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKstructliteral && newval->op == TOKstructliteral)
{
assignInPlace(e1, newval);
return returnValue;
}
}
#if LOGASSIGN
if (wantRef)
printf("REF ASSIGN: %s=%s\n", e1->toChars(), newval->toChars());
else
printf("ASSIGN: %s=%s\n", e1->toChars(), newval->toChars());
showCtfeExpr(newval);
#endif
/* Assignment to variable of the form:
* v = newval
*/
if (e1->op == TOKvar)
{
VarExp *ve = (VarExp *)e1;
VarDeclaration *v = ve->var->isVarDeclaration();
if (wantRef)
{
v->setValueNull();
v->setValue(newval);
}
else if (e1->type->toBasetype()->ty == Tstruct)
{
// In-place modification
if (newval->op != TOKstructliteral)
{
error("CTFE internal error assigning struct");
return EXP_CANT_INTERPRET;
}
newval = copyLiteral(newval);
if (v->getValue())
assignInPlace(v->getValue(), newval);
else
v->setValue(newval);
}
else
{
TY tyE1 = e1->type->toBasetype()->ty;
if (tyE1 == Tarray || tyE1 == Taarray)
{ // arr op= arr
v->setValue(newval);
}
else
{
v->setValue(newval);
}
}
}
else if (e1->op == TOKdotvar)
{
/* Assignment to member variable of the form:
* e.v = newval
*/
Expression *exx = ((DotVarExp *)e1)->e1;
if (wantRef && exx->op != TOKstructliteral)
{
exx = exx->interpret(istate);
if (exceptionOrCantInterpret(exx))
return exx;
}
if (exx->op != TOKstructliteral && exx->op != TOKclassreference)
{
error("CTFE internal error: Dotvar assignment");
return EXP_CANT_INTERPRET;
}
VarDeclaration *member = ((DotVarExp *)e1)->var->isVarDeclaration();
if (!member)
{
error("CTFE internal error: Dotvar assignment");
return EXP_CANT_INTERPRET;
}
StructLiteralExp *se = exx->op == TOKstructliteral
? (StructLiteralExp *)exx
: ((ClassReferenceExp *)exx)->value;
int fieldi = exx->op == TOKstructliteral
? findFieldIndexByName(se->sd, member)
: ((ClassReferenceExp *)exx)->findFieldIndexByName(member);
if (fieldi == -1)
{
error("CTFE internal error: cannot find field %s in %s", member->toChars(), exx->toChars());
return EXP_CANT_INTERPRET;
}
assert(fieldi >= 0 && fieldi < se->elements->dim);
// If it's a union, set all other members of this union to void
if (exx->op == TOKstructliteral)
{
assert(se->sd);
int unionStart = se->sd->firstFieldInUnion(fieldi);
int unionSize = se->sd->numFieldsInUnion(fieldi);
for(int i = unionStart; i < unionStart + unionSize; ++i)
{ if (i == fieldi)
continue;
Expression **el = &se->elements->tdata()[i];
if ((*el)->op != TOKvoid)
*el = (*el)->type->voidInitLiteral(member);
}
}
if (newval->op == TOKstructliteral)
assignInPlace(se->elements->tdata()[fieldi], newval);
else
se->elements->tdata()[fieldi] = newval;
return returnValue;
}
else if (e1->op == TOKindex)
{
/* Assignment to array element of the form:
* aggregate[i] = newval
* aggregate is not AA (AAs were dealt with already).
*/
IndexExp *ie = (IndexExp *)e1;
assert(ie->e1->type->toBasetype()->ty != Taarray);
uinteger_t destarraylen = 0;
// Set the $ variable, and find the array literal to modify
if (ie->e1->type->toBasetype()->ty != Tpointer)
{
Expression *oldval = ie->e1->interpret(istate);
if (oldval->op == TOKnull)
{
error("cannot index null array %s", ie->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (oldval->op != TOKarrayliteral && oldval->op != TOKstring
&& oldval->op != TOKslice)
{
error("cannot determine length of %s at compile time",
ie->e1->toChars());
return EXP_CANT_INTERPRET;
}
destarraylen = resolveArrayLength(oldval);
if (ie->lengthVar)
{
IntegerExp *dollarExp = new IntegerExp(loc, destarraylen, Type::tsize_t);
ctfeStack.push(ie->lengthVar);
ie->lengthVar->setValue(dollarExp);
}
}
Expression *index = ie->e2->interpret(istate);
if (ie->lengthVar)
ctfeStack.pop(ie->lengthVar); // $ is defined only inside []
if (exceptionOrCantInterpret(index))
return index;
assert (index->op != TOKslice); // only happens with AA assignment
ArrayLiteralExp *existingAE = NULL;
StringExp *existingSE = NULL;
Expression *aggregate = resolveReferences(ie->e1, istate->localThis);
// Set the index to modify, and check that it is in range
dinteger_t indexToModify = index->toInteger();
if (ie->e1->type->toBasetype()->ty == Tpointer)
{
dinteger_t ofs;
aggregate = aggregate->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(aggregate))
return aggregate;
if (aggregate->op == TOKnull)
{
error("cannot index through null pointer %s", ie->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (aggregate->op == TOKint64)
{
error("cannot index through invalid pointer %s of value %s",
ie->e1->toChars(), aggregate->toChars());
return EXP_CANT_INTERPRET;
}
aggregate = getAggregateFromPointer(aggregate, &ofs);
indexToModify += ofs;
if (aggregate->op != TOKslice && aggregate->op != TOKstring &&
aggregate->op != TOKarrayliteral && aggregate->op != TOKassocarrayliteral)
{
if (indexToModify != 0)
{
error("pointer index [%lld] lies outside memory block [0..1]", indexToModify);
return EXP_CANT_INTERPRET;
}
// It is equivalent to *aggregate = newval.
// Aggregate could be varexp, a dotvar, ...
// TODO: we could support this
error("indexed assignment of non-array pointers is not yet supported at compile time; use *%s = %s instead",
ie->e1->toChars(), e2->toChars());
return EXP_CANT_INTERPRET;
}
destarraylen = resolveArrayLength(aggregate);
}
if (indexToModify >= destarraylen)
{
error("array index %lld is out of bounds [0..%lld]", indexToModify,
destarraylen);
return EXP_CANT_INTERPRET;
}
/* The only possible indexable LValue aggregates are array literals, and
* slices of array literals.
*/
if (aggregate->op == TOKindex || aggregate->op == TOKdotvar ||
aggregate->op == TOKslice || aggregate->op == TOKcall ||
aggregate->op == TOKstar)
{
Expression *origagg = aggregate;
aggregate = aggregate->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(aggregate))
return aggregate;
// The array could be an index of an AA. Resolve it if so.
if (aggregate->op == TOKindex &&
((IndexExp *)aggregate)->e1->op == TOKassocarrayliteral)
{
IndexExp *ix = (IndexExp *)aggregate;
aggregate = findKeyInAA(loc, (AssocArrayLiteralExp *)ix->e1, ix->e2);
if (!aggregate)
{
error("key %s not found in associative array %s",
ix->e2->toChars(), ix->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (exceptionOrCantInterpret(aggregate))
return aggregate;
}
}
if (aggregate->op == TOKvar)
{
VarExp *ve = (VarExp *)aggregate;
VarDeclaration *v = ve->var->isVarDeclaration();
aggregate = v->getValue();
if (aggregate->op == TOKnull)
{
// This would be a runtime segfault
error("cannot index null array %s", v->toChars());
return EXP_CANT_INTERPRET;
}
}
if (aggregate->op == TOKslice)
{
SliceExp *sexp = (SliceExp *)aggregate;
aggregate = sexp->e1;
Expression *lwr = sexp->lwr->interpret(istate);
indexToModify += lwr->toInteger();
}
if (aggregate->op == TOKarrayliteral)
existingAE = (ArrayLiteralExp *)aggregate;
else if (aggregate->op == TOKstring)
existingSE = (StringExp *)aggregate;
else
{
error("CTFE internal compiler error %s", aggregate->toChars());
return EXP_CANT_INTERPRET;
}
if (!wantRef && newval->op == TOKslice)
{
newval = resolveSlice(newval);
if (newval == EXP_CANT_INTERPRET)
{
error("Compiler error: CTFE index assign %s", toChars());
assert(0);
}
}
if (wantRef && newval->op == TOKindex
&& ((IndexExp *)newval)->e1 == aggregate)
{ // It's a circular reference, resolve it now
newval = newval->interpret(istate);
}
if (existingAE)
{
if (newval->op == TOKstructliteral)
assignInPlace((Expression *)(existingAE->elements->tdata()[indexToModify]), newval);
else
existingAE->elements->tdata()[indexToModify] = newval;
return returnValue;
}
if (existingSE)
{
unsigned char *s = (unsigned char *)existingSE->string;
if (!existingSE->ownedByCtfe)
{
error("cannot modify read-only string literal %s", ie->e1->toChars());
return EXP_CANT_INTERPRET;
}
unsigned value = newval->toInteger();
switch (existingSE->sz)
{
case 1: s[indexToModify] = value; break;
case 2: ((unsigned short *)s)[indexToModify] = value; break;
case 4: ((unsigned *)s)[indexToModify] = value; break;
default:
assert(0);
break;
}
return returnValue;
}
else
{
error("Index assignment %s is not yet supported in CTFE ", toChars());
return EXP_CANT_INTERPRET;
}
return returnValue;
}
else if (e1->op == TOKslice)
{
// ------------------------------
// aggregate[] = newval
// aggregate[low..upp] = newval
// ------------------------------
SliceExp * sexp = (SliceExp *)e1;
// Set the $ variable
Expression *oldval = sexp->e1;
bool assignmentToSlicedPointer = false;
if (isPointer(oldval->type))
{ // Slicing a pointer
oldval = oldval->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(oldval))
return oldval;
dinteger_t ofs;
oldval = getAggregateFromPointer(oldval, &ofs);
assignmentToSlicedPointer = true;
} else
oldval = oldval->interpret(istate);
if (oldval->op != TOKarrayliteral && oldval->op != TOKstring
&& oldval->op != TOKslice && oldval->op != TOKnull)
{
if (assignmentToSlicedPointer)
{
error("pointer %s cannot be sliced at compile time (it does not point to an array)",
sexp->e1->toChars());
}
else
error("CTFE ICE: cannot resolve array length");
return EXP_CANT_INTERPRET;
}
uinteger_t dollar = resolveArrayLength(oldval);
if (sexp->lengthVar)
{
Expression *arraylen = new IntegerExp(loc, dollar, Type::tsize_t);
ctfeStack.push(sexp->lengthVar);
sexp->lengthVar->setValue(arraylen);
}
Expression *upper = NULL;
Expression *lower = NULL;
if (sexp->upr)
upper = sexp->upr->interpret(istate);
if (exceptionOrCantInterpret(upper))
{
if (sexp->lengthVar)
ctfeStack.pop(sexp->lengthVar); // $ is defined only in [L..U]
return upper;
}
if (sexp->lwr)
lower = sexp->lwr->interpret(istate);
if (sexp->lengthVar)
ctfeStack.pop(sexp->lengthVar); // $ is defined only in [L..U]
if (exceptionOrCantInterpret(lower))
return lower;
size_t dim = dollar;
size_t upperbound = upper ? upper->toInteger() : dim;
int lowerbound = lower ? lower->toInteger() : 0;
if (!assignmentToSlicedPointer && (((int)lowerbound < 0) || (upperbound > dim)))
{
error("Array bounds [0..%d] exceeded in slice [%d..%d]",
dim, lowerbound, upperbound);
return EXP_CANT_INTERPRET;
}
if (upperbound == lowerbound)
return newval;
Expression *aggregate = resolveReferences(((SliceExp *)e1)->e1, istate->localThis);
dinteger_t firstIndex = lowerbound;
ArrayLiteralExp *existingAE = NULL;
StringExp *existingSE = NULL;
/* The only possible slicable LValue aggregates are array literals,
* and slices of array literals.
*/
if (aggregate->op == TOKindex || aggregate->op == TOKdotvar ||
aggregate->op == TOKslice ||
aggregate->op == TOKstar || aggregate->op == TOKcall)
{
aggregate = aggregate->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(aggregate))
return aggregate;
// The array could be an index of an AA. Resolve it if so.
if (aggregate->op == TOKindex &&
((IndexExp *)aggregate)->e1->op == TOKassocarrayliteral)
{
IndexExp *ix = (IndexExp *)aggregate;
aggregate = findKeyInAA(loc, (AssocArrayLiteralExp *)ix->e1, ix->e2);
if (!aggregate)
{
error("key %s not found in associative array %s",
ix->e2->toChars(), ix->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (exceptionOrCantInterpret(aggregate))
return aggregate;
}
}
if (aggregate->op == TOKvar)
{
VarExp *ve = (VarExp *)(aggregate);
VarDeclaration *v = ve->var->isVarDeclaration();
aggregate = v->getValue();
}
if (aggregate->op == TOKslice)
{ // Slice of a slice --> change the bounds
SliceExp *sexpold = (SliceExp *)aggregate;
dinteger_t hi = upperbound + sexpold->lwr->toInteger();
firstIndex = lowerbound + sexpold->lwr->toInteger();
if (hi > sexpold->upr->toInteger())
{
error("slice [%d..%d] exceeds array bounds [0..%lld]",
lowerbound, upperbound,
sexpold->upr->toInteger() - sexpold->lwr->toInteger());
return EXP_CANT_INTERPRET;
}
aggregate = sexpold->e1;
}
if ( isPointer(aggregate->type) )
{ // Slicing a pointer --> change the bounds
aggregate = sexp->e1->interpret(istate, ctfeNeedLvalue);
dinteger_t ofs;
aggregate = getAggregateFromPointer(aggregate, &ofs);
if (aggregate->op == TOKnull)
{
error("cannot slice null pointer %s", sexp->e1->toChars());
return EXP_CANT_INTERPRET;
}
dinteger_t hi = upperbound + ofs;
firstIndex = lowerbound + ofs;
if (firstIndex < 0 || hi > dim)
{
error("slice [lld..%lld] exceeds memory block bounds [0..%lld]",
firstIndex, hi, dim);
return EXP_CANT_INTERPRET;
}
}
if (aggregate->op == TOKarrayliteral)
existingAE = (ArrayLiteralExp *)aggregate;
else if (aggregate->op == TOKstring)
existingSE = (StringExp *)aggregate;
if (existingSE && !existingSE->ownedByCtfe)
{ error("cannot modify read-only string literal %s", sexp->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (!wantRef && newval->op == TOKslice)
{
newval = resolveSlice(newval);
if (newval == EXP_CANT_INTERPRET)
{
error("Compiler error: CTFE slice %s", toChars());
assert(0);
}
}
if (wantRef && newval->op == TOKindex
&& ((IndexExp *)newval)->e1 == aggregate)
{ // It's a circular reference, resolve it now
newval = newval->interpret(istate);
}
// For slice assignment, we check that the lengths match.
size_t srclen = 0;
if (newval->op == TOKarrayliteral)
srclen = ((ArrayLiteralExp *)newval)->elements->dim;
else if (newval->op == TOKstring)
srclen = ((StringExp *)newval)->len;
if (!isBlockAssignment && srclen != (upperbound - lowerbound))
{
error("Array length mismatch assigning [0..%d] to [%d..%d]", srclen, lowerbound, upperbound);
return EXP_CANT_INTERPRET;
}
if (!isBlockAssignment && newval->op == TOKarrayliteral && existingAE)
{
Expressions *oldelems = existingAE->elements;
Expressions *newelems = ((ArrayLiteralExp *)newval)->elements;
for (size_t j = 0; j < newelems->dim; j++)
{
oldelems->tdata()[j + firstIndex] = newelems->tdata()[j];
}
return newval;
}
else if (newval->op == TOKstring && existingSE)
{
sliceAssignStringFromString((StringExp *)existingSE, (StringExp *)newval, firstIndex);
return newval;
}
else if (newval->op == TOKstring && existingAE
&& existingAE->type->isString())
{ /* Mixed slice: it was initialized as an array literal of chars.
* Now a slice of it is being set with a string.
*/
sliceAssignArrayLiteralFromString(existingAE, (StringExp *)newval, firstIndex);
return newval;
}
else if (newval->op == TOKarrayliteral && existingSE)
{ /* Mixed slice: it was initialized as a string literal.
* Now a slice of it is being set with an array literal.
*/
sliceAssignStringFromArrayLiteral(existingSE, (ArrayLiteralExp *)newval, firstIndex);
return newval;
}
else if (existingSE)
{ // String literal block slice assign
unsigned value = newval->toInteger();
unsigned char *s = (unsigned char *)existingSE->string;
for (size_t j = 0; j < upperbound-lowerbound; j++)
{
switch (existingSE->sz)
{
case 1: s[j+firstIndex] = value; break;
case 2: ((unsigned short *)s)[j+firstIndex] = value; break;
case 4: ((unsigned *)s)[j+firstIndex] = value; break;
default:
assert(0);
break;
}
}
if (goal == ctfeNeedNothing)
return NULL; // avoid creating an unused literal
SliceExp *retslice = new SliceExp(loc, existingSE,
new IntegerExp(loc, firstIndex, Type::tsize_t),
new IntegerExp(loc, firstIndex + upperbound-lowerbound, Type::tsize_t));
retslice->type = this->type;
return retslice->interpret(istate);
}
else if (existingAE)
{
/* Block assignment, initialization of static arrays
* x[] = e
* x may be a multidimensional static array. (Note that this
* only happens with array literals, never with strings).
*/
Expressions * w = existingAE->elements;
assert( existingAE->type->ty == Tsarray ||
existingAE->type->ty == Tarray);
#if DMDV2
Type *desttype = ((TypeArray *)existingAE->type)->next->castMod(0);
bool directblk = (e2->type->toBasetype()->castMod(0)) == desttype;
#else
Type *desttype = ((TypeArray *)existingAE->type)->next;
bool directblk = (e2->type->toBasetype()) == desttype;
#endif
bool cow = !(newval->op == TOKstructliteral || newval->op == TOKarrayliteral
|| newval->op == TOKstring);
for (size_t j = 0; j < upperbound-lowerbound; j++)
{
if (!directblk)
// Multidimensional array block assign
recursiveBlockAssign((ArrayLiteralExp *)w->tdata()[j+firstIndex], newval, wantRef);
else
{
if (wantRef || cow)
existingAE->elements->tdata()[j+firstIndex] = newval;
else
assignInPlace(existingAE->elements->tdata()[j+firstIndex], newval);
}
}
if (goal == ctfeNeedNothing)
return NULL; // avoid creating an unused literal
SliceExp *retslice = new SliceExp(loc, existingAE,
new IntegerExp(loc, firstIndex, Type::tsize_t),
new IntegerExp(loc, firstIndex + upperbound-lowerbound, Type::tsize_t));
retslice->type = this->type;
return retslice->interpret(istate);
}
else
error("Slice operation %s cannot be evaluated at compile time", toChars());
}
else
{
error("%s cannot be evaluated at compile time", toChars());
}
return returnValue;
}
Expression *AssignExp::interpret(InterState *istate, CtfeGoal goal)
{
return interpretAssignCommon(istate, goal, NULL);
}
#define BIN_ASSIGN_INTERPRET_CTFE(op, ctfeOp) \
Expression *op##AssignExp::interpret(InterState *istate, CtfeGoal goal) \
{ \
return interpretAssignCommon(istate, goal, &ctfeOp); \
}
#define BIN_ASSIGN_INTERPRET(op) BIN_ASSIGN_INTERPRET_CTFE(op, op)
BIN_ASSIGN_INTERPRET(Add)
BIN_ASSIGN_INTERPRET(Min)
BIN_ASSIGN_INTERPRET_CTFE(Cat, ctfeCat)
BIN_ASSIGN_INTERPRET(Mul)
BIN_ASSIGN_INTERPRET(Div)
BIN_ASSIGN_INTERPRET(Mod)
BIN_ASSIGN_INTERPRET(Shl)
BIN_ASSIGN_INTERPRET(Shr)
BIN_ASSIGN_INTERPRET(Ushr)
BIN_ASSIGN_INTERPRET(And)
BIN_ASSIGN_INTERPRET(Or)
BIN_ASSIGN_INTERPRET(Xor)
#if DMDV2
BIN_ASSIGN_INTERPRET(Pow)
#endif
Expression *PostExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("PostExp::interpret() %s\n", toChars());
#endif
Expression *e;
if (op == TOKplusplus)
e = interpretAssignCommon(istate, goal, &Add, 1);
else
e = interpretAssignCommon(istate, goal, &Min, 1);
#if LOG
if (e == EXP_CANT_INTERPRET)
printf("PostExp::interpret() CANT\n");
#endif
return e;
}
Expression *AndAndExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("AndAndExp::interpret() %s\n", toChars());
#endif
Expression *e = e1->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
int result;
if (e != EXP_CANT_INTERPRET)
{
if (e->isBool(FALSE))
result = 0;
else if (isTrueBool(e))
{
e = e2->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (e == EXP_VOID_INTERPRET)
{
assert(type->ty == Tvoid);
return NULL;
}
if (e != EXP_CANT_INTERPRET)
{
if (e->isBool(FALSE))
result = 0;
else if (isTrueBool(e))
result = 1;
else
{
error("%s does not evaluate to a boolean", e->toChars());
e = EXP_CANT_INTERPRET;
}
}
}
else
{
error("%s cannot be interpreted as a boolean", e->toChars());
e = EXP_CANT_INTERPRET;
}
}
if (e != EXP_CANT_INTERPRET && goal != ctfeNeedNothing)
e = new IntegerExp(loc, result, type);
return e;
}
Expression *OrOrExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("OrOrExp::interpret() %s\n", toChars());
#endif
Expression *e = e1->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
int result;
if (e != EXP_CANT_INTERPRET)
{
if (isTrueBool(e))
result = 1;
else if (e->isBool(FALSE))
{
e = e2->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (e == EXP_VOID_INTERPRET)
{
assert(type->ty == Tvoid);
return NULL;
}
if (e != EXP_CANT_INTERPRET)
{
if (e->isBool(FALSE))
result = 0;
else if (isTrueBool(e))
result = 1;
else
{
error("%s cannot be interpreted as a boolean", e->toChars());
e = EXP_CANT_INTERPRET;
}
}
}
else
{
error("%s cannot be interpreted as a boolean", e->toChars());
e = EXP_CANT_INTERPRET;
}
}
if (e != EXP_CANT_INTERPRET && goal != ctfeNeedNothing)
e = new IntegerExp(loc, result, type);
return e;
}
// Print a stack trace, starting from callingExp which called fd.
// To shorten the stack trace, try to detect recursion.
void showCtfeBackTrace(InterState *istate, CallExp * callingExp, FuncDeclaration *fd)
{
if (CtfeStatus::stackTraceCallsToSuppress > 0)
{
--CtfeStatus::stackTraceCallsToSuppress;
return;
}
errorSupplemental(callingExp->loc, "called from here: %s", callingExp->toChars());
// Quit if it's not worth trying to compress the stack trace
if (CtfeStatus::callDepth < 6 || global.params.verbose)
return;
// Recursion happens if the current function already exists in the call stack.
int numToSuppress = 0;
int recurseCount = 0;
int depthSoFar = 0;
InterState *lastRecurse = istate;
for (InterState * cur = istate; cur; cur = cur->caller)
{
if (cur->fd == fd)
{ ++recurseCount;
numToSuppress = depthSoFar;
lastRecurse = cur;
}
++depthSoFar;
}
// We need at least three calls to the same function, to make compression worthwhile
if (recurseCount < 2)
return;
// We found a useful recursion. Print all the calls involved in the recursion
errorSupplemental(fd->loc, "%d recursive calls to function %s", recurseCount, fd->toChars());
for (InterState *cur = istate; cur->fd != fd; cur = cur->caller)
{
errorSupplemental(cur->fd->loc, "recursively called from function %s", cur->fd->toChars());
}
// We probably didn't enter the recursion in this function.
// Go deeper to find the real beginning.
InterState * cur = istate;
while (lastRecurse->caller && cur->fd == lastRecurse->caller->fd)
{
cur = cur->caller;
lastRecurse = lastRecurse->caller;
++numToSuppress;
}
CtfeStatus::stackTraceCallsToSuppress = numToSuppress;
}
Expression *CallExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e = EXP_CANT_INTERPRET;
#if LOG
printf("CallExp::interpret() %s\n", toChars());
#endif
Expression * pthis = NULL;
FuncDeclaration *fd = NULL;
Expression *ecall = e1;
if (ecall->op == TOKcall)
{
ecall = e1->interpret(istate);
if (exceptionOrCantInterpret(ecall))
return ecall;
}
if (ecall->op == TOKstar)
{ // Calling a function pointer
Expression * pe = ((PtrExp*)ecall)->e1;
if (pe->op == TOKvar) {
VarDeclaration *vd = ((VarExp *)((PtrExp*)ecall)->e1)->var->isVarDeclaration();
if (vd && vd->getValue() && vd->getValue()->op == TOKsymoff)
fd = ((SymOffExp *)vd->getValue())->var->isFuncDeclaration();
else
{
ecall = getVarExp(loc, istate, vd, goal);
if (exceptionOrCantInterpret(ecall))
return ecall;
if (ecall->op == TOKsymoff)
fd = ((SymOffExp *)ecall)->var->isFuncDeclaration();
}
}
else if (pe->op == TOKsymoff)
fd = ((SymOffExp *)pe)->var->isFuncDeclaration();
else
ecall = ((PtrExp*)ecall)->e1->interpret(istate);
}
if (exceptionOrCantInterpret(ecall))
return ecall;
if (ecall->op == TOKindex)
{ ecall = e1->interpret(istate);
if (exceptionOrCantInterpret(ecall))
return ecall;
}
if (ecall->op == TOKdotvar && !((DotVarExp*)ecall)->var->isFuncDeclaration())
{ ecall = e1->interpret(istate);
if (exceptionOrCantInterpret(ecall))
return ecall;
}
if (ecall->op == TOKdotvar)
{ // Calling a member function
pthis = ((DotVarExp*)e1)->e1;
fd = ((DotVarExp*)e1)->var->isFuncDeclaration();
}
else if (ecall->op == TOKvar)
{
VarDeclaration *vd = ((VarExp *)ecall)->var->isVarDeclaration();
if (vd && vd->getValue())
ecall = vd->getValue();
else // Calling a function
fd = ((VarExp *)e1)->var->isFuncDeclaration();
}
if (ecall->op == TOKdelegate)
{ // Calling a delegate
fd = ((DelegateExp *)ecall)->func;
pthis = ((DelegateExp *)ecall)->e1;
}
else if (ecall->op == TOKfunction)
{ // Calling a delegate literal
fd = ((FuncExp*)ecall)->fd;
}
else if (ecall->op == TOKstar && ((PtrExp*)ecall)->e1->op==TOKfunction)
{ // Calling a function literal
fd = ((FuncExp*)((PtrExp*)ecall)->e1)->fd;
}
TypeFunction *tf = fd ? (TypeFunction *)(fd->type) : NULL;
if (!tf)
{ // DAC: This should never happen, it's an internal compiler error.
//printf("ecall=%s %d %d\n", ecall->toChars(), ecall->op, TOKcall);
if (ecall->op == TOKidentifier)
error("cannot evaluate %s at compile time. Circular reference?", toChars());
else
error("CTFE internal error: cannot evaluate %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
if (!fd)
{
error("cannot evaluate %s at compile time", toChars());
return EXP_CANT_INTERPRET;
}
if (pthis)
{ // Member function call
Expression *oldpthis;
if (pthis->op == TOKthis)
{
pthis = istate ? istate->localThis : NULL;
oldpthis = pthis;
}
else
{
if (pthis->op == TOKcomma)
pthis = pthis->interpret(istate);
if (exceptionOrCantInterpret(pthis))
return pthis;
// Evaluate 'this'
oldpthis = pthis;
if (pthis->op != TOKvar)
pthis = pthis->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(pthis))
return pthis;
}
if (fd->isVirtual())
{ // Make a virtual function call.
Expression *thisval = pthis;
if (pthis->op == TOKvar)
{ assert(((VarExp*)thisval)->var->isVarDeclaration());
thisval = ((VarExp*)thisval)->var->isVarDeclaration()->getValue();
}
// Get the function from the vtable of the original class
ClassDeclaration *cd;
if (thisval && thisval->op == TOKnull)
{
error("function call through null class reference %s", pthis->toChars());
return EXP_CANT_INTERPRET;
}
if (oldpthis->op == TOKsuper)
{ assert(oldpthis->type->ty == Tclass);
cd = ((TypeClass *)oldpthis->type)->sym;
}
else
{
assert(thisval && thisval->op == TOKclassreference);
cd = ((ClassReferenceExp *)thisval)->originalClass();
}
// We can't just use the vtable index to look it up, because
// vtables for interfaces don't get populated until the glue layer.
fd = cd->findFunc(fd->ident, (TypeFunction *)fd->type);
assert(fd);
}
}
if (fd && fd->semanticRun >= PASSsemantic3done && fd->semantic3Errors)
{
error("CTFE failed because of previous errors in %s", fd->toChars());
return EXP_CANT_INTERPRET;
}
// Check for built-in functions
Expression *eresult = evaluateIfBuiltin(istate, loc, fd, arguments, pthis);
if (eresult)
return eresult;
// Inline .dup. Special case because it needs the return type.
if (!pthis && fd->ident == Id::adDup && arguments && arguments->dim == 2)
{
e = arguments->tdata()[1];
e = e->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (e != EXP_CANT_INTERPRET)
{
if (e->op == TOKslice)
e= resolveSlice(e);
e = paintTypeOntoLiteral(type, copyLiteral(e));
}
return e;
}
if (!fd->fbody)
{
error("%s cannot be interpreted at compile time,"
" because it has no available source code", fd->toChars());
return EXP_CANT_INTERPRET;
}
eresult = fd->interpret(istate, arguments, pthis);
if (eresult == EXP_CANT_INTERPRET)
{ // Print a stack trace.
if (!global.gag)
showCtfeBackTrace(istate, this, fd);
}
else if (eresult == EXP_VOID_INTERPRET)
;
else
eresult->loc = loc;
return eresult;
}
Expression *CommaExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("CommaExp::interpret() %s\n", toChars());
#endif
CommaExp * firstComma = this;
while (firstComma->e1->op == TOKcomma)
firstComma = (CommaExp *)firstComma->e1;
// If it creates a variable, and there's no context for
// the variable to be created in, we need to create one now.
InterState istateComma;
if (!istate && firstComma->e1->op == TOKdeclaration)
{
ctfeStack.startFrame();
istate = &istateComma;
}
Expression *e = EXP_CANT_INTERPRET;
// If the comma returns a temporary variable, it needs to be an lvalue
// (this is particularly important for struct constructors)
if (e1->op == TOKdeclaration && e2->op == TOKvar
&& ((DeclarationExp *)e1)->declaration == ((VarExp*)e2)->var
&& ((VarExp*)e2)->var->storage_class & STCctfe) // same as Expression::isTemp
{
VarExp* ve = (VarExp *)e2;
VarDeclaration *v = ve->var->isVarDeclaration();
ctfeStack.push(v);
if (!v->init && !v->getValue())
{
v->setValue(copyLiteral(v->type->defaultInitLiteral(loc)));
}
if (!v->getValue()) {
Expression *newval = v->init->toExpression();
// Bug 4027. Copy constructors are a weird case where the
// initializer is a void function (the variable is modified
// through a reference parameter instead).
newval = newval->interpret(istate);
if (exceptionOrCantInterpret(newval))
{
if (istate == &istateComma)
ctfeStack.endFrame(0);
return newval;
}
if (newval != EXP_VOID_INTERPRET)
{
// v isn't necessarily null.
v->setValueWithoutChecking(copyLiteral(newval));
}
}
if (goal == ctfeNeedLvalue || goal == ctfeNeedLvalueRef)
e = e2;
else
e = e2->interpret(istate, goal);
}
else
{
e = e1->interpret(istate, ctfeNeedNothing);
if (!exceptionOrCantInterpret(e))
e = e2->interpret(istate, goal);
}
// If we created a temporary stack frame, end it now.
if (istate == &istateComma)
ctfeStack.endFrame(0);
return e;
}
Expression *CondExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("CondExp::interpret() %s\n", toChars());
#endif
Expression *e;
if ( isPointer(econd->type) )
{
e = econd->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e))
return e;
if (e->op != TOKnull)
e = new IntegerExp(loc, 1, Type::tbool);
}
else
e = econd->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
if (isTrueBool(e))
e = e1->interpret(istate, goal);
else if (e->isBool(FALSE))
e = e2->interpret(istate, goal);
else
{
error("%s does not evaluate to boolean result at compile time",
econd->toChars());
e = EXP_CANT_INTERPRET;
}
return e;
}
Expression *ArrayLengthExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e;
Expression *e1;
#if LOG
printf("ArrayLengthExp::interpret() %s\n", toChars());
#endif
e1 = this->e1->interpret(istate);
assert(e1);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKstring || e1->op == TOKarrayliteral || e1->op == TOKslice
|| e1->op == TOKassocarrayliteral || e1->op == TOKnull)
{
e = new IntegerExp(loc, resolveArrayLength(e1), type);
}
else
{
error("%s cannot be evaluated at compile time", toChars());
return EXP_CANT_INTERPRET;
}
return e;
}
/* Given an AA literal 'ae', and a key 'e2':
* Return ae[e2] if present, or NULL if not found.
* Return EXP_CANT_INTERPRET on error.
*/
Expression *findKeyInAA(Loc loc, AssocArrayLiteralExp *ae, Expression *e2)
{
/* Search the keys backwards, in case there are duplicate keys
*/
for (size_t i = ae->keys->dim; i;)
{
i--;
Expression *ekey = ae->keys->tdata()[i];
Expression *ex = ctfeEqual(loc, TOKequal, Type::tbool, ekey, e2);
if (ex == EXP_CANT_INTERPRET)
return ex;
if (ex->isBool(TRUE))
{
return ae->values->tdata()[i];
}
}
return NULL;
}
/* Same as for constfold.Index, except that it only works for static arrays,
* dynamic arrays, and strings. We know that e1 is an
* interpreted CTFE expression, so it cannot have side-effects.
*/
Expression *ctfeIndex(Loc loc, Type *type, Expression *e1, uinteger_t indx)
{ //printf("ctfeIndex(e1 = %s)\n", e1->toChars());
assert(e1->type);
if (e1->op == TOKstring)
{ StringExp *es1 = (StringExp *)e1;
if (indx >= es1->len)
{
error(loc, "string index %ju is out of bounds [0 .. %zu]", indx, es1->len);
return EXP_CANT_INTERPRET;
}
else
return new IntegerExp(loc, es1->charAt(indx), type);
}
assert(e1->op == TOKarrayliteral);
ArrayLiteralExp *ale = (ArrayLiteralExp *)e1;
if (indx >= ale->elements->dim)
{
error(loc, "array index %ju is out of bounds %s[0 .. %u]", indx, e1->toChars(), ale->elements->dim);
return EXP_CANT_INTERPRET;
}
Expression *e = ale->elements->tdata()[indx];
return paintTypeOntoLiteral(type, e);
}
Expression *IndexExp::interpret(InterState *istate, CtfeGoal goal)
{
Expression *e1 = NULL;
Expression *e2;
#if LOG
printf("IndexExp::interpret() %s\n", toChars());
#endif
if (this->e1->type->toBasetype()->ty == Tpointer)
{
// Indexing a pointer. Note that there is no $ in this case.
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
dinteger_t indx = e2->toInteger();
dinteger_t ofs;
Expression *agg = getAggregateFromPointer(e1, &ofs);
if (agg->op == TOKnull)
{
error("cannot index null pointer %s", this->e1->toChars());
return EXP_CANT_INTERPRET;
}
if ( agg->op == TOKarrayliteral || agg->op == TOKstring)
{
dinteger_t len = ArrayLength(Type::tsize_t, agg)->toInteger();
Type *pointee = ((TypePointer *)agg->type)->next;
if ((indx + ofs) < 0 || (indx+ofs) > len)
{
error("pointer index [%lld] exceeds allocated memory block [0..%lld]",
indx+ofs, len);
return EXP_CANT_INTERPRET;
}
return ctfeIndex(loc, type, agg, indx+ofs);
}
else
{ // Pointer to a non-array variable
if ((indx + ofs) != 0)
{
error("pointer index [%lld] lies outside memory block [0..1]",
indx+ofs);
return EXP_CANT_INTERPRET;
}
return agg->interpret(istate);
}
}
e1 = this->e1;
if (!(e1->op == TOKarrayliteral && ((ArrayLiteralExp *)e1)->ownedByCtfe))
e1 = e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKnull)
{
if (goal == ctfeNeedLvalue && e1->type->ty == Taarray)
return paintTypeOntoLiteral(type, e1);
error("cannot index null array %s", this->e1->toChars());
return EXP_CANT_INTERPRET;
}
/* Set the $ variable.
* Note that foreach uses indexing but doesn't need $
*/
if (lengthVar && (e1->op == TOKstring || e1->op == TOKarrayliteral
|| e1->op == TOKslice))
{
uinteger_t dollar = resolveArrayLength(e1);
Expression *dollarExp = new IntegerExp(loc, dollar, Type::tsize_t);
ctfeStack.push(lengthVar);
lengthVar->setValue(dollarExp);
}
e2 = this->e2->interpret(istate);
if (lengthVar)
ctfeStack.pop(lengthVar); // $ is defined only inside []
if (exceptionOrCantInterpret(e2))
return e2;
if (e1->op == TOKslice && e2->op == TOKint64)
{
// Simplify index of slice: agg[lwr..upr][indx] --> agg[indx']
uinteger_t indx = e2->toInteger();
uinteger_t ilo = ((SliceExp *)e1)->lwr->toInteger();
uinteger_t iup = ((SliceExp *)e1)->upr->toInteger();
if (indx > iup - ilo)
{
error("index %llu exceeds array length %llu", indx, iup - ilo);
return EXP_CANT_INTERPRET;
}
indx += ilo;
e1 = ((SliceExp *)e1)->e1;
e2 = new IntegerExp(e2->loc, indx, e2->type);
}
Expression *e = NULL;
if ((goal == ctfeNeedLvalue && type->ty != Taarray && type->ty != Tarray
&& type->ty != Tsarray && type->ty != Tstruct && type->ty != Tclass)
|| (goal == ctfeNeedLvalueRef && type->ty != Tsarray && type->ty != Tstruct)
)
{ // Pointer or reference of a scalar type
e = new IndexExp(loc, e1, e2);
e->type = type;
return e;
}
if (e1->op == TOKassocarrayliteral)
{
if (e2->op == TOKslice)
e2 = resolveSlice(e2);
e = findKeyInAA(loc, (AssocArrayLiteralExp *)e1, e2);
if (!e)
{
error("key %s not found in associative array %s",
e2->toChars(), this->e1->toChars());
return EXP_CANT_INTERPRET;
}
}
else
{
if (e2->op != TOKint64)
{
e1->error("CTFE internal error: non-integral index [%s]", this->e2->toChars());
return EXP_CANT_INTERPRET;
}
e = ctfeIndex(loc, type, e1, e2->toInteger());
}
if (exceptionOrCantInterpret(e))
return e;
if (goal == ctfeNeedRvalue && (e->op == TOKslice || e->op == TOKdotvar))
e = e->interpret(istate);
if (goal == ctfeNeedRvalue && e->op == TOKvoid)
{
error("%s is used before initialized", toChars());
errorSupplemental(e->loc, "originally uninitialized here");
return EXP_CANT_INTERPRET;
}
e = paintTypeOntoLiteral(type, e);
return e;
}
Expression *SliceExp::interpret(InterState *istate, CtfeGoal goal)
{
Expression *e1;
Expression *lwr;
Expression *upr;
#if LOG
printf("SliceExp::interpret() %s\n", toChars());
#endif
if (this->e1->type->toBasetype()->ty == Tpointer)
{
// Slicing a pointer. Note that there is no $ in this case.
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKint64)
{
error("cannot slice invalid pointer %s of value %s",
this->e1->toChars(), e1->toChars());
return EXP_CANT_INTERPRET;
}
/* Evaluate lower and upper bounds of slice
*/
lwr = this->lwr->interpret(istate);
if (exceptionOrCantInterpret(lwr))
return lwr;
upr = this->upr->interpret(istate);
if (exceptionOrCantInterpret(upr))
return upr;
uinteger_t ilwr;
uinteger_t iupr;
ilwr = lwr->toInteger();
iupr = upr->toInteger();
Expression *e;
dinteger_t ofs;
Expression *agg = getAggregateFromPointer(e1, &ofs);
if (agg->op == TOKnull)
{
if (iupr == ilwr)
{
e = new NullExp(loc);
e->type = type;
return e;
}
error("cannot slice null pointer %s", this->e1->toChars());
return EXP_CANT_INTERPRET;
}
if (agg->op != TOKarrayliteral && agg->op != TOKstring)
{
error("pointer %s cannot be sliced at compile time (it does not point to an array)",
this->e1->toChars());
return EXP_CANT_INTERPRET;
}
assert(agg->op == TOKarrayliteral || agg->op == TOKstring);
dinteger_t len = ArrayLength(Type::tsize_t, agg)->toInteger();
Type *pointee = ((TypePointer *)agg->type)->next;
if ((ilwr + ofs) < 0 || (iupr+ofs) > (len + 1) || iupr < ilwr)
{
error("pointer slice [%lld..%lld] exceeds allocated memory block [0..%lld]",
ilwr+ofs, iupr+ofs, len);
return EXP_CANT_INTERPRET;
}
e = new SliceExp(loc, agg, lwr, upr);
e->type = type;
return e;
}
if (goal == ctfeNeedRvalue && this->e1->op == TOKstring)
e1 = this->e1; // Will get duplicated anyway
else
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKvar)
e1 = e1->interpret(istate);
if (!this->lwr)
{
if (goal == ctfeNeedLvalue || goal == ctfeNeedLvalueRef)
return e1;
return paintTypeOntoLiteral(type, e1);
}
/* Set the $ variable
*/
if (e1->op != TOKarrayliteral && e1->op != TOKstring &&
e1->op != TOKnull && e1->op != TOKslice)
{
error("Cannot determine length of %s at compile time", e1->toChars());
return EXP_CANT_INTERPRET;
}
uinteger_t dollar = resolveArrayLength(e1);
if (lengthVar)
{
IntegerExp *dollarExp = new IntegerExp(loc, dollar, Type::tsize_t);
ctfeStack.push(lengthVar);
lengthVar->setValue(dollarExp);
}
/* Evaluate lower and upper bounds of slice
*/
lwr = this->lwr->interpret(istate);
if (exceptionOrCantInterpret(lwr))
{
if (lengthVar)
ctfeStack.pop(lengthVar);; // $ is defined only inside [L..U]
return lwr;
}
upr = this->upr->interpret(istate);
if (lengthVar)
ctfeStack.pop(lengthVar); // $ is defined only inside [L..U]
if (exceptionOrCantInterpret(upr))
return upr;
Expression *e;
uinteger_t ilwr;
uinteger_t iupr;
ilwr = lwr->toInteger();
iupr = upr->toInteger();
if (e1->op == TOKnull)
{
if (ilwr== 0 && iupr == 0)
return e1;
e1->error("slice [%llu..%llu] is out of bounds", ilwr, iupr);
return EXP_CANT_INTERPRET;
}
if (e1->op == TOKslice)
{
SliceExp *se = (SliceExp *)e1;
// Simplify slice of slice:
// aggregate[lo1..up1][lwr..upr] ---> aggregate[lwr'..upr']
uinteger_t lo1 = se->lwr->toInteger();
uinteger_t up1 = se->upr->toInteger();
if (ilwr > iupr || iupr > up1 - lo1)
{
error("slice[%llu..%llu] exceeds array bounds[%llu..%llu]",
ilwr, iupr, lo1, up1);
return EXP_CANT_INTERPRET;
}
ilwr += lo1;
iupr += lo1;
e = new SliceExp(loc, se->e1,
new IntegerExp(loc, ilwr, lwr->type),
new IntegerExp(loc, iupr, upr->type));
e->type = type;
return e;
}
if (e1->op == TOKarrayliteral
|| e1->op == TOKstring)
{
if (iupr < ilwr || ilwr < 0 || iupr > dollar)
{
error("slice [%lld..%lld] exceeds array bounds [0..%lld]",
ilwr, iupr, dollar);
return EXP_CANT_INTERPRET;
}
}
e = new SliceExp(loc, e1, lwr, upr);
e->type = type;
return e;
}
Expression *InExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e = EXP_CANT_INTERPRET;
#if LOG
printf("InExp::interpret() %s\n", toChars());
#endif
Expression *e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
Expression *e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
if (e2->op == TOKnull)
return new NullExp(loc, type);
if (e2->op != TOKassocarrayliteral)
{
error(" %s cannot be interpreted at compile time", toChars());
return EXP_CANT_INTERPRET;
}
if (e1->op == TOKslice)
e1 = resolveSlice(e1);
e = findKeyInAA(loc, (AssocArrayLiteralExp *)e2, e1);
if (exceptionOrCantInterpret(e))
return e;
if (!e)
return new NullExp(loc, type);
e = new IndexExp(loc, e2, e1);
e->type = type;
return e;
}
Expression *CatExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e;
Expression *e1;
Expression *e2;
#if LOG
printf("CatExp::interpret() %s\n", toChars());
#endif
e1 = this->e1->interpret(istate);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op == TOKslice)
{
e1 = resolveSlice(e1);
}
e2 = this->e2->interpret(istate);
if (exceptionOrCantInterpret(e2))
return e2;
if (e2->op == TOKslice)
e2 = resolveSlice(e2);
e = ctfeCat(type, e1, e2);
if (e == EXP_CANT_INTERPRET)
error("%s cannot be interpreted at compile time", toChars());
// We know we still own it, because we interpreted both e1 and e2
if (e->op == TOKarrayliteral)
((ArrayLiteralExp *)e)->ownedByCtfe = true;
if (e->op == TOKstring)
((StringExp *)e)->ownedByCtfe = true;
return e;
}
// Return true if t is a pointer (not a function pointer)
bool isPointer(Type *t)
{
Type * tb = t->toBasetype();
return tb->ty == Tpointer && tb->nextOf()->ty != Tfunction;
}
// Return true if t is an AA, or AssociativeArray!(key, value)
bool isAssocArray(Type *t)
{
t = t->toBasetype();
if (t->ty == Taarray)
return true;
#if DMDV2
if (t->ty != Tstruct)
return false;
StructDeclaration *sym = ((TypeStruct *)t)->sym;
if (sym->ident == Id::AssociativeArray && sym->parent &&
sym->parent->parent &&
sym->parent->parent->ident == Id::object)
{
return true;
}
#endif
return false;
}
// Given a template AA type, extract the corresponding built-in AA type
TypeAArray *toBuiltinAAType(Type *t)
{
t = t->toBasetype();
if (t->ty == Taarray)
return (TypeAArray *)t;
#if DMDV2
assert(t->ty == Tstruct);
StructDeclaration *sym = ((TypeStruct *)t)->sym;
assert(sym->ident == Id::AssociativeArray);
TemplateInstance *tinst = sym->parent->isTemplateInstance();
assert(tinst);
return new TypeAArray((Type *)(tinst->tiargs->tdata()[1]), (Type *)(tinst->tiargs->tdata()[0]));
#else
assert(0);
return NULL;
#endif
}
Expression *CastExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e;
Expression *e1;
#if LOG
printf("CastExp::interpret() %s\n", toChars());
#endif
e1 = this->e1->interpret(istate, goal);
if (exceptionOrCantInterpret(e1))
return e1;
// If the expression has been cast to void, do nothing.
if (to->ty == Tvoid && goal == ctfeNeedNothing)
return e1;
if (to->ty == Tpointer && e1->op != TOKnull)
{
Type *pointee = ((TypePointer *)type)->next;
// Implement special cases of normally-unsafe casts
#if DMDV2
if (pointee->ty == Taarray && e1->op == TOKaddress
&& isAssocArray(((AddrExp*)e1)->e1->type))
{ // cast from template AA pointer to true AA pointer is OK.
return paintTypeOntoLiteral(to, e1);
}
#endif
if (e1->op == TOKint64)
{ // Happens with Windows HANDLEs, for example.
return paintTypeOntoLiteral(to, e1);
}
bool castBackFromVoid = false;
if (e1->type->ty == Tarray || e1->type->ty == Tsarray || e1->type->ty == Tpointer)
{
// Check for unsupported type painting operations
// For slices, we need the type being sliced,
// since it may have already been type painted
Type *elemtype = e1->type->nextOf();
if (e1->op == TOKslice)
elemtype = ((SliceExp *)e1)->e1->type->nextOf();
// Allow casts from X* to void *, and X** to void** for any X.
// But don't allow cast from X* to void**.
// So, we strip all matching * from source and target to find X.
// Allow casts to X* from void* only if the 'void' was originally an X;
// we check this later on.
Type *ultimatePointee = pointee;
Type *ultimateSrc = elemtype;
while (ultimatePointee->ty == Tpointer && ultimateSrc->ty == Tpointer)
{
ultimatePointee = ultimatePointee->nextOf();
ultimateSrc = ultimateSrc->nextOf();
}
if (ultimatePointee->ty != Tvoid && ultimateSrc->ty != Tvoid
&& !isSafePointerCast(elemtype, pointee))
{
error("reinterpreting cast from %s* to %s* is not supported in CTFE",
elemtype->toChars(), pointee->toChars());
return EXP_CANT_INTERPRET;
}
if (ultimateSrc->ty == Tvoid)
castBackFromVoid = true;
}
if (e1->op == TOKslice)
{
if ( ((SliceExp *)e1)->e1->op == TOKnull)
{
return paintTypeOntoLiteral(type, ((SliceExp *)e1)->e1);
}
e = new IndexExp(loc, ((SliceExp *)e1)->e1, ((SliceExp *)e1)->lwr);
e->type = type;
return e;
}
if (e1->op == TOKarrayliteral || e1->op == TOKstring)
{
e = new IndexExp(loc, e1, new IntegerExp(loc, 0, Type::tsize_t));
e->type = type;
return e;
}
if (e1->op == TOKindex && ((IndexExp *)e1)->e1->type != e1->type)
{ // type painting operation
IndexExp *ie = (IndexExp *)e1;
e = new IndexExp(e1->loc, ie->e1, ie->e2);
if (castBackFromVoid)
{
// get the original type. For strings, it's just the type...
Type *origType = ie->e1->type->nextOf();
// ..but for arrays of type void*, it's the type of the element
Expression *xx = NULL;
if (ie->e1->op == TOKarrayliteral && ie->e2->op == TOKint64)
{ ArrayLiteralExp *ale = (ArrayLiteralExp *)ie->e1;
uinteger_t indx = ie->e2->toInteger();
if (indx < ale->elements->dim)
xx = ale->elements->tdata()[indx];
}
if (xx && xx->op == TOKindex)
origType = ((IndexExp *)xx)->e1->type->nextOf();
else if (xx && xx->op == TOKaddress)
origType= ((AddrExp *)xx)->e1->type;
else if (xx && xx->op == TOKvar)
origType = ((VarExp *)xx)->var->type;
if (!isSafePointerCast(origType, pointee))
{
error("using void* to reinterpret cast from %s* to %s* is not supported in CTFE",
origType->toChars(), pointee->toChars());
return EXP_CANT_INTERPRET;
}
}
e->type = type;
return e;
}
if (e1->op == TOKaddress)
{
Type *origType = ((AddrExp *)e1)->type;
if (isSafePointerCast(origType, pointee))
{
e = new AddrExp(loc, ((AddrExp *)e1)->e1);
e->type = type;
return e;
}
}
if (e1->op == TOKvar)
{ // type painting operation
Type *origType = ((VarExp *)e1)->var->type;
if (castBackFromVoid && !isSafePointerCast(origType, pointee))
{
error("using void* to reinterpret cast from %s* to %s* is not supported in CTFE",
origType->toChars(), pointee->toChars());
return EXP_CANT_INTERPRET;
}
e = new VarExp(loc, ((VarExp *)e1)->var);
e->type = type;
return e;
}
// Check if we have a null pointer (eg, inside a struct)
e1 = e1->interpret(istate);
if (e1->op != TOKnull)
{
error("pointer cast from %s to %s is not supported at compile time",
e1->type->toChars(), to->toChars());
return EXP_CANT_INTERPRET;
}
}
if (to->ty == Tarray && e1->op == TOKslice)
{
e1 = new SliceExp(e1->loc, ((SliceExp *)e1)->e1, ((SliceExp *)e1)->lwr,
((SliceExp *)e1)->upr);
e1->type = to;
return e1;
}
// Disallow array type painting, except for conversions between built-in
// types of identical size.
if ((to->ty == Tsarray || to->ty == Tarray) &&
(e1->type->ty == Tsarray || e1->type->ty == Tarray) &&
!isSafePointerCast(e1->type->nextOf(), to->nextOf()) )
{
error("array cast from %s to %s is not supported at compile time", e1->type->toChars(), to->toChars());
return EXP_CANT_INTERPRET;
}
if (to->ty == Tsarray && e1->op == TOKslice)
e1 = resolveSlice(e1);
if (to->toBasetype()->ty == Tbool && e1->type->ty==Tpointer)
{
return new IntegerExp(loc, e1->op != TOKnull, to);
}
return ctfeCast(loc, type, to, e1);
}
Expression *AssertExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e;
Expression *e1;
#if LOG
printf("AssertExp::interpret() %s\n", toChars());
#endif
#if DMDV2
e1 = this->e1->interpret(istate);
#else
// Deal with pointers (including compiler-inserted assert(&this, "null this"))
if ( isPointer(this->e1->type) )
{
e1 = this->e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e1))
return e1;
if (e1->op != TOKnull)
return new IntegerExp(loc, 1, Type::tbool);
}
else
e1 = this->e1->interpret(istate);
#endif
if (exceptionOrCantInterpret(e1))
return e1;
if (isTrueBool(e1))
{
}
else if (e1->isBool(FALSE))
{
if (msg)
{
e = msg->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
error("%s", e->toChars());
}
else
error("%s failed", toChars());
goto Lcant;
}
else
{
error("%s is not a compile-time boolean expression", e1->toChars());
goto Lcant;
}
return e1;
Lcant:
return EXP_CANT_INTERPRET;
}
Expression *PtrExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e = EXP_CANT_INTERPRET;
#if LOG
printf("PtrExp::interpret() %s\n", toChars());
#endif
// Constant fold *(&structliteral + offset)
if (e1->op == TOKadd)
{ AddExp *ae = (AddExp *)e1;
if (ae->e1->op == TOKaddress && ae->e2->op == TOKint64)
{ AddrExp *ade = (AddrExp *)ae->e1;
Expression *ex = ade->e1;
ex = ex->interpret(istate);
if (exceptionOrCantInterpret(ex))
return ex;
if (ex->op == TOKstructliteral)
{ StructLiteralExp *se = (StructLiteralExp *)ex;
dinteger_t offset = ae->e2->toInteger();
e = se->getField(type, offset);
if (!e)
e = EXP_CANT_INTERPRET;
return e;
}
}
e = Ptr(type, e1);
}
#if DMDV2
#else // this is required for D1, where structs return *this instead of 'this'.
else if (e1->op == TOKthis)
{
if(istate->localThis)
return istate->localThis->interpret(istate);
}
#endif
else
{ // It's possible we have an array bounds error. We need to make sure it
// errors with this line number, not the one where the pointer was set.
e = e1->interpret(istate, ctfeNeedLvalue);
if (exceptionOrCantInterpret(e))
return e;
if (!(e->op == TOKvar || e->op == TOKdotvar || e->op == TOKindex
|| e->op == TOKslice || e->op == TOKaddress))
{
error("dereference of invalid pointer '%s'", e->toChars());
return EXP_CANT_INTERPRET;
}
if (goal != ctfeNeedLvalue)
{
if (e->op == TOKindex && e->type->ty == Tpointer)
{
IndexExp *ie = (IndexExp *)e;
// Is this a real index to an array of pointers, or just a CTFE pointer?
// If the index has the same levels of indirection, it's an index
int srcLevels = 0;
int destLevels = 0;
for(Type *xx = ie->e1->type; xx->ty == Tpointer; xx = xx->nextOf())
++srcLevels;
for(Type *xx = e->type->nextOf(); xx->ty == Tpointer; xx = xx->nextOf())
++destLevels;
bool isGenuineIndex = (srcLevels == destLevels);
if ((ie->e1->op == TOKarrayliteral || ie->e1->op == TOKstring)
&& ie->e2->op == TOKint64)
{
Expression *dollar = ArrayLength(Type::tsize_t, ie->e1);
dinteger_t len = dollar->toInteger();
dinteger_t indx = ie->e2->toInteger();
assert(indx >=0 && indx <= len); // invalid pointer
if (indx == len)
{
error("dereference of pointer %s one past end of memory block limits [0..%lld]",
toChars(), len);
return EXP_CANT_INTERPRET;
}
e = ctfeIndex(loc, type, ie->e1, indx);
if (isGenuineIndex)
{
if (e->op == TOKindex)
e = e->interpret(istate, goal);
else if (e->op == TOKaddress)
e = paintTypeOntoLiteral(type, ((AddrExp *)e)->e1);
}
return e;
}
if (ie->e1->op == TOKassocarrayliteral)
{
e = Index(type, ie->e1, ie->e2);
if (isGenuineIndex)
{
if (e->op == TOKindex)
e = e->interpret(istate, goal);
else if (e->op == TOKaddress)
e = paintTypeOntoLiteral(type, ((AddrExp *)e)->e1);
}
return e;
}
}
if (e->op == TOKstructliteral)
return e;
e = e1->interpret(istate, goal);
if (e->op == TOKaddress)
{
e = ((AddrExp*)e)->e1;
if (e->op == TOKdotvar || e->op == TOKindex)
e = e->interpret(istate, goal);
}
else if (e->op == TOKvar)
{
e = e->interpret(istate, goal);
}
if (exceptionOrCantInterpret(e))
return e;
}
else if (e->op == TOKaddress)
e = ((AddrExp*)e)->e1; // *(&x) ==> x
else if (e->op == TOKnull)
{
error("dereference of null pointer '%s'", e1->toChars());
return EXP_CANT_INTERPRET;
}
e->type = type;
}
#if LOG
if (e == EXP_CANT_INTERPRET)
printf("PtrExp::interpret() %s = EXP_CANT_INTERPRET\n", toChars());
#endif
return e;
}
Expression *DotVarExp::interpret(InterState *istate, CtfeGoal goal)
{ Expression *e = EXP_CANT_INTERPRET;
#if LOG
printf("DotVarExp::interpret() %s\n", toChars());
#endif
Expression *ex = e1->interpret(istate);
if (exceptionOrCantInterpret(ex))
return ex;
if (ex != EXP_CANT_INTERPRET)
{
#if DMDV2
// Special case for template AAs: AA.var returns the AA itself.
// ie AA.p ----> AA. This is a hack, to get around the
// corresponding hack in the AA druntime implementation.
if (isAssocArray(ex->type))
return ex;
#endif
if (ex->op == TOKaddress)
ex = ((AddrExp *)ex)->e1;
VarDeclaration *v = var->isVarDeclaration();
if (!v)
error("CTFE internal error: %s", toChars());
if (ex->op == TOKnull && ex->type->toBasetype()->ty == Tclass)
{ error("class '%s' is null and cannot be dereferenced", e1->toChars());
return EXP_CANT_INTERPRET;
}
if (ex->op == TOKstructliteral || ex->op == TOKclassreference)
{
StructLiteralExp *se = ex->op == TOKclassreference ? ((ClassReferenceExp *)ex)->value : (StructLiteralExp *)ex;
// We can't use getField, because it makes a copy
int i = -1;
if (ex->op == TOKclassreference)
i = ((ClassReferenceExp *)ex)->findFieldIndexByName(v);
else
i = findFieldIndexByName(se->sd, v);
if (i == -1)
{
error("couldn't find field %s of type %s in %s", v->toChars(), type->toChars(), se->toChars());
return EXP_CANT_INTERPRET;
}
e = se->elements->tdata()[i];
if (goal == ctfeNeedLvalue || goal == ctfeNeedLvalueRef)
{
// If it is an lvalue literal, return it...
if (e->op == TOKstructliteral)
return e;
if ((type->ty == Tsarray || goal == ctfeNeedLvalue) && (
e->op == TOKarrayliteral ||
e->op == TOKassocarrayliteral || e->op == TOKstring ||
e->op == TOKclassreference || e->op == TOKslice))
return e;
/* Element is an allocated pointer, which was created in
* CastExp.
*/
if (goal == ctfeNeedLvalue && e->op == TOKindex &&
e->type == type &&
isPointer(type) )
return e;
// ...Otherwise, just return the (simplified) dotvar expression
e = new DotVarExp(loc, ex, v);
e->type = type;
return e;
}
if (!e)
{
error("couldn't find field %s in %s", v->toChars(), type->toChars());
e = EXP_CANT_INTERPRET;
}
// If it is an rvalue literal, return it...
if (e->op == TOKstructliteral || e->op == TOKarrayliteral ||
e->op == TOKassocarrayliteral || e->op == TOKstring)
return e;
if (e->op == TOKvoid)
{
VoidInitExp *ve = (VoidInitExp *)e;
error("cannot read uninitialized variable %s in ctfe", toChars());
ve->var->error("was uninitialized and used before set");
return EXP_CANT_INTERPRET;
}
if ( isPointer(type) )
{
return paintTypeOntoLiteral(type, e);
}
if (e->op == TOKvar)
{ // Don't typepaint twice, since that might cause an erroneous copy
e = getVarExp(loc, istate, ((VarExp *)e)->var, goal);
if (e != EXP_CANT_INTERPRET && e->op != TOKthrownexception)
e = paintTypeOntoLiteral(type, e);
return e;
}
return e->interpret(istate, goal);
}
else
error("%s.%s is not yet implemented at compile time", e1->toChars(), var->toChars());
}
#if LOG
if (e == EXP_CANT_INTERPRET)
printf("DotVarExp::interpret() %s = EXP_CANT_INTERPRET\n", toChars());
#endif
return e;
}
Expression *RemoveExp::interpret(InterState *istate, CtfeGoal goal)
{
#if LOG
printf("RemoveExp::interpret() %s\n", toChars());
#endif
Expression *agg = e1->interpret(istate);
if (exceptionOrCantInterpret(agg))
return agg;
Expression *index = e2->interpret(istate);
if (exceptionOrCantInterpret(index))
return index;
if (agg->op == TOKnull)
return EXP_VOID_INTERPRET;
assert(agg->op == TOKassocarrayliteral);
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)agg;
Expressions *keysx = aae->keys;
Expressions *valuesx = aae->values;
size_t removed = 0;
for (size_t j = 0; j < valuesx->dim; ++j)
{ Expression *ekey = keysx->tdata()[j];
Expression *ex = ctfeEqual(loc, TOKequal, Type::tbool, ekey, index);
if (exceptionOrCantInterpret(ex))
return ex;
if (ex->isBool(TRUE))
++removed;
else if (removed != 0)
{ keysx->tdata()[j - removed] = ekey;
valuesx->tdata()[j - removed] = valuesx->tdata()[j];
}
}
valuesx->dim = valuesx->dim - removed;
keysx->dim = keysx->dim - removed;
return new IntegerExp(loc, removed?1:0, Type::tbool);
}
/******************************* Special Functions ***************************/
Expression *interpret_length(InterState *istate, Expression *earg)
{
//printf("interpret_length()\n");
earg = earg->interpret(istate);
if (earg == EXP_CANT_INTERPRET)
return NULL;
if (exceptionOrCantInterpret(earg))
return earg;
dinteger_t len = 0;
if (earg->op == TOKassocarrayliteral)
len = ((AssocArrayLiteralExp *)earg)->keys->dim;
else assert(earg->op == TOKnull);
Expression *e = new IntegerExp(earg->loc, len, Type::tsize_t);
return e;
}
Expression *interpret_keys(InterState *istate, Expression *earg, Type *elemType)
{
#if LOG
printf("interpret_keys()\n");
#endif
earg = earg->interpret(istate);
if (earg == EXP_CANT_INTERPRET)
return NULL;
if (exceptionOrCantInterpret(earg))
return earg;
if (earg->op == TOKnull)
return new NullExp(earg->loc);
if (earg->op != TOKassocarrayliteral && earg->type->toBasetype()->ty != Taarray)
return NULL;
assert(earg->op == TOKassocarrayliteral);
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)earg;
ArrayLiteralExp *ae = new ArrayLiteralExp(aae->loc, aae->keys);
ae->ownedByCtfe = aae->ownedByCtfe;
ae->type = new TypeSArray(elemType, new IntegerExp(aae->keys->dim));
return copyLiteral(ae);
}
Expression *interpret_values(InterState *istate, Expression *earg, Type *elemType)
{
#if LOG
printf("interpret_values()\n");
#endif
earg = earg->interpret(istate);
if (earg == EXP_CANT_INTERPRET)
return NULL;
if (exceptionOrCantInterpret(earg))
return earg;
if (earg->op == TOKnull)
return new NullExp(earg->loc);
if (earg->op != TOKassocarrayliteral && earg->type->toBasetype()->ty != Taarray)
return NULL;
assert(earg->op == TOKassocarrayliteral);
AssocArrayLiteralExp *aae = (AssocArrayLiteralExp *)earg;
ArrayLiteralExp *ae = new ArrayLiteralExp(aae->loc, aae->values);
ae->ownedByCtfe = aae->ownedByCtfe;
ae->type = new TypeSArray(elemType, new IntegerExp(aae->values->dim));
//printf("result is %s\n", e->toChars());
return copyLiteral(ae);
}
// signature is int delegate(ref Value) OR int delegate(ref Key, ref Value)
Expression *interpret_aaApply(InterState *istate, Expression *aa, Expression *deleg)
{ aa = aa->interpret(istate);
if (exceptionOrCantInterpret(aa))
return aa;
if (aa->op != TOKassocarrayliteral)
return new IntegerExp(deleg->loc, 0, Type::tsize_t);
FuncDeclaration *fd = NULL;
Expression *pthis = NULL;
if (deleg->op == TOKdelegate)
{
fd = ((DelegateExp *)deleg)->func;
pthis = ((DelegateExp *)deleg)->e1;
}
else if (deleg->op == TOKfunction)
fd = ((FuncExp*)deleg)->fd;
assert(fd && fd->fbody);
assert(fd->parameters);
int numParams = fd->parameters->dim;
assert(numParams == 1 || numParams==2);
Type *valueType = fd->parameters->tdata()[numParams-1]->type;
Type *keyType = numParams == 2 ? fd->parameters->tdata()[0]->type
: Type::tsize_t;
Expressions args;
args.setDim(numParams);
AssocArrayLiteralExp *ae = (AssocArrayLiteralExp *)aa;
if (!ae->keys || ae->keys->dim == 0)
return new IntegerExp(deleg->loc, 0, Type::tsize_t);
Expression *eresult;
for (size_t i = 0; i < ae->keys->dim; ++i)
{
Expression *ekey = ae->keys->tdata()[i];
Expression *evalue = ae->values->tdata()[i];
args.tdata()[numParams - 1] = evalue;
if (numParams == 2) args.tdata()[0] = ekey;
eresult = fd->interpret(istate, &args, pthis);
if (exceptionOrCantInterpret(eresult))
return eresult;
assert(eresult->op == TOKint64);
if (((IntegerExp *)eresult)->value != 0)
return eresult;
}
return eresult;
}
// Helper function: given a function of type A[] f(...),
// return A.
Type *returnedArrayElementType(FuncDeclaration *fd)
{
assert(fd->type->ty == Tfunction);
assert(fd->type->nextOf()->ty == Tarray);
return ((TypeFunction *)fd->type)->nextOf()->nextOf();
}
/* Decoding UTF strings for foreach loops. Duplicates the functionality of
* the twelve _aApplyXXn functions in aApply.d in the runtime.
*/
Expression *foreachApplyUtf(InterState *istate, Expression *str, Expression *deleg, bool rvs)
{
#if LOG
printf("foreachApplyUtf(%s, %s)\n", str->toChars(), deleg->toChars());
#endif
FuncDeclaration *fd = NULL;
Expression *pthis = NULL;
if (deleg->op == TOKdelegate)
{
fd = ((DelegateExp *)deleg)->func;
pthis = ((DelegateExp *)deleg)->e1;
}
else if (deleg->op == TOKfunction)
fd = ((FuncExp*)deleg)->fd;
assert(fd && fd->fbody);
assert(fd->parameters);
int numParams = fd->parameters->dim;
assert(numParams == 1 || numParams==2);
Type *charType = fd->parameters->tdata()[numParams-1]->type;
Type *indexType = numParams == 2 ? fd->parameters->tdata()[0]->type
: Type::tsize_t;
uinteger_t len = resolveArrayLength(str);
if (len == 0)
return new IntegerExp(deleg->loc, 0, indexType);
if (str->op == TOKslice)
str = resolveSlice(str);
StringExp *se = NULL;
ArrayLiteralExp *ale = NULL;
if (str->op == TOKstring)
se = (StringExp *) str;
else if (str->op == TOKarrayliteral)
ale = (ArrayLiteralExp *)str;
else
{ str->error("CTFE internal error: cannot foreach %s", str->toChars());
return EXP_CANT_INTERPRET;
}
Expressions args;
args.setDim(numParams);
Expression *eresult;
// Buffers for encoding; also used for decoding array literals
unsigned char utf8buf[4];
unsigned short utf16buf[2];
size_t start = rvs ? len : 0;
size_t end = rvs ? 0: len;
for (size_t indx = start; indx != end;)
{
// Step 1: Decode the next dchar from the string.
const char *errmsg = NULL; // Used for reporting decoding errors
dchar_t rawvalue; // Holds the decoded dchar
size_t currentIndex = indx; // The index of the decoded character
if (ale)
{ // If it is an array literal, copy the code points into the buffer
int buflen = 1; // #code points in the buffer
size_t n = 1; // #code points in this char
size_t sz = ale->type->nextOf()->size();
switch(sz)
{
case 1:
if (rvs)
{ // find the start of the string
--indx;
buflen = 1;
while (indx > 0 && buflen < 4)
{ Expression * r = ale->elements->tdata()[indx];
assert(r->op == TOKint64);
unsigned char x = (unsigned char)(((IntegerExp *)r)->value);
if ( (x & 0xC0) != 0x80)
break;
++buflen;
}
}
else
buflen = (indx + 4 > len) ? len - indx : 4;
for (int i=0; i < buflen; ++i)
{
Expression * r = ale->elements->tdata()[indx + i];
assert(r->op == TOKint64);
utf8buf[i] = (unsigned char)(((IntegerExp *)r)->value);
}
n = 0;
errmsg = utf_decodeChar(&utf8buf[0], buflen, &n, &rawvalue);
break;
case 2:
if (rvs)
{ // find the start of the string
--indx;
buflen = 1;
Expression * r = ale->elements->tdata()[indx];
assert(r->op == TOKint64);
unsigned short x = (unsigned short)(((IntegerExp *)r)->value);
if (indx > 0 && x >= 0xDC00 && x <= 0xDFFF)
{
--indx;
++buflen;
}
}
else
buflen = (indx + 2 > len) ? len - indx : 2;
for (int i=0; i < buflen; ++i)
{
Expression * r = ale->elements->tdata()[indx + i];
assert(r->op == TOKint64);
utf16buf[i] = (unsigned short)(((IntegerExp *)r)->value);
}
n = 0;
errmsg = utf_decodeWchar(&utf16buf[0], buflen, &n, &rawvalue);
break;
case 4:
{
if (rvs)
--indx;
Expression * r = ale->elements->tdata()[indx];
assert(r->op == TOKint64);
rawvalue = ((IntegerExp *)r)->value;
n = 1;
}
break;
default:
assert(0);
}
if (!rvs)
indx += n;
}
else
{ // String literals
size_t saveindx; // used for reverse iteration
switch (se->sz)
{
case 1:
if (rvs)
{ // find the start of the string
unsigned char *s = (unsigned char *)se->string;
--indx;
while (indx > 0 && ((s[indx]&0xC0)==0x80))
--indx;
saveindx = indx;
}
errmsg = utf_decodeChar((unsigned char *)se->string, se->len, &indx, &rawvalue);
if (rvs)
indx = saveindx;
break;
case 2:
if (rvs)
{ // find the start
unsigned short *s = (unsigned short *)se->string;
--indx;
if (s[indx] >= 0xDC00 && s[indx]<= 0xDFFF)
--indx;
saveindx = indx;
}
errmsg = utf_decodeWchar((unsigned short *)se->string, se->len, &indx, &rawvalue);
if (rvs)
indx = saveindx;
break;
case 4:
if (rvs)
--indx;
rawvalue = ((unsigned *)(se->string))[indx];
if (!rvs)
++indx;
break;
default:
assert(0);
}
}
if (errmsg)
{ deleg->error("%s", errmsg);
return EXP_CANT_INTERPRET;
}
// Step 2: encode the dchar in the target encoding
int charlen = 1; // How many codepoints are involved?
switch(charType->size())
{
case 1:
charlen = utf_codeLengthChar(rawvalue);
utf_encodeChar(&utf8buf[0], rawvalue);
break;
case 2:
charlen = utf_codeLengthWchar(rawvalue);
utf_encodeWchar(&utf16buf[0], rawvalue);
break;
case 4:
break;
default:
assert(0);
}
if (rvs)
currentIndex = indx;
// Step 3: call the delegate once for each code point
// The index only needs to be set once
if (numParams == 2)
args.tdata()[0] = new IntegerExp(deleg->loc, currentIndex, indexType);
Expression *val = NULL;
for (int k= 0; k < charlen; ++k)
{
dchar_t codepoint;
switch(charType->size())
{
case 1:
codepoint = utf8buf[k];
break;
case 2:
codepoint = utf16buf[k];
break;
case 4:
codepoint = rawvalue;
break;
default:
assert(0);
}
val = new IntegerExp(str->loc, codepoint, charType);
args.tdata()[numParams - 1] = val;
eresult = fd->interpret(istate, &args, pthis);
if (exceptionOrCantInterpret(eresult))
return eresult;
assert(eresult->op == TOKint64);
if (((IntegerExp *)eresult)->value != 0)
return eresult;
}
}
return eresult;
}
/* If this is a built-in function, return the interpreted result,
* Otherwise, return NULL.
*/
Expression *evaluateIfBuiltin(InterState *istate, Loc loc,
FuncDeclaration *fd, Expressions *arguments, Expression *pthis)
{
Expression *e = NULL;
int nargs = arguments ? arguments->dim : 0;
#if DMDV2
if (pthis && isAssocArray(pthis->type))
{
if (fd->ident == Id::length && nargs==0)
return interpret_length(istate, pthis);
else if (fd->ident == Id::keys && nargs==0)
return interpret_keys(istate, pthis, returnedArrayElementType(fd));
else if (fd->ident == Id::values && nargs==0)
return interpret_values(istate, pthis, returnedArrayElementType(fd));
else if (fd->ident == Id::rehash && nargs==0)
return pthis->interpret(istate, ctfeNeedLvalue); // rehash is a no-op
}
if (!pthis)
{
enum BUILTIN b = fd->isBuiltin();
if (b)
{ Expressions args;
args.setDim(nargs);
for (size_t i = 0; i < args.dim; i++)
{
Expression *earg = arguments->tdata()[i];
earg = earg->interpret(istate);
if (exceptionOrCantInterpret(earg))
return earg;
args.tdata()[i] = earg;
}
e = eval_builtin(loc, b, &args);
if (!e)
e = EXP_CANT_INTERPRET;
}
}
/* Horrid hack to retrieve the builtin AA functions after they've been
* mashed by the inliner.
*/
if (!pthis)
{
Expression *firstarg = nargs > 0 ? (Expression *)(arguments->data[0]) : NULL;
// Check for the first parameter being a templatized AA. Hack: we assume that
// template AA.var is always the AA data itself.
Expression *firstdotvar = (firstarg && firstarg->op == TOKdotvar)
? ((DotVarExp *)firstarg)->e1 : NULL;
if (nargs==3 && isAssocArray(firstarg->type) && !strcmp(fd->ident->string, "_aaApply"))
return interpret_aaApply(istate, firstarg, (Expression *)(arguments->data[2]));
if (nargs==3 && isAssocArray(firstarg->type) &&!strcmp(fd->ident->string, "_aaApply2"))
return interpret_aaApply(istate, firstarg, (Expression *)(arguments->data[2]));
if (firstdotvar && isAssocArray(firstdotvar->type))
{ if (fd->ident == Id::aaLen && nargs == 1)
return interpret_length(istate, firstdotvar->interpret(istate));
else if (fd->ident == Id::aaKeys && nargs == 2)
{
Expression *trueAA = firstdotvar->interpret(istate);
return interpret_keys(istate, trueAA, toBuiltinAAType(trueAA->type)->index);
}
else if (fd->ident == Id::aaValues && nargs == 3)
{
Expression *trueAA = firstdotvar->interpret(istate);
return interpret_values(istate, trueAA, toBuiltinAAType(trueAA->type)->nextOf());
}
else if (fd->ident == Id::aaRehash && nargs == 2)
{
return firstdotvar->interpret(istate, ctfeNeedLvalue);
}
}
}
#endif
#if DMDV1
if (!pthis)
{
Expression *firstarg = nargs > 0 ? (Expression *)(arguments->data[0]) : NULL;
if (firstarg && firstarg->type->toBasetype()->ty == Taarray)
{
TypeAArray *firstAAtype = (TypeAArray *)firstarg->type;
if (fd->ident == Id::aaLen && nargs == 1)
return interpret_length(istate, firstarg);
else if (fd->ident == Id::aaKeys)
return interpret_keys(istate, firstarg, firstAAtype->index);
else if (fd->ident == Id::aaValues)
return interpret_values(istate, firstarg, firstAAtype->nextOf());
else if (nargs==2 && fd->ident == Id::aaRehash)
return firstarg->interpret(istate, ctfeNeedLvalue); //no-op
else if (nargs==3 && !strcmp(fd->ident->string, "_aaApply"))
return interpret_aaApply(istate, firstarg, (Expression *)(arguments->data[2]));
else if (nargs==3 && !strcmp(fd->ident->string, "_aaApply2"))
return interpret_aaApply(istate, firstarg, (Expression *)(arguments->data[2]));
}
}
#endif
#if DMDV2
if (pthis && !fd->fbody && fd->isCtorDeclaration() && fd->parent && fd->parent->parent && fd->parent->parent->ident == Id::object)
{
if (pthis->op == TOKclassreference && fd->parent->ident == Id::Throwable)
{ // At present, the constructors just copy their arguments into the struct.
// But we might need some magic if stack tracing gets added to druntime.
StructLiteralExp *se = ((ClassReferenceExp *)pthis)->value;
assert(arguments->dim <= se->elements->dim);
for (int i = 0; i < arguments->dim; ++i)
{
Expression *e = arguments->tdata()[i]->interpret(istate);
if (exceptionOrCantInterpret(e))
return e;
se->elements->tdata()[i] = e;
}
return EXP_VOID_INTERPRET;
}
}
#endif
if (nargs == 1 && !pthis &&
(fd->ident == Id::criticalenter || fd->ident == Id::criticalexit))
{ // Support synchronized{} as a no-op
return EXP_VOID_INTERPRET;
}
if (!pthis)
{
size_t idlen = strlen(fd->ident->string);
if (nargs == 2 && (idlen == 10 || idlen == 11)
&& !strncmp(fd->ident->string, "_aApply", 7))
{ // Functions from aApply.d and aApplyR.d in the runtime
bool rvs = (idlen == 11); // true if foreach_reverse
char c = fd->ident->string[idlen-3]; // char width: 'c', 'w', or 'd'
char s = fd->ident->string[idlen-2]; // string width: 'c', 'w', or 'd'
char n = fd->ident->string[idlen-1]; // numParams: 1 or 2.
// There are 12 combinations
if ( (n == '1' || n == '2') &&
(c == 'c' || c == 'w' || c == 'd') &&
(s == 'c' || s == 'w' || s == 'd') && c != s)
{ Expression *str = arguments->tdata()[0];
str = str->interpret(istate);
if (exceptionOrCantInterpret(str))
return str;
return foreachApplyUtf(istate, str, arguments->tdata()[1], rvs);
}
}
}
return e;
}
/*************************** CTFE Sanity Checks ***************************/
/* Setter functions for CTFE variable values.
* These functions exist to check for compiler CTFE bugs.
*/
bool isCtfeValueValid(Expression *newval)
{
if (
#if DMDV2
newval->type->ty == Tnull ||
#endif
isPointer(newval->type) )
{
if (newval->op == TOKaddress || newval->op == TOKnull ||
newval->op == TOKstring)
return true;
if (newval->op == TOKindex)
{
Expression *g = ((IndexExp *)newval)->e1;
if (g->op == TOKarrayliteral || g->op == TOKstring ||
g->op == TOKassocarrayliteral)
return true;
}
if (newval->op == TOKvar)
return true;
if (newval->type->nextOf()->ty == Tarray && newval->op == TOKslice)
return true;
if (newval->op == TOKint64)
return true; // Result of a cast, but cannot be dereferenced
// else it must be a reference
}
if (newval->op == TOKclassreference || (newval->op == TOKnull && newval->type->ty == Tclass))
return true;
if (newval->op == TOKvar)
{
VarExp *ve = (VarExp *)newval;
VarDeclaration *vv = ve->var->isVarDeclaration();
// Must not be a reference to a reference
if (!(vv && vv->getValue() && vv->getValue()->op == TOKvar))
return true;
}
if (newval->op == TOKdotvar)
{
if (((DotVarExp *)newval)->e1->op == TOKstructliteral)
{
assert(((StructLiteralExp *)((DotVarExp *)newval)->e1)->ownedByCtfe);
return true;
}
}
if (newval->op == TOKindex)
{
IndexExp *ie = (IndexExp *)newval;
if (ie->e2->op == TOKint64)
{
if (ie->e1->op == TOKarrayliteral || ie->e1->op == TOKstring)
return true;
}
if (ie->e1->op == TOKassocarrayliteral)
return true;
// BUG: Happens ONLY in ref foreach. Should tighten this.
if (ie->e2->op == TOKvar)
return true;
}
if (newval->op == TOKfunction) return true; // function/delegate literal
if (newval->op == TOKdelegate) return true;
if (newval->op == TOKsymoff) // function pointer
{
if (((SymOffExp *)newval)->var->isFuncDeclaration())
return true;
}
if (newval->op == TOKint64 || newval->op == TOKfloat64 ||
newval->op == TOKchar || newval->op == TOKcomplex80)
return true;
// References
if (newval->op == TOKstructliteral)
assert(((StructLiteralExp *)newval)->ownedByCtfe);
if (newval->op == TOKarrayliteral)
assert(((ArrayLiteralExp *)newval)->ownedByCtfe);
if (newval->op == TOKassocarrayliteral)
assert(((AssocArrayLiteralExp *)newval)->ownedByCtfe);
if ((newval->op ==TOKarrayliteral) || ( newval->op==TOKstructliteral) ||
(newval->op==TOKstring) || (newval->op == TOKassocarrayliteral) ||
(newval->op == TOKnull))
{ return true;
}
// Dynamic arrays passed by ref may be null. When this happens
// they may originate from an index or dotvar expression.
if (newval->type->ty == Tarray || newval->type->ty == Taarray)
if (newval->op == TOKdotvar || newval->op == TOKindex)
return true; // actually must be null
if (newval->op == TOKslice)
{
SliceExp *se = (SliceExp *)newval;
assert(se->lwr && se->lwr != EXP_CANT_INTERPRET && se->lwr->op == TOKint64);
assert(se->upr && se->upr != EXP_CANT_INTERPRET && se->upr->op == TOKint64);
assert(se->e1->op == TOKarrayliteral || se->e1->op == TOKstring);
if (se->e1->op == TOKarrayliteral)
assert(((ArrayLiteralExp *)se->e1)->ownedByCtfe);
return true;
}
if (newval->op == TOKvoid)
{
return true;
}
newval->error("CTFE internal error: illegal value %s\n", newval->toChars());
return false;
}
bool VarDeclaration::hasValue()
{
if (ctfeAdrOnStack == (size_t)-1)
return false;
return NULL != getValue();
}
Expression *VarDeclaration::getValue()
{
return ctfeStack.getValue(this);
}
void VarDeclaration::setValueNull()
{
ctfeStack.setValue(this, NULL);
}
// Don't check for validity
void VarDeclaration::setValueWithoutChecking(Expression *newval)
{
ctfeStack.setValue(this, newval);
}
void VarDeclaration::setValue(Expression *newval)
{
assert(isCtfeValueValid(newval));
ctfeStack.setValue(this, newval);
}
Expression *Type::voidInitLiteral(VarDeclaration *var)
{
return new VoidInitExp(var, this);
}
Expression *TypeSArray::voidInitLiteral(VarDeclaration *var)
{
return createBlockDuplicatedArrayLiteral(var->loc, this, next->voidInitLiteral(var), dim->toInteger());
}
Expression *TypeStruct::voidInitLiteral(VarDeclaration *var)
{
Expressions *exps = new Expressions();
exps->setDim(sym->fields.dim);
for (size_t i = 0; i < sym->fields.dim; i++)
{
(*exps)[i] = new VoidInitExp(var, sym->fields[i]->type);
}
StructLiteralExp *se = new StructLiteralExp(var->loc, sym, exps);
se->type = this;
se->ownedByCtfe = true;
return se;
}
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