/** * CTFE for expressions involving pointers, slices, array concatenation etc. * * Copyright: Copyright (C) 1999-2022 by The D Language Foundation, All Rights Reserved * Authors: $(LINK2 https://www.digitalmars.com, Walter Bright) * License: $(LINK2 https://www.boost.org/LICENSE_1_0.txt, Boost License 1.0) * Source: $(LINK2 https://github.com/dlang/dmd/blob/master/src/dmd/ctfeexpr.d, _ctfeexpr.d) * Documentation: https://dlang.org/phobos/dmd_ctfeexpr.html * Coverage: https://codecov.io/gh/dlang/dmd/src/master/src/dmd/ctfeexpr.d */ module dmd.ctfeexpr; import core.stdc.stdio; import core.stdc.stdlib; import core.stdc.string; import dmd.arraytypes; import dmd.astenums; import dmd.constfold; import dmd.compiler; import dmd.dclass; import dmd.declaration; import dmd.dinterpret; import dmd.dstruct; import dmd.dtemplate; import dmd.errors; import dmd.expression; import dmd.func; import dmd.globals; import dmd.mtype; import dmd.root.complex; import dmd.root.ctfloat; import dmd.root.port; import dmd.root.rmem; import dmd.tokens; import dmd.visitor; /*********************************************************** * A reference to a class, or an interface. We need this when we * point to a base class (we must record what the type is). */ extern (C++) final class ClassReferenceExp : Expression { StructLiteralExp value; extern (D) this(const ref Loc loc, StructLiteralExp lit, Type type) { super(loc, EXP.classReference, __traits(classInstanceSize, ClassReferenceExp)); assert(lit && lit.sd && lit.sd.isClassDeclaration()); this.value = lit; this.type = type; } ClassDeclaration originalClass() { return value.sd.isClassDeclaration(); } // Return index of the field, or -1 if not found private int getFieldIndex(Type fieldtype, uint fieldoffset) { ClassDeclaration cd = originalClass(); uint 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; } VarDeclaration v2 = cd.fields[j - fieldsSoFar]; if (fieldoffset == v2.offset && fieldtype.size() == v2.type.size()) { return cast(int)(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; } VarDeclaration v2 = cd.fields[j - fieldsSoFar]; if (v == v2) { return cast(int)(value.elements.dim - fieldsSoFar - cd.fields.dim + (j - fieldsSoFar)); } } return -1; } override void accept(Visitor v) { v.visit(this); } } /************************* * Same as getFieldIndex, but checks for a direct match with the VarDeclaration * Returns: * index of the field, or -1 if not found */ int findFieldIndexByName(const StructDeclaration sd, const VarDeclaration v) pure { foreach (i, field; sd.fields) { if (field == v) return cast(int)i; } return -1; } /*********************************************************** * Fake class which holds the thrown exception. * Used for implementing exception handling. */ extern (C++) final class ThrownExceptionExp : Expression { ClassReferenceExp thrown; // the thing being tossed extern (D) this(const ref Loc loc, ClassReferenceExp victim) { super(loc, EXP.thrownException, __traits(classInstanceSize, ThrownExceptionExp)); this.thrown = victim; this.type = victim.type; } override const(char)* toChars() const { return "CTFE ThrownException"; } // Generate an error message when this exception is not caught extern (D) void generateUncaughtError() { UnionExp ue = void; Expression e = resolveSlice((*thrown.value.elements)[0], &ue); StringExp se = e.toStringExp(); thrown.error("uncaught CTFE exception `%s(%s)`", thrown.type.toChars(), se ? se.toChars() : e.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.isValid() && !loc.equals(thrown.loc)) .errorSupplemental(loc, "thrown from here"); } override void accept(Visitor v) { v.visit(this); } } /*********************************************************** * This type is only used by the interpreter. */ extern (C++) final class CTFEExp : Expression { extern (D) this(EXP tok) { super(Loc.initial, tok, __traits(classInstanceSize, CTFEExp)); type = Type.tvoid; } override const(char)* toChars() const { switch (op) { case EXP.cantExpression: return ""; case EXP.voidExpression: return "cast(void)0"; case EXP.showCtfeContext: return ""; case EXP.break_: return ""; case EXP.continue_: return ""; case EXP.goto_: return ""; default: assert(0); } } extern (D) __gshared CTFEExp cantexp; extern (D) __gshared CTFEExp voidexp; extern (D) __gshared CTFEExp breakexp; extern (D) __gshared CTFEExp continueexp; extern (D) __gshared CTFEExp gotoexp; /* Used when additional information is needed regarding * a ctfe error. */ extern (D) __gshared CTFEExp showcontext; extern (D) static bool isCantExp(const Expression e) { return e && e.op == EXP.cantExpression; } extern (D) static bool isGotoExp(const Expression e) { return e && e.op == EXP.goto_; } } // True if 'e' is CTFEExp::cantexp, or an exception bool exceptionOrCantInterpret(const Expression e) { return e && (e.op == EXP.cantExpression || e.op == EXP.thrownException || e.op == EXP.showCtfeContext); } /************** Aggregate literals (AA/string/array/struct) ******************/ // Given expr, which evaluates to an array/AA/string literal, // return true if it needs to be copied bool needToCopyLiteral(const Expression expr) { Expression e = cast()expr; for (;;) { switch (e.op) { case EXP.arrayLiteral: return e.isArrayLiteralExp().ownedByCtfe == OwnedBy.code; case EXP.assocArrayLiteral: return e.isAssocArrayLiteralExp().ownedByCtfe == OwnedBy.code; case EXP.structLiteral: return e.isStructLiteralExp().ownedByCtfe == OwnedBy.code; case EXP.string_: case EXP.this_: case EXP.variable: return false; case EXP.assign: return false; case EXP.index: case EXP.dotVariable: case EXP.slice: case EXP.cast_: e = e.isUnaExp().e1; continue; case EXP.concatenate: return needToCopyLiteral(e.isBinExp().e1) || needToCopyLiteral(e.isBinExp().e2); case EXP.concatenateAssign: case EXP.concatenateElemAssign: case EXP.concatenateDcharAssign: e = e.isBinExp().e2; continue; default: return false; } } } private Expressions* copyLiteralArray(Expressions* oldelems, Expression basis = null) { if (!oldelems) return oldelems; incArrayAllocs(); auto newelems = new Expressions(oldelems.dim); foreach (i, el; *oldelems) { (*newelems)[i] = copyLiteral(el ? el : basis).copy(); } return newelems; } // Make a copy of the ArrayLiteral, AALiteral, String, or StructLiteral. // This value will be used for in-place modification. UnionExp copyLiteral(Expression e) { UnionExp ue = void; if (auto se = e.isStringExp()) // syntaxCopy doesn't make a copy for StringExp! { char* s = cast(char*)mem.xcalloc(se.len + 1, se.sz); const slice = se.peekData(); memcpy(s, slice.ptr, slice.length); emplaceExp!(StringExp)(&ue, se.loc, s[0 .. se.len * se.sz], se.len, se.sz); StringExp se2 = ue.exp().isStringExp(); se2.committed = se.committed; se2.postfix = se.postfix; se2.type = se.type; se2.ownedByCtfe = OwnedBy.ctfe; return ue; } if (auto ale = e.isArrayLiteralExp()) { auto elements = copyLiteralArray(ale.elements, ale.basis); emplaceExp!(ArrayLiteralExp)(&ue, e.loc, e.type, elements); ArrayLiteralExp r = ue.exp().isArrayLiteralExp(); r.ownedByCtfe = OwnedBy.ctfe; return ue; } if (auto aae = e.isAssocArrayLiteralExp()) { emplaceExp!(AssocArrayLiteralExp)(&ue, e.loc, copyLiteralArray(aae.keys), copyLiteralArray(aae.values)); AssocArrayLiteralExp r = ue.exp().isAssocArrayLiteralExp(); r.type = e.type; r.ownedByCtfe = OwnedBy.ctfe; return ue; } if (auto sle = e.isStructLiteralExp()) { /* 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. */ auto oldelems = sle.elements; auto newelems = new Expressions(oldelems.dim); foreach (i, ref el; *newelems) { // We need the struct definition to detect block assignment auto v = sle.sd.fields[i]; auto m = (*oldelems)[i]; // If it is a void assignment, use the default initializer if (!m) m = voidInitLiteral(v.type, v).copy(); if (v.type.ty == Tarray || v.type.ty == Taarray) { // Don't have to copy array references } else { // Buzilla 15681: Copy the source element always. m = copyLiteral(m).copy(); // Block assignment from inside struct literals if (v.type.ty != m.type.ty && v.type.ty == Tsarray) { auto tsa = v.type.isTypeSArray(); auto len = cast(size_t)tsa.dim.toInteger(); m = createBlockDuplicatedArrayLiteral(&ue, e.loc, v.type, m, len); if (m == ue.exp()) m = ue.copy(); } } el = m; } emplaceExp!(StructLiteralExp)(&ue, e.loc, sle.sd, newelems, sle.stype); auto r = ue.exp().isStructLiteralExp(); r.type = e.type; r.ownedByCtfe = OwnedBy.ctfe; r.origin = sle.origin; return ue; } if (e.op == EXP.function_ || e.op == EXP.delegate_ || e.op == EXP.symbolOffset || e.op == EXP.null_ || e.op == EXP.variable || e.op == EXP.dotVariable || e.op == EXP.int64 || e.op == EXP.float64 || e.op == EXP.char_ || e.op == EXP.complex80 || e.op == EXP.void_ || e.op == EXP.vector || e.op == EXP.typeid_) { // Simple value types // Keep e1 for DelegateExp and DotVarExp emplaceExp!(UnionExp)(&ue, e); Expression r = ue.exp(); r.type = e.type; return ue; } if (auto se = e.isSliceExp()) { if (se.type.toBasetype().ty == Tsarray) { // same with resolveSlice() if (se.e1.op == EXP.null_) { emplaceExp!(NullExp)(&ue, se.loc, se.type); return ue; } ue = Slice(se.type, se.e1, se.lwr, se.upr); auto r = ue.exp().isArrayLiteralExp(); r.elements = copyLiteralArray(r.elements); r.ownedByCtfe = OwnedBy.ctfe; return ue; } else { // Array slices only do a shallow copy emplaceExp!(SliceExp)(&ue, e.loc, se.e1, se.lwr, se.upr); Expression r = ue.exp(); r.type = e.type; return ue; } } if (isPointer(e.type)) { // For pointers, we only do a shallow copy. if (auto ae = e.isAddrExp()) emplaceExp!(AddrExp)(&ue, e.loc, ae.e1); else if (auto ie = e.isIndexExp()) emplaceExp!(IndexExp)(&ue, e.loc, ie.e1, ie.e2); else if (auto dve = e.isDotVarExp()) { emplaceExp!(DotVarExp)(&ue, e.loc, dve.e1, dve.var, dve.hasOverloads); } else assert(0); Expression r = ue.exp(); r.type = e.type; return ue; } if (auto cre = e.isClassReferenceExp()) { emplaceExp!(ClassReferenceExp)(&ue, e.loc, cre.value, e.type); return ue; } if (e.op == EXP.error) { emplaceExp!(UnionExp)(&ue, e); return ue; } e.error("CTFE internal error: literal `%s`", e.toChars()); assert(0); } /* 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.equals(type)) return lit; return paintTypeOntoLiteralCopy(type, lit).copy(); } Expression paintTypeOntoLiteral(UnionExp* pue, Type type, Expression lit) { if (lit.type.equals(type)) return lit; *pue = paintTypeOntoLiteralCopy(type, lit); return pue.exp(); } private UnionExp paintTypeOntoLiteralCopy(Type type, Expression lit) { UnionExp ue; if (lit.type.equals(type)) { emplaceExp!(UnionExp)(&ue, lit); return ue; } // If it is a cast to inout, retain the original type of the referenced part. if (type.hasWild()) { emplaceExp!(UnionExp)(&ue, lit); ue.exp().type = type; return ue; } if (auto se = lit.isSliceExp()) { emplaceExp!(SliceExp)(&ue, lit.loc, se.e1, se.lwr, se.upr); } else if (auto ie = lit.isIndexExp()) { emplaceExp!(IndexExp)(&ue, lit.loc, ie.e1, ie.e2); } else if (lit.op == EXP.arrayLiteral) { emplaceExp!(SliceExp)(&ue, lit.loc, lit, ctfeEmplaceExp!IntegerExp(Loc.initial, 0, Type.tsize_t), ArrayLength(Type.tsize_t, lit).copy()); } else if (lit.op == EXP.string_) { // For strings, we need to introduce another level of indirection emplaceExp!(SliceExp)(&ue, lit.loc, lit, ctfeEmplaceExp!IntegerExp(Loc.initial, 0, Type.tsize_t), ArrayLength(Type.tsize_t, lit).copy()); } else if (auto aae = lit.isAssocArrayLiteralExp()) { // TODO: we should be creating a reference to this AAExp, not // just a ref to the keys and values. OwnedBy wasOwned = aae.ownedByCtfe; emplaceExp!(AssocArrayLiteralExp)(&ue, lit.loc, aae.keys, aae.values); aae = ue.exp().isAssocArrayLiteralExp(); aae.ownedByCtfe = wasOwned; } else { // Can't type paint from struct to struct*; this needs another // level of indirection if (lit.op == EXP.structLiteral && isPointer(type)) lit.error("CTFE internal error: painting `%s`", type.toChars()); ue = copyLiteral(lit); } ue.exp().type = type; return ue; } /************************************* * If e is a SliceExp, constant fold it. * Params: * e = expression to resolve * pue = if not null, store resulting expression here * Returns: * resulting expression */ Expression resolveSlice(Expression e, UnionExp* pue = null) { SliceExp se = e.isSliceExp(); if (!se) return e; if (se.e1.op == EXP.null_) return se.e1; if (pue) { *pue = Slice(e.type, se.e1, se.lwr, se.upr); return pue.exp(); } else return Slice(e.type, se.e1, se.lwr, se.upr).copy(); } /* 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) { switch (e.op) { case EXP.vector: return e.isVectorExp().dim; case EXP.null_: return 0; case EXP.slice: { auto se = e.isSliceExp(); const ilo = se.lwr.toInteger(); const iup = se.upr.toInteger(); return iup - ilo; } case EXP.string_: return e.isStringExp().len; case EXP.arrayLiteral: { const ale = e.isArrayLiteralExp(); return ale.elements ? ale.elements.dim : 0; } case EXP.assocArrayLiteral: { return e.isAssocArrayLiteralExp().keys.dim; } default: assert(0); } } /****************************** * Helper for NewExp * Create an array literal consisting of 'elem' duplicated 'dim' times. * Params: * pue = where to store result * loc = source location where the interpretation occurs * type = target type of the result * elem = the source of array element, it will be owned by the result * dim = element number of the result * Returns: * Constructed ArrayLiteralExp */ ArrayLiteralExp createBlockDuplicatedArrayLiteral(UnionExp* pue, const ref Loc loc, Type type, Expression elem, size_t dim) { if (type.ty == Tsarray && type.nextOf().ty == Tsarray && elem.type.ty != Tsarray) { // If it is a multidimensional array literal, do it recursively auto tsa = type.nextOf().isTypeSArray(); const len = cast(size_t)tsa.dim.toInteger(); elem = createBlockDuplicatedArrayLiteral(pue, loc, type.nextOf(), elem, len); if (elem == pue.exp()) elem = pue.copy(); } // Buzilla 15681 const tb = elem.type.toBasetype(); const mustCopy = tb.ty == Tstruct || tb.ty == Tsarray; auto elements = new Expressions(dim); foreach (i, ref el; *elements) { el = mustCopy && i ? copyLiteral(elem).copy() : elem; } emplaceExp!(ArrayLiteralExp)(pue, loc, type, elements); auto ale = pue.exp().isArrayLiteralExp(); ale.ownedByCtfe = OwnedBy.ctfe; return ale; } /****************************** * Helper for NewExp * Create a string literal consisting of 'value' duplicated 'dim' times. */ StringExp createBlockDuplicatedStringLiteral(UnionExp* pue, const ref Loc loc, Type type, dchar value, size_t dim, ubyte sz) { auto s = cast(char*)mem.xcalloc(dim, sz); foreach (elemi; 0 .. dim) { switch (sz) { case 1: s[elemi] = cast(char)value; break; case 2: (cast(wchar*)s)[elemi] = cast(wchar)value; break; case 4: (cast(dchar*)s)[elemi] = value; break; default: assert(0); } } emplaceExp!(StringExp)(pue, loc, s[0 .. dim * sz], dim, sz); auto se = pue.exp().isStringExp(); se.type = type; se.committed = true; se.ownedByCtfe = OwnedBy.ctfe; return se; } // Return true if t is an AA bool isAssocArray(Type t) { return t.toBasetype().isTypeAArray() !is null; } // Given a template AA type, extract the corresponding built-in AA type TypeAArray toBuiltinAAType(Type t) { return t.toBasetype().isTypeAArray(); } /************** TypeInfo operations ************************************/ // Return true if type is TypeInfo_Class bool isTypeInfo_Class(const Type type) { auto tc = cast()type.isTypeClass(); return tc && (Type.dtypeinfo == tc.sym || Type.dtypeinfo.isBaseOf(tc.sym, null)); } /************** Pointer operations ************************************/ // 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; } // For CTFE only. Returns true if 'e' is true or a non-null pointer. bool isTrueBool(Expression e) { return e.toBool().hasValue(true) || ((e.type.ty == Tpointer || e.type.ty == Tclass) && e.op != EXP.null_); } /* 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 safe to cast S** to D** if it's OK to cast S* to D* while (srcPointee.ty == Tpointer && destPointee.ty == Tpointer) { srcPointee = srcPointee.nextOf(); destPointee = destPointee.nextOf(); } // It's OK if both are the same (modulo const) if (srcPointee.constConv(destPointee)) return true; // It's ok to cast from/to shared because CTFE is single threaded anyways if (srcPointee.unSharedOf() == destPointee.unSharedOf()) return true; // It's OK if function pointers differ only in safe/pure/nothrow if (srcPointee.ty == Tfunction && destPointee.ty == Tfunction) return srcPointee.covariant(destPointee) == Covariant.yes || destPointee.covariant(srcPointee) == Covariant.yes; // it's OK to cast to void* if (destPointee.ty == Tvoid) return true; // It's OK to cast from V[K] to void* if (srcPointee.ty == Taarray && destPointee == Type.tvoidptr) return true; // It's OK if they are the same size (static array of) integers, eg: // int* --> uint* // int[5][] --> uint[5][] if (srcPointee.ty == Tsarray && destPointee.ty == Tsarray) { if (srcPointee.size() != destPointee.size()) return false; srcPointee = srcPointee.baseElemOf(); destPointee = destPointee.baseElemOf(); } return srcPointee.isintegral() && destPointee.isintegral() && srcPointee.size() == destPointee.size(); } Expression getAggregateFromPointer(Expression e, dinteger_t* ofs) { *ofs = 0; if (auto ae = e.isAddrExp()) e = ae.e1; if (auto soe = e.isSymOffExp()) *ofs = soe.offset; if (auto dve = e.isDotVarExp()) { auto ex = dve.e1; const v = dve.var.isVarDeclaration(); assert(v); StructLiteralExp se = (ex.op == EXP.classReference) ? ex.isClassReferenceExp().value : ex.isStructLiteralExp(); // We can't use getField, because it makes a copy const i = (ex.op == EXP.classReference) ? ex.isClassReferenceExp().getFieldIndex(e.type, v.offset) : se.getFieldIndex(e.type, v.offset); e = (*se.elements)[i]; } if (auto ie = e.isIndexExp()) { // 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 == EXP.string_ || ie.e1.op == EXP.arrayLiteral) && ie.e2.op == EXP.int64) { *ofs = ie.e2.toInteger(); return ie.e1; } } if (auto se = e.isSliceExp()) { if (se && e.type.toBasetype().ty == Tsarray && (se.e1.type.ty == Tarray || se.e1.type.ty == Tsarray || se.e1.op == EXP.string_ || se.e1.op == EXP.arrayLiteral) && se.lwr.op == EXP.int64) { *ofs = se.lwr.toInteger(); return se.e1; } } // It can be a `null` disguised as a cast, e.g. `cast(void*)0`. if (auto ie = e.isIntegerExp()) if (ie.type.ty == Tpointer && ie.getInteger() == 0) return new NullExp(ie.loc, e.type.nextOf()); // Those casts are invalid, but let the rest of the code handle it, // as it could be something like `x !is null`, which doesn't need // to dereference the pointer, even if the pointer is `cast(void*)420`. return e; } /** Return true if agg1 and agg2 are pointers to the same memory block */ bool pointToSameMemoryBlock(Expression agg1, Expression agg2) { if (agg1 == agg2) return true; // For integers cast to pointers, we regard them as non-comparable // unless they are identical. (This may be overly strict). if (agg1.op == EXP.int64 && agg2.op == EXP.int64 && agg1.toInteger() == agg2.toInteger()) { return true; } // Note that type painting can occur with VarExp, so we // must compare the variables being pointed to. if (agg1.op == EXP.variable && agg2.op == EXP.variable && agg1.isVarExp().var == agg2.isVarExp().var) { return true; } if (agg1.op == EXP.symbolOffset && agg2.op == EXP.symbolOffset && agg1.isSymOffExp().var == agg2.isSymOffExp().var) { return true; } return false; } // return e1 - e2 as an integer, or error if not possible Expression pointerDifference(UnionExp* pue, const ref 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 = (cast(TypePointer)agg1.type).next; const sz = pointee.size(); emplaceExp!(IntegerExp)(pue, loc, (ofs1 - ofs2) * sz, type); } else if (agg1.op == EXP.string_ && agg2.op == EXP.string_ && agg1.isStringExp().peekString().ptr == agg2.isStringExp().peekString().ptr) { Type pointee = (cast(TypePointer)agg1.type).next; const sz = pointee.size(); emplaceExp!(IntegerExp)(pue, loc, (ofs1 - ofs2) * sz, type); } else if (agg1.op == EXP.symbolOffset && agg2.op == EXP.symbolOffset && agg1.isSymOffExp().var == agg2.isSymOffExp().var) { emplaceExp!(IntegerExp)(pue, loc, ofs1 - ofs2, type); } else { error(loc, "`%s - %s` cannot be interpreted at compile time: cannot subtract pointers to two different memory blocks", e1.toChars(), e2.toChars()); emplaceExp!(CTFEExp)(pue, EXP.cantExpression); } return pue.exp(); } // Return eptr op e2, where eptr is a pointer, e2 is an integer, // and op is EXP.add or EXP.min Expression pointerArithmetic(UnionExp* pue, const ref Loc loc, EXP op, Type type, Expression eptr, Expression e2) { if (eptr.type.nextOf().ty == Tvoid) { error(loc, "cannot perform arithmetic on `void*` pointers at compile time"); Lcant: emplaceExp!(CTFEExp)(pue, EXP.cantExpression); return pue.exp(); } if (eptr.op == EXP.address) eptr = eptr.isAddrExp().e1; dinteger_t ofs1; Expression agg1 = getAggregateFromPointer(eptr, &ofs1); if (agg1.op == EXP.symbolOffset) { if (agg1.isSymOffExp().var.type.ty != Tsarray) { error(loc, "cannot perform pointer arithmetic on arrays of unknown length at compile time"); goto Lcant; } } else if (agg1.op != EXP.string_ && agg1.op != EXP.arrayLiteral) { error(loc, "cannot perform pointer arithmetic on non-arrays at compile time"); goto Lcant; } dinteger_t ofs2 = e2.toInteger(); Type pointee = (cast(TypeNext)agg1.type.toBasetype()).next; dinteger_t sz = pointee.size(); sinteger_t indx; dinteger_t len; if (agg1.op == EXP.symbolOffset) { indx = ofs1 / sz; len = (cast(TypeSArray)agg1.isSymOffExp().var.type).dim.toInteger(); } else { Expression dollar = ArrayLength(Type.tsize_t, agg1).copy(); assert(!CTFEExp.isCantExp(dollar)); indx = ofs1; len = dollar.toInteger(); } if (op == EXP.add || op == EXP.addAssign || op == EXP.plusPlus) indx += ofs2 / sz; else if (op == EXP.min || op == EXP.minAssign || op == EXP.minusMinus) indx -= ofs2 / sz; else { error(loc, "CTFE internal error: bad pointer operation"); goto Lcant; } if (indx < 0 || len < indx) { error(loc, "cannot assign pointer to index %lld inside memory block `[0..%lld]`", indx, len); goto Lcant; } if (agg1.op == EXP.symbolOffset) { emplaceExp!(SymOffExp)(pue, loc, agg1.isSymOffExp().var, indx * sz); SymOffExp se = pue.exp().isSymOffExp(); se.type = type; return pue.exp(); } if (agg1.op != EXP.arrayLiteral && agg1.op != EXP.string_) { error(loc, "CTFE internal error: pointer arithmetic `%s`", agg1.toChars()); goto Lcant; } if (eptr.type.toBasetype().ty == Tsarray) { dinteger_t dim = (cast(TypeSArray)eptr.type.toBasetype()).dim.toInteger(); // Create a CTFE pointer &agg1[indx .. indx+dim] auto se = ctfeEmplaceExp!SliceExp(loc, agg1, ctfeEmplaceExp!IntegerExp(loc, indx, Type.tsize_t), ctfeEmplaceExp!IntegerExp(loc, indx + dim, Type.tsize_t)); se.type = type.toBasetype().nextOf(); emplaceExp!(AddrExp)(pue, loc, se); pue.exp().type = type; return pue.exp(); } // Create a CTFE pointer &agg1[indx] auto ofs = ctfeEmplaceExp!IntegerExp(loc, indx, Type.tsize_t); Expression ie = ctfeEmplaceExp!IndexExp(loc, agg1, ofs); ie.type = type.toBasetype().nextOf(); // https://issues.dlang.org/show_bug.cgi?id=13992 emplaceExp!(AddrExp)(pue, loc, ie); pue.exp().type = type; return pue.exp(); } // Return 1 if true, 0 if false // -1 if comparison is illegal because they point to non-comparable memory blocks int comparePointers(EXP op, Expression agg1, dinteger_t ofs1, Expression agg2, dinteger_t ofs2) { if (pointToSameMemoryBlock(agg1, agg2)) { int n; switch (op) { case EXP.lessThan: n = (ofs1 < ofs2); break; case EXP.lessOrEqual: n = (ofs1 <= ofs2); break; case EXP.greaterThan: n = (ofs1 > ofs2); break; case EXP.greaterOrEqual: n = (ofs1 >= ofs2); break; case EXP.identity: case EXP.equal: n = (ofs1 == ofs2); break; case EXP.notIdentity: case EXP.notEqual: n = (ofs1 != ofs2); break; default: assert(0); } return n; } const null1 = (agg1.op == EXP.null_); const null2 = (agg2.op == EXP.null_); int cmp; if (null1 || null2) { switch (op) { case EXP.lessThan: cmp = null1 && !null2; break; case EXP.greaterThan: cmp = !null1 && null2; break; case EXP.lessOrEqual: cmp = null1; break; case EXP.greaterOrEqual: cmp = null2; break; case EXP.identity: case EXP.equal: case EXP.notIdentity: // 'cmp' gets inverted below case EXP.notEqual: cmp = (null1 == null2); break; default: assert(0); } } else { switch (op) { case EXP.identity: case EXP.equal: case EXP.notIdentity: // 'cmp' gets inverted below case EXP.notEqual: cmp = 0; break; default: return -1; // memory blocks are different } } if (op == EXP.notIdentity || op == EXP.notEqual) cmp ^= 1; return cmp; } // True if conversion from type 'from' to 'to' involves a reinterpret_cast // floating point -> integer or integer -> floating point bool isFloatIntPaint(Type to, Type from) { return from.size() == to.size() && (from.isintegral() && to.isfloating() || from.isfloating() && to.isintegral()); } // Reinterpret float/int value 'fromVal' as a float/integer of type 'to'. Expression paintFloatInt(UnionExp* pue, Expression fromVal, Type to) { if (exceptionOrCantInterpret(fromVal)) return fromVal; assert(to.size() == 4 || to.size() == 8); return Compiler.paintAsType(pue, fromVal, to); } /******** Constant folding, with support for CTFE ***************************/ /// Return true if non-pointer expression e can be compared /// with >,is, ==, etc, using ctfeCmp, ctfeEqual, ctfeIdentity bool isCtfeComparable(Expression e) { if (e.op == EXP.slice) e = e.isSliceExp().e1; if (e.isConst() != 1) { if (e.op == EXP.null_ || e.op == EXP.string_ || e.op == EXP.function_ || e.op == EXP.delegate_ || e.op == EXP.arrayLiteral || e.op == EXP.structLiteral || e.op == EXP.assocArrayLiteral || e.op == EXP.classReference) { return true; } // https://issues.dlang.org/show_bug.cgi?id=14123 // TypeInfo object is comparable in CTFE if (e.op == EXP.typeid_) return true; return false; } return true; } /// Map EXP comparison ops private bool numCmp(N)(EXP op, N n1, N n2) { switch (op) { case EXP.lessThan: return n1 < n2; case EXP.lessOrEqual: return n1 <= n2; case EXP.greaterThan: return n1 > n2; case EXP.greaterOrEqual: return n1 >= n2; default: assert(0); } } /// Returns cmp OP 0; where OP is ==, !=, <, >=, etc. Result is 0 or 1 bool specificCmp(EXP op, int rawCmp) { return numCmp!int(op, rawCmp, 0); } /// Returns e1 OP e2; where OP is ==, !=, <, >=, etc. Result is 0 or 1 bool intUnsignedCmp(EXP op, dinteger_t n1, dinteger_t n2) { return numCmp!dinteger_t(op, n1, n2); } /// Returns e1 OP e2; where OP is ==, !=, <, >=, etc. Result is 0 or 1 bool intSignedCmp(EXP op, sinteger_t n1, sinteger_t n2) { return numCmp!sinteger_t(op, n1, n2); } /// Returns e1 OP e2; where OP is ==, !=, <, >=, etc. Result is 0 or 1 bool realCmp(EXP op, real_t r1, real_t r2) { // Don't rely on compiler, handle NAN arguments separately if (CTFloat.isNaN(r1) || CTFloat.isNaN(r2)) // if unordered { switch (op) { case EXP.lessThan: case EXP.lessOrEqual: case EXP.greaterThan: case EXP.greaterOrEqual: return false; default: assert(0); } } else { return numCmp!real_t(op, r1, r2); } } /* Conceptually the same as memcmp(e1, e2). * e1 and e2 may be strings, arrayliterals, or slices. * For string types, return <0 if e1 < e2, 0 if e1==e2, >0 if e1 > e2. * For all other types, return 0 if e1 == e2, !=0 if e1 != e2. * Returns: * -1,0,1 */ private int ctfeCmpArrays(const ref Loc loc, Expression e1, Expression e2, uinteger_t len) { // Resolve slices, if necessary uinteger_t lo1 = 0; uinteger_t lo2 = 0; Expression x1 = e1; if (auto sle1 = x1.isSliceExp()) { lo1 = sle1.lwr.toInteger(); x1 = sle1.e1; } auto se1 = x1.isStringExp(); auto ae1 = x1.isArrayLiteralExp(); Expression x2 = e2; if (auto sle2 = x2.isSliceExp()) { lo2 = sle2.lwr.toInteger(); x2 = sle2.e1; } auto se2 = x2.isStringExp(); auto ae2 = x2.isArrayLiteralExp(); // Now both must be either EXP.arrayLiteral or EXP.string_ if (se1 && se2) return sliceCmpStringWithString(se1, se2, cast(size_t)lo1, cast(size_t)lo2, cast(size_t)len); if (se1 && ae2) return sliceCmpStringWithArray(se1, ae2, cast(size_t)lo1, cast(size_t)lo2, cast(size_t)len); if (se2 && ae1) return -sliceCmpStringWithArray(se2, ae1, cast(size_t)lo2, cast(size_t)lo1, cast(size_t)len); assert(ae1 && ae2); // Comparing two array literals. This case is potentially recursive. // If they aren't strings, we just need an equality check rather than // a full cmp. const bool needCmp = ae1.type.nextOf().isintegral(); foreach (size_t i; 0 .. cast(size_t)len) { Expression ee1 = (*ae1.elements)[cast(size_t)(lo1 + i)]; Expression ee2 = (*ae2.elements)[cast(size_t)(lo2 + i)]; if (needCmp) { const sinteger_t c = ee1.toInteger() - ee2.toInteger(); if (c > 0) return 1; if (c < 0) return -1; } else { if (ctfeRawCmp(loc, ee1, ee2)) return 1; } } return 0; } /* Given a delegate expression e, return .funcptr. * If e is NullExp, return NULL. */ private FuncDeclaration funcptrOf(Expression e) { assert(e.type.ty == Tdelegate); if (auto de = e.isDelegateExp()) return de.func; if (auto fe = e.isFuncExp()) return fe.fd; assert(e.op == EXP.null_); return null; } private bool isArray(const Expression e) { return e.op == EXP.arrayLiteral || e.op == EXP.string_ || e.op == EXP.slice || e.op == EXP.null_; } /***** * Params: * loc = source file location * e1 = left operand * e2 = right operand * identity = true for `is` identity comparisons * Returns: * For strings, return <0 if e1 < e2, 0 if e1==e2, >0 if e1 > e2. * For all other types, return 0 if e1 == e2, !=0 if e1 != e2. */ private int ctfeRawCmp(const ref Loc loc, Expression e1, Expression e2, bool identity = false) { if (e1.op == EXP.classReference || e2.op == EXP.classReference) { if (e1.op == EXP.classReference && e2.op == EXP.classReference && e1.isClassReferenceExp().value == e2.isClassReferenceExp().value) return 0; return 1; } if (e1.op == EXP.typeid_ && e2.op == EXP.typeid_) { // printf("e1: %s\n", e1.toChars()); // printf("e2: %s\n", e2.toChars()); Type t1 = isType(e1.isTypeidExp().obj); Type t2 = isType(e2.isTypeidExp().obj); assert(t1); assert(t2); return t1 != t2; } // null == null, regardless of type if (e1.op == EXP.null_ && e2.op == EXP.null_) return 0; if (e1.type.ty == Tpointer && e2.type.ty == Tpointer) { // Can only be an equality test. dinteger_t ofs1, ofs2; Expression agg1 = getAggregateFromPointer(e1, &ofs1); Expression agg2 = getAggregateFromPointer(e2, &ofs2); if ((agg1 == agg2) || (agg1.op == EXP.variable && agg2.op == EXP.variable && agg1.isVarExp().var == agg2.isVarExp().var)) { if (ofs1 == ofs2) return 0; } return 1; } if (e1.type.ty == Tdelegate && e2.type.ty == Tdelegate) { // If .funcptr isn't the same, they are not equal if (funcptrOf(e1) != funcptrOf(e2)) return 1; // If both are delegate literals, assume they have the // same closure pointer. TODO: We don't support closures yet! if (e1.op == EXP.function_ && e2.op == EXP.function_) return 0; assert(e1.op == EXP.delegate_ && e2.op == EXP.delegate_); // Same .funcptr. Do they have the same .ptr? Expression ptr1 = e1.isDelegateExp().e1; Expression ptr2 = e2.isDelegateExp().e1; dinteger_t ofs1, ofs2; Expression agg1 = getAggregateFromPointer(ptr1, &ofs1); Expression agg2 = getAggregateFromPointer(ptr2, &ofs2); // If they are EXP.variable, it means they are FuncDeclarations if ((agg1 == agg2 && ofs1 == ofs2) || (agg1.op == EXP.variable && agg2.op == EXP.variable && agg1.isVarExp().var == agg2.isVarExp().var)) { return 0; } return 1; } if (isArray(e1) && isArray(e2)) { const uinteger_t len1 = resolveArrayLength(e1); const uinteger_t len2 = resolveArrayLength(e2); // workaround for dmc optimizer bug calculating wrong len for // uinteger_t len = (len1 < len2 ? len1 : len2); // if (len == 0) ... if (len1 > 0 && len2 > 0) { const uinteger_t len = (len1 < len2 ? len1 : len2); const int res = ctfeCmpArrays(loc, e1, e2, len); if (res != 0) return res; } return cast(int)(len1 - len2); } if (e1.type.isintegral()) { return e1.toInteger() != e2.toInteger(); } if (e1.type.isreal() || e1.type.isimaginary()) { real_t r1 = e1.type.isreal() ? e1.toReal() : e1.toImaginary(); real_t r2 = e1.type.isreal() ? e2.toReal() : e2.toImaginary(); if (identity) return !CTFloat.isIdentical(r1, r2); if (CTFloat.isNaN(r1) || CTFloat.isNaN(r2)) // if unordered { return 1; // they are not equal } else { return (r1 != r2); } } else if (e1.type.iscomplex()) { auto c1 = e1.toComplex(); auto c2 = e2.toComplex(); if (identity) { return !RealIdentical(c1.re, c2.re) && !RealIdentical(c1.im, c2.im); } return c1 != c2; } if (e1.op == EXP.structLiteral && e2.op == EXP.structLiteral) { StructLiteralExp es1 = e1.isStructLiteralExp(); StructLiteralExp es2 = e2.isStructLiteralExp(); // For structs, we only need to return 0 or 1 (< and > aren't legal). if (es1.sd != es2.sd) return 1; else if ((!es1.elements || !es1.elements.dim) && (!es2.elements || !es2.elements.dim)) return 0; // both arrays are empty else if (!es1.elements || !es2.elements) return 1; else if (es1.elements.dim != es2.elements.dim) return 1; else { foreach (size_t i; 0 .. es1.elements.dim) { Expression ee1 = (*es1.elements)[i]; Expression ee2 = (*es2.elements)[i]; // https://issues.dlang.org/show_bug.cgi?id=16284 if (ee1.op == EXP.void_ && ee2.op == EXP.void_) // if both are VoidInitExp continue; if (ee1 == ee2) continue; if (!ee1 || !ee2) return 1; const int cmp = ctfeRawCmp(loc, ee1, ee2, identity); if (cmp) return 1; } return 0; // All elements are equal } } if (e1.op == EXP.assocArrayLiteral && e2.op == EXP.assocArrayLiteral) { AssocArrayLiteralExp es1 = e1.isAssocArrayLiteralExp(); AssocArrayLiteralExp es2 = e2.isAssocArrayLiteralExp(); size_t dim = es1.keys.dim; if (es2.keys.dim != dim) return 1; bool* used = cast(bool*)mem.xmalloc(bool.sizeof * dim); memset(used, 0, bool.sizeof * dim); foreach (size_t i; 0 .. dim) { Expression k1 = (*es1.keys)[i]; Expression v1 = (*es1.values)[i]; Expression v2 = null; foreach (size_t j; 0 .. dim) { if (used[j]) continue; Expression k2 = (*es2.keys)[j]; if (ctfeRawCmp(loc, k1, k2, identity)) continue; used[j] = true; v2 = (*es2.values)[j]; break; } if (!v2 || ctfeRawCmp(loc, v1, v2, identity)) { mem.xfree(used); return 1; } } mem.xfree(used); return 0; } else if (e1.op == EXP.assocArrayLiteral && e2.op == EXP.null_) { return e1.isAssocArrayLiteralExp.keys.dim != 0; } else if (e1.op == EXP.null_ && e2.op == EXP.assocArrayLiteral) { return e2.isAssocArrayLiteralExp.keys.dim != 0; } error(loc, "CTFE internal error: bad compare of `%s` and `%s`", e1.toChars(), e2.toChars()); assert(0); } /// Evaluate ==, !=. Resolves slices before comparing. Returns 0 or 1 bool ctfeEqual(const ref Loc loc, EXP op, Expression e1, Expression e2) { return !ctfeRawCmp(loc, e1, e2) ^ (op == EXP.notEqual); } /// Evaluate is, !is. Resolves slices before comparing. Returns 0 or 1 bool ctfeIdentity(const ref Loc loc, EXP op, Expression e1, Expression e2) { //printf("ctfeIdentity %s %s\n", e1.toChars(), e2.toChars()); //printf("ctfeIdentity op = '%s', e1 = %s %s, e2 = %s %s\n", EXPtoString(op).ptr, // EXPtoString(e1.op).ptr, e1.toChars(), EXPtoString(e2.op).ptr, e1.toChars()); bool cmp; if (e1.op == EXP.null_) { cmp = (e2.op == EXP.null_); } else if (e2.op == EXP.null_) { cmp = false; } else if (e1.op == EXP.symbolOffset && e2.op == EXP.symbolOffset) { SymOffExp es1 = e1.isSymOffExp(); SymOffExp es2 = e2.isSymOffExp(); cmp = (es1.var == es2.var && es1.offset == es2.offset); } else if (e1.type.isreal()) cmp = CTFloat.isIdentical(e1.toReal(), e2.toReal()); else if (e1.type.isimaginary()) cmp = RealIdentical(e1.toImaginary(), e2.toImaginary()); else if (e1.type.iscomplex()) { complex_t v1 = e1.toComplex(); complex_t v2 = e2.toComplex(); cmp = RealIdentical(creall(v1), creall(v2)) && RealIdentical(cimagl(v1), cimagl(v1)); } else { cmp = !ctfeRawCmp(loc, e1, e2, true); } if (op == EXP.notIdentity || op == EXP.notEqual) cmp ^= true; return cmp; } /// Evaluate >,<=, etc. Resolves slices before comparing. Returns 0 or 1 bool ctfeCmp(const ref Loc loc, EXP op, Expression e1, Expression e2) { Type t1 = e1.type.toBasetype(); Type t2 = e2.type.toBasetype(); if (t1.isString() && t2.isString()) return specificCmp(op, ctfeRawCmp(loc, e1, e2)); else if (t1.isreal()) return realCmp(op, e1.toReal(), e2.toReal()); else if (t1.isimaginary()) return realCmp(op, e1.toImaginary(), e2.toImaginary()); else if (t1.isunsigned() || t2.isunsigned()) return intUnsignedCmp(op, e1.toInteger(), e2.toInteger()); else return intSignedCmp(op, e1.toInteger(), e2.toInteger()); } UnionExp ctfeCat(const ref Loc loc, Type type, Expression e1, Expression e2) { Type t1 = e1.type.toBasetype(); Type t2 = e2.type.toBasetype(); UnionExp ue; if (e2.op == EXP.string_ && e1.op == EXP.arrayLiteral && t1.nextOf().isintegral()) { // [chars] ~ string => string (only valid for CTFE) StringExp es1 = e2.isStringExp(); ArrayLiteralExp es2 = e1.isArrayLiteralExp(); const len = es1.len + es2.elements.dim; const sz = es1.sz; void* s = mem.xmalloc((len + 1) * sz); const data1 = es1.peekData(); memcpy(cast(char*)s + sz * es2.elements.dim, data1.ptr, data1.length); foreach (size_t i; 0 .. es2.elements.dim) { Expression es2e = (*es2.elements)[i]; if (es2e.op != EXP.int64) { emplaceExp!(CTFEExp)(&ue, EXP.cantExpression); return ue; } dinteger_t v = es2e.toInteger(); Port.valcpy(cast(char*)s + i * sz, v, sz); } // Add terminating 0 memset(cast(char*)s + len * sz, 0, sz); emplaceExp!(StringExp)(&ue, loc, s[0 .. len * sz], len, sz); StringExp es = ue.exp().isStringExp(); es.committed = 0; es.type = type; return ue; } if (e1.op == EXP.string_ && e2.op == EXP.arrayLiteral && t2.nextOf().isintegral()) { // string ~ [chars] => string (only valid for CTFE) // Concatenate the strings StringExp es1 = e1.isStringExp(); ArrayLiteralExp es2 = e2.isArrayLiteralExp(); const len = es1.len + es2.elements.dim; const sz = es1.sz; void* s = mem.xmalloc((len + 1) * sz); auto slice = es1.peekData(); memcpy(s, slice.ptr, slice.length); foreach (size_t i; 0 .. es2.elements.dim) { Expression es2e = (*es2.elements)[i]; if (es2e.op != EXP.int64) { emplaceExp!(CTFEExp)(&ue, EXP.cantExpression); return ue; } const v = es2e.toInteger(); Port.valcpy(cast(char*)s + (es1.len + i) * sz, v, sz); } // Add terminating 0 memset(cast(char*)s + len * sz, 0, sz); emplaceExp!(StringExp)(&ue, loc, s[0 .. len * sz], len, sz); StringExp es = ue.exp().isStringExp(); es.sz = sz; es.committed = 0; //es1.committed; es.type = type; return ue; } if (e1.op == EXP.arrayLiteral && e2.op == EXP.arrayLiteral && t1.nextOf().equals(t2.nextOf())) { // [ e1 ] ~ [ e2 ] ---> [ e1, e2 ] ArrayLiteralExp es1 = e1.isArrayLiteralExp(); ArrayLiteralExp es2 = e2.isArrayLiteralExp(); emplaceExp!(ArrayLiteralExp)(&ue, es1.loc, type, copyLiteralArray(es1.elements)); es1 = ue.exp().isArrayLiteralExp(); es1.elements.insert(es1.elements.dim, copyLiteralArray(es2.elements)); return ue; } if (e1.op == EXP.arrayLiteral && e2.op == EXP.null_ && t1.nextOf().equals(t2.nextOf())) { // [ e1 ] ~ null ----> [ e1 ].dup ue = paintTypeOntoLiteralCopy(type, copyLiteral(e1).copy()); return ue; } if (e1.op == EXP.null_ && e2.op == EXP.arrayLiteral && t1.nextOf().equals(t2.nextOf())) { // null ~ [ e2 ] ----> [ e2 ].dup ue = paintTypeOntoLiteralCopy(type, copyLiteral(e2).copy()); return ue; } ue = Cat(loc, type, e1, e2); return ue; } /* Given an AA literal 'ae', and a key 'e2': * Return ae[e2] if present, or NULL if not found. */ Expression findKeyInAA(const ref 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)[i]; const int eq = ctfeEqual(loc, EXP.equal, ekey, e2); if (eq) { return (*ae.values)[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(UnionExp* pue, const ref Loc loc, Type type, Expression e1, uinteger_t indx) { //printf("ctfeIndex(e1 = %s)\n", e1.toChars()); assert(e1.type); if (auto es1 = e1.isStringExp()) { if (indx >= es1.len) { error(loc, "string index %llu is out of bounds `[0 .. %llu]`", indx, cast(ulong)es1.len); return CTFEExp.cantexp; } emplaceExp!IntegerExp(pue, loc, es1.getCodeUnit(cast(size_t) indx), type); return pue.exp(); } if (auto ale = e1.isArrayLiteralExp()) { if (indx >= ale.elements.dim) { error(loc, "array index %llu is out of bounds `%s[0 .. %llu]`", indx, e1.toChars(), cast(ulong)ale.elements.dim); return CTFEExp.cantexp; } Expression e = (*ale.elements)[cast(size_t)indx]; return paintTypeOntoLiteral(pue, type, e); } assert(0); } Expression ctfeCast(UnionExp* pue, const ref Loc loc, Type type, Type to, Expression e, bool explicitCast = false) { Expression paint() { return paintTypeOntoLiteral(pue, to, e); } if (e.op == EXP.null_) return paint(); if (e.op == EXP.classReference) { // Disallow reinterpreting class casts. Do this by ensuring that // the original class can implicitly convert to the target class. // Also do not check 'alias this' for explicit cast expressions. auto tclass = e.isClassReferenceExp().originalClass().type.isTypeClass(); auto match = explicitCast ? tclass.implicitConvToWithoutAliasThis(to.mutableOf()) : tclass.implicitConvTo(to.mutableOf()); if (match) return paint(); else { emplaceExp!(NullExp)(pue, loc, to); return pue.exp(); } } // Allow TypeInfo type painting if (isTypeInfo_Class(e.type) && e.type.implicitConvTo(to)) return paint(); // Allow casting away const for struct literals if (e.op == EXP.structLiteral && e.type.toBasetype().castMod(0) == to.toBasetype().castMod(0)) return paint(); Expression r; if (e.type.equals(type) && type.equals(to)) { // necessary not to change e's address for pointer comparisons r = e; } else if (to.toBasetype().ty == Tarray && type.toBasetype().ty == Tarray && to.toBasetype().nextOf().size() == type.toBasetype().nextOf().size()) { // https://issues.dlang.org/show_bug.cgi?id=12495 // Array reinterpret casts: eg. string to immutable(ubyte)[] return paint(); } else { *pue = Cast(loc, type, to, e); r = pue.exp(); } if (CTFEExp.isCantExp(r)) error(loc, "cannot cast `%s` to `%s` at compile time", e.toChars(), to.toChars()); if (auto ae = e.isArrayLiteralExp()) ae.ownedByCtfe = OwnedBy.ctfe; if (auto se = e.isStringExp()) se.ownedByCtfe = OwnedBy.ctfe; return r; } /******** Assignment helper functions ***************************/ /* 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) { if (!(dest.op == EXP.structLiteral || dest.op == EXP.arrayLiteral || dest.op == EXP.string_)) { printf("invalid op %d %d\n", src.op, dest.op); assert(0); } Expressions* oldelems; Expressions* newelems; if (dest.op == EXP.structLiteral) { assert(dest.op == src.op); oldelems = dest.isStructLiteralExp().elements; newelems = src.isStructLiteralExp().elements; auto sd = dest.isStructLiteralExp().sd; const nfields = sd.nonHiddenFields(); const nvthis = sd.fields.dim - nfields; if (nvthis && oldelems.dim >= nfields && oldelems.dim < newelems.dim) foreach (_; 0 .. newelems.dim - oldelems.dim) oldelems.push(null); } else if (dest.op == EXP.arrayLiteral && src.op == EXP.arrayLiteral) { oldelems = dest.isArrayLiteralExp().elements; newelems = src.isArrayLiteralExp().elements; } else if (dest.op == EXP.string_ && src.op == EXP.string_) { sliceAssignStringFromString(dest.isStringExp(), src.isStringExp(), 0); return; } else if (dest.op == EXP.arrayLiteral && src.op == EXP.string_) { sliceAssignArrayLiteralFromString(dest.isArrayLiteralExp(), src.isStringExp(), 0); return; } else if (src.op == EXP.arrayLiteral && dest.op == EXP.string_) { sliceAssignStringFromArrayLiteral(dest.isStringExp(), src.isArrayLiteralExp(), 0); return; } else { printf("invalid op %d %d\n", src.op, dest.op); assert(0); } assert(oldelems.dim == newelems.dim); foreach (size_t i; 0 .. oldelems.dim) { Expression e = (*newelems)[i]; Expression o = (*oldelems)[i]; if (e.op == EXP.structLiteral) { assert(o.op == e.op); assignInPlace(o, e); } else if (e.type.ty == Tsarray && e.op != EXP.void_ && o.type.ty == Tsarray) { assignInPlace(o, e); } else { (*oldelems)[i] = (*newelems)[i]; } } } // Given an AA literal aae, set aae[index] = newval and return newval. Expression assignAssocArrayElement(const ref 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)[j]; int eq = ctfeEqual(loc, EXP.equal, ekey, index); if (eq) { (*valuesx)[j] = newval; updated = 1; } } if (!updated) { // Append index/newval to keysx[]/valuesx[] valuesx.push(newval); keysx.push(index); } return newval; } /// Given array literal oldval of type ArrayLiteralExp or StringExp, of length /// oldlen, change its length to newlen. If the newlen is longer than oldlen, /// all new elements will be set to the default initializer for the element type. Expression changeArrayLiteralLength(UnionExp* pue, const ref Loc loc, TypeArray arrayType, Expression oldval, size_t oldlen, size_t newlen) { Type elemType = arrayType.next; assert(elemType); Expression defaultElem = elemType.defaultInitLiteral(loc); auto elements = new Expressions(newlen); // Resolve slices size_t indxlo = 0; if (oldval.op == EXP.slice) { indxlo = cast(size_t)oldval.isSliceExp().lwr.toInteger(); oldval = oldval.isSliceExp().e1; } size_t copylen = oldlen < newlen ? oldlen : newlen; if (oldval.op == EXP.string_) { StringExp oldse = oldval.isStringExp(); void* s = mem.xcalloc(newlen + 1, oldse.sz); const data = oldse.peekData(); memcpy(s, data.ptr, copylen * oldse.sz); const defaultValue = cast(uint)defaultElem.toInteger(); foreach (size_t elemi; copylen .. newlen) { switch (oldse.sz) { case 1: (cast(char*)s)[cast(size_t)(indxlo + elemi)] = cast(char)defaultValue; break; case 2: (cast(wchar*)s)[cast(size_t)(indxlo + elemi)] = cast(wchar)defaultValue; break; case 4: (cast(dchar*)s)[cast(size_t)(indxlo + elemi)] = cast(dchar)defaultValue; break; default: assert(0); } } emplaceExp!(StringExp)(pue, loc, s[0 .. newlen * oldse.sz], newlen, oldse.sz); StringExp se = pue.exp().isStringExp(); se.type = arrayType; se.sz = oldse.sz; se.committed = oldse.committed; se.ownedByCtfe = OwnedBy.ctfe; } else { if (oldlen != 0) { assert(oldval.op == EXP.arrayLiteral); ArrayLiteralExp ae = oldval.isArrayLiteralExp(); foreach (size_t i; 0 .. copylen) (*elements)[i] = (*ae.elements)[indxlo + 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 */ foreach (size_t i; copylen .. newlen) (*elements)[i] = copyLiteral(defaultElem).copy(); } else { foreach (size_t i; copylen .. newlen) (*elements)[i] = defaultElem; } emplaceExp!(ArrayLiteralExp)(pue, loc, arrayType, elements); ArrayLiteralExp aae = pue.exp().isArrayLiteralExp(); aae.ownedByCtfe = OwnedBy.ctfe; } return pue.exp(); } /*************************** CTFE Sanity Checks ***************************/ bool isCtfeValueValid(Expression newval) { Type tb = newval.type.toBasetype(); switch (newval.op) { case EXP.int64: case EXP.float64: case EXP.char_: case EXP.complex80: return tb.isscalar(); case EXP.null_: return tb.ty == Tnull || tb.ty == Tpointer || tb.ty == Tarray || tb.ty == Taarray || tb.ty == Tclass || tb.ty == Tdelegate; case EXP.string_: return true; // CTFE would directly use the StringExp in AST. case EXP.arrayLiteral: return true; //((ArrayLiteralExp *)newval)->ownedByCtfe; case EXP.assocArrayLiteral: return true; //((AssocArrayLiteralExp *)newval)->ownedByCtfe; case EXP.structLiteral: return true; //((StructLiteralExp *)newval)->ownedByCtfe; case EXP.classReference: return true; case EXP.type: return true; case EXP.vector: return true; // vector literal case EXP.function_: return true; // function literal or delegate literal case EXP.delegate_: { // &struct.func or &clasinst.func // &nestedfunc Expression ethis = newval.isDelegateExp().e1; return (ethis.op == EXP.structLiteral || ethis.op == EXP.classReference || ethis.op == EXP.variable && ethis.isVarExp().var == newval.isDelegateExp().func); } case EXP.symbolOffset: { // function pointer, or pointer to static variable Declaration d = newval.isSymOffExp().var; return d.isFuncDeclaration() || d.isDataseg(); } case EXP.typeid_: { // always valid return true; } case EXP.address: { // e1 should be a CTFE reference Expression e1 = newval.isAddrExp().e1; return tb.ty == Tpointer && ( (e1.op == EXP.structLiteral || e1.op == EXP.arrayLiteral) && isCtfeValueValid(e1) || e1.op == EXP.variable || e1.op == EXP.dotVariable && isCtfeReferenceValid(e1) || e1.op == EXP.index && isCtfeReferenceValid(e1) || e1.op == EXP.slice && e1.type.toBasetype().ty == Tsarray ); } case EXP.slice: { // e1 should be an array aggregate const SliceExp se = newval.isSliceExp(); assert(se.lwr && se.lwr.op == EXP.int64); assert(se.upr && se.upr.op == EXP.int64); return (tb.ty == Tarray || tb.ty == Tsarray) && (se.e1.op == EXP.string_ || se.e1.op == EXP.arrayLiteral); } case EXP.void_: return true; // uninitialized value default: newval.error("CTFE internal error: illegal CTFE value `%s`", newval.toChars()); return false; } } bool isCtfeReferenceValid(Expression newval) { switch (newval.op) { case EXP.this_: return true; case EXP.variable: { const VarDeclaration v = newval.isVarExp().var.isVarDeclaration(); assert(v); // Must not be a reference to a reference return true; } case EXP.index: { const Expression eagg = newval.isIndexExp().e1; return eagg.op == EXP.string_ || eagg.op == EXP.arrayLiteral || eagg.op == EXP.assocArrayLiteral; } case EXP.dotVariable: { Expression eagg = newval.isDotVarExp().e1; return (eagg.op == EXP.structLiteral || eagg.op == EXP.classReference) && isCtfeValueValid(eagg); } default: // Internally a ref variable may directly point a stack memory. // e.g. ref int v = 1; return isCtfeValueValid(newval); } } // 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 == EXP.structLiteral) { elements = e.isStructLiteralExp().elements; sd = e.isStructLiteralExp().sd; printf("STRUCT type = %s %p:\n", e.type.toChars(), e); } else if (e.op == EXP.classReference) { elements = e.isClassReferenceExp().value.elements; cd = e.isClassReferenceExp().originalClass(); printf("CLASS type = %s %p:\n", e.type.toChars(), e.isClassReferenceExp().value); } else if (e.op == EXP.arrayLiteral) { elements = e.isArrayLiteralExp().elements; printf("ARRAY LITERAL type=%s %p:\n", e.type.toChars(), e); } else if (e.op == EXP.assocArrayLiteral) { printf("AA LITERAL type=%s %p:\n", e.type.toChars(), e); } else if (e.op == EXP.string_) { printf("STRING %s %p\n", e.toChars(), e.isStringExp.peekString.ptr); } else if (e.op == EXP.slice) { printf("SLICE %p: %s\n", e, e.toChars()); showCtfeExpr(e.isSliceExp().e1, level + 1); } else if (e.op == EXP.variable) { printf("VAR %p %s\n", e, e.toChars()); VarDeclaration v = e.isVarExp().var.isVarDeclaration(); if (v && getValue(v)) showCtfeExpr(getValue(v), level + 1); } else if (e.op == EXP.address) { // This is potentially recursive. We mustn't try to print the thing we're pointing to. printf("POINTER %p to %p: %s\n", e, e.isAddrExp().e1, 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; VarDeclaration v = null; if (i > 15) { printf("...(total %d elements)\n", cast(int)elements.dim); return; } if (sd) { v = sd.fields[i]; z = (*elements)[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()); } v = cd.fields[i - fieldsSoFar]; assert((elements.dim + i) >= (fieldsSoFar + cd.fields.dim)); size_t indx = (elements.dim - fieldsSoFar) - cd.fields.dim + i; assert(indx < elements.dim); z = (*elements)[indx]; } if (!z) { for (int j = level; j > 0; --j) printf(" "); printf(" void\n"); continue; } if (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 initialized static array\n"); continue; } } showCtfeExpr(z, level + 1); } } } /*************************** Void initialization ***************************/ UnionExp voidInitLiteral(Type t, VarDeclaration var) { UnionExp ue; if (t.ty == Tsarray) { TypeSArray tsa = cast(TypeSArray)t; Expression elem = voidInitLiteral(tsa.next, var).copy(); // For aggregate value types (structs, static arrays) we must // create an a separate copy for each element. const mustCopy = (elem.op == EXP.arrayLiteral || elem.op == EXP.structLiteral); const d = cast(size_t)tsa.dim.toInteger(); auto elements = new Expressions(d); foreach (i; 0 .. d) { if (mustCopy && i > 0) elem = copyLiteral(elem).copy(); (*elements)[i] = elem; } emplaceExp!(ArrayLiteralExp)(&ue, var.loc, tsa, elements); ArrayLiteralExp ae = ue.exp().isArrayLiteralExp(); ae.ownedByCtfe = OwnedBy.ctfe; } else if (t.ty == Tstruct) { TypeStruct ts = cast(TypeStruct)t; auto exps = new Expressions(ts.sym.fields.dim); foreach (size_t i; 0 .. ts.sym.fields.dim) { (*exps)[i] = voidInitLiteral(ts.sym.fields[i].type, ts.sym.fields[i]).copy(); } emplaceExp!(StructLiteralExp)(&ue, var.loc, ts.sym, exps); StructLiteralExp se = ue.exp().isStructLiteralExp(); se.type = ts; se.ownedByCtfe = OwnedBy.ctfe; } else emplaceExp!(VoidInitExp)(&ue, var); return ue; }