/*****************************************************************************/ /* */ /* function.c */ /* */ /* Parse function entry/body/exit */ /* */ /* */ /* */ /* (C) 2000-2012, Ullrich von Bassewitz */ /* Roemerstrasse 52 */ /* D-70794 Filderstadt */ /* EMail: uz@cc65.org */ /* */ /* */ /* This software is provided 'as-is', without any expressed or implied */ /* warranty. In no event will the authors be held liable for any damages */ /* arising from the use of this software. */ /* */ /* Permission is granted to anyone to use this software for any purpose, */ /* including commercial applications, and to alter it and redistribute it */ /* freely, subject to the following restrictions: */ /* */ /* 1. The origin of this software must not be misrepresented; you must not */ /* claim that you wrote the original software. If you use this software */ /* in a product, an acknowledgment in the product documentation would be */ /* appreciated but is not required. */ /* 2. Altered source versions must be plainly marked as such, and must not */ /* be misrepresented as being the original software. */ /* 3. This notice may not be removed or altered from any source */ /* distribution. */ /* */ /*****************************************************************************/ /* common */ #include "check.h" #include "xmalloc.h" /* cc65 */ #include "asmcode.h" #include "asmlabel.h" #include "codegen.h" #include "error.h" #include "funcdesc.h" #include "global.h" #include "litpool.h" #include "locals.h" #include "scanner.h" #include "stackptr.h" #include "standard.h" #include "stmt.h" #include "symtab.h" #include "function.h" /*****************************************************************************/ /* Data */ /*****************************************************************************/ /* Enumeration for function flags */ typedef enum { FF_NONE = 0x0000, FF_HAS_RETURN = 0x0001, /* Function has a return statement */ FF_IS_MAIN = 0x0002, /* This is the main function */ FF_VOID_RETURN = 0x0004, /* Function returning void */ } funcflags_t; /* Structure that holds all data needed for function activation */ struct Function { struct SymEntry* FuncEntry; /* Symbol table entry */ Type* ReturnType; /* Function return type */ FuncDesc* Desc; /* Function descriptor */ int Reserved; /* Reserved local space */ unsigned RetLab; /* Return code label */ int TopLevelSP; /* SP at function top level */ unsigned RegOffs; /* Register variable space offset */ funcflags_t Flags; /* Function flags */ }; /* Pointer to current function */ Function* CurrentFunc = 0; /*****************************************************************************/ /* Subroutines working with struct Function */ /*****************************************************************************/ static Function* NewFunction (struct SymEntry* Sym) /* Create a new function activation structure and return it */ { /* Allocate a new structure */ Function* F = (Function*) xmalloc (sizeof (Function)); /* Initialize the fields */ F->FuncEntry = Sym; F->ReturnType = GetFuncReturn (Sym->Type); F->Desc = GetFuncDesc (Sym->Type); F->Reserved = 0; F->RetLab = GetLocalLabel (); F->TopLevelSP = 0; F->RegOffs = RegisterSpace; F->Flags = IsTypeVoid (F->ReturnType) ? FF_VOID_RETURN : FF_NONE; /* Return the new structure */ return F; } static void FreeFunction (Function* F) /* Free a function activation structure */ { xfree (F); } const char* F_GetFuncName (const Function* F) /* Return the name of the current function */ { return F->FuncEntry->Name; } unsigned F_GetParamCount (const Function* F) /* Return the parameter count for the current function */ { return F->Desc->ParamCount; } unsigned F_GetParamSize (const Function* F) /* Return the parameter size for the current function */ { return F->Desc->ParamSize; } Type* F_GetReturnType (Function* F) /* Get the return type for the function */ { return F->ReturnType; } int F_HasVoidReturn (const Function* F) /* Return true if the function does not have a return value */ { return (F->Flags & FF_VOID_RETURN) != 0; } void F_ReturnFound (Function* F) /* Mark the function as having a return statement */ { F->Flags |= FF_HAS_RETURN; } int F_HasReturn (const Function* F) /* Return true if the function contains a return statement*/ { return (F->Flags & FF_HAS_RETURN) != 0; } int F_IsMainFunc (const Function* F) /* Return true if this is the main function */ { return (F->Flags & FF_IS_MAIN) != 0; } int F_IsVariadic (const Function* F) /* Return true if this is a variadic function */ { return (F->Desc->Flags & FD_VARIADIC) != 0; } int F_IsOldStyle (const Function* F) /* Return true if this is an old style (K&R) function */ { return (F->Desc->Flags & FD_OLDSTYLE) != 0; } int F_HasOldStyleIntRet (const Function* F) /* Return true if this is an old style (K&R) function with an implicit int return */ { return (F->Desc->Flags & FD_OLDSTYLE_INTRET) != 0; } unsigned F_GetRetLab (const Function* F) /* Return the return jump label */ { return F->RetLab; } int F_GetTopLevelSP (const Function* F) /* Get the value of the stack pointer on function top level */ { return F->TopLevelSP; } int F_ReserveLocalSpace (Function* F, unsigned Size) /* Reserve (but don't allocate) the given local space and return the stack * offset. */ { F->Reserved += Size; return StackPtr - F->Reserved; } int F_GetStackPtr (const Function* F) /* Return the current stack pointer including reserved (but not allocated) * space on the stack. */ { return StackPtr - F->Reserved; } void F_AllocLocalSpace (Function* F) /* Allocate any local space previously reserved. The function will do * nothing if there is no reserved local space. */ { if (F->Reserved > 0) { /* Create space on the stack */ g_space (F->Reserved); /* Correct the stack pointer */ StackPtr -= F->Reserved; /* Nothing more reserved */ F->Reserved = 0; } } int F_AllocRegVar (Function* F, const Type* Type) /* Allocate a register variable for the given variable type. If the allocation * was successful, return the offset of the register variable in the register * bank (zero page storage). If there is no register space left, return -1. */ { /* Allow register variables only on top level and if enabled */ if (IS_Get (&EnableRegVars) && GetLexicalLevel () == LEX_LEVEL_FUNCTION) { /* Get the size of the variable */ unsigned Size = CheckedSizeOf (Type); /* Do we have space left? */ if (F->RegOffs >= Size) { /* Space left. We allocate the variables from high to low addresses, * so the adressing is compatible with the saved values on stack. * This allows shorter code when saving/restoring the variables. */ F->RegOffs -= Size; return F->RegOffs; } } /* No space left or no allocation */ return -1; } static void F_RestoreRegVars (Function* F) /* Restore the register variables for the local function if there are any. */ { const SymEntry* Sym; /* If we don't have register variables in this function, bail out early */ if (F->RegOffs == RegisterSpace) { return; } /* Save the accumulator if needed */ if (!F_HasVoidReturn (F)) { g_save (CF_CHAR | CF_FORCECHAR); } /* Get the first symbol from the function symbol table */ Sym = F->FuncEntry->V.F.Func->SymTab->SymHead; /* Walk through all symbols checking for register variables */ while (Sym) { if (SymIsRegVar (Sym)) { /* Check for more than one variable */ int Offs = Sym->V.R.SaveOffs; unsigned Bytes = CheckedSizeOf (Sym->Type); while (1) { /* Find next register variable */ const SymEntry* NextSym = Sym->NextSym; while (NextSym && !SymIsRegVar (NextSym)) { NextSym = NextSym->NextSym; } /* If we have a next one, compare the stack offsets */ if (NextSym) { /* We have a following register variable. Get the size */ int Size = CheckedSizeOf (NextSym->Type); /* Adjacent variable? */ if (NextSym->V.R.SaveOffs + Size != Offs) { /* No */ break; } /* Adjacent variable */ Bytes += Size; Offs -= Size; Sym = NextSym; } else { break; } } /* Restore the memory range */ g_restore_regvars (Offs, Sym->V.R.RegOffs, Bytes); } /* Check next symbol */ Sym = Sym->NextSym; } /* Restore the accumulator if needed */ if (!F_HasVoidReturn (F)) { g_restore (CF_CHAR | CF_FORCECHAR); } } static void F_EmitDebugInfo (void) /* Emit debug infos for the current function */ { if (DebugInfo) { /* Get the current function */ const SymEntry* Sym = CurrentFunc->FuncEntry; /* Output info for the function itself */ AddTextLine ("\t.dbg\tfunc, \"%s\", \"00\", %s, \"%s\"", Sym->Name, (Sym->Flags & SC_EXTERN)? "extern" : "static", Sym->AsmName); } } /*****************************************************************************/ /* code */ /*****************************************************************************/ void NewFunc (SymEntry* Func) /* Parse argument declarations and function body. */ { int C99MainFunc = 0;/* Flag for C99 main function returning int */ SymEntry* Param; /* Get the function descriptor from the function entry */ FuncDesc* D = Func->V.F.Func; /* Allocate the function activation record for the function */ CurrentFunc = NewFunction (Func); /* Reenter the lexical level */ ReenterFunctionLevel (D); /* Check if the function header contains unnamed parameters. These are * only allowed in cc65 mode. */ if ((D->Flags & FD_UNNAMED_PARAMS) != 0 && (IS_Get (&Standard) != STD_CC65)) { Error ("Parameter name omitted"); } /* Declare two special functions symbols: __fixargs__ and __argsize__. * The latter is different depending on the type of the function (variadic * or not). */ AddConstSym ("__fixargs__", type_uint, SC_DEF | SC_CONST, D->ParamSize); if (D->Flags & FD_VARIADIC) { /* Variadic function. The variable must be const. */ static const Type T[] = { TYPE(T_UCHAR | T_QUAL_CONST), TYPE(T_END) }; AddLocalSym ("__argsize__", T, SC_DEF | SC_REF | SC_AUTO, 0); } else { /* Non variadic */ AddConstSym ("__argsize__", type_uchar, SC_DEF | SC_CONST, D->ParamSize); } /* Function body now defined */ Func->Flags |= SC_DEF; /* Special handling for main() */ if (strcmp (Func->Name, "main") == 0) { /* Mark this as the main function */ CurrentFunc->Flags |= FF_IS_MAIN; /* Main cannot be a fastcall function */ if (IsQualFastcall (Func->Type)) { Error ("`main' cannot be declared as __fastcall__"); } /* If cc65 extensions aren't enabled, don't allow a main function that * doesn't return an int. */ if (IS_Get (&Standard) != STD_CC65 && CurrentFunc->ReturnType[0].C != T_INT) { Error ("`main' must always return an int"); } /* Add a forced import of a symbol that is contained in the startup * code. This will force the startup code to be linked in. */ g_importstartup (); /* If main() takes parameters, generate a forced import to a function * that will setup these parameters. This way, programs that do not * need the additional code will not get it. */ if (D->ParamCount > 0 || (D->Flags & FD_VARIADIC) != 0) { g_importmainargs (); } /* Determine if this is a main function in a C99 environment that * returns an int. */ if (IsTypeInt (F_GetReturnType (CurrentFunc)) && IS_Get (&Standard) == STD_C99) { C99MainFunc = 1; } } /* Allocate code and data segments for this function */ Func->V.F.Seg = PushSegments (Func); /* Allocate a new literal pool */ PushLiteralPool (Func); /* If this is a fastcall function, push the last parameter onto the stack */ if (IsQualFastcall (Func->Type) && D->ParamCount > 0) { unsigned Flags; /* Fastcall functions may never have an ellipsis or the compiler is buggy */ CHECK ((D->Flags & FD_VARIADIC) == 0); /* Generate the push */ if (IsTypeFunc (D->LastParam->Type)) { /* Pointer to function */ Flags = CF_PTR; } else { Flags = TypeOf (D->LastParam->Type) | CF_FORCECHAR; } g_push (Flags, 0); } /* Generate function entry code if needed */ g_enter (TypeOf (Func->Type), F_GetParamSize (CurrentFunc)); /* If stack checking code is requested, emit a call to the helper routine */ if (IS_Get (&CheckStack)) { g_stackcheck (); } /* Setup the stack */ StackPtr = 0; /* Walk through the parameter list and allocate register variable space * for parameters declared as register. Generate code to swap the contents * of the register bank with the save area on the stack. */ Param = D->SymTab->SymHead; while (Param && (Param->Flags & SC_PARAM) != 0) { /* Check for a register variable */ if (SymIsRegVar (Param)) { /* Allocate space */ int Reg = F_AllocRegVar (CurrentFunc, Param->Type); /* Could we allocate a register? */ if (Reg < 0) { /* No register available: Convert parameter to auto */ CvtRegVarToAuto (Param); } else { /* Remember the register offset */ Param->V.R.RegOffs = Reg; /* Generate swap code */ g_swap_regvars (Param->V.R.SaveOffs, Reg, CheckedSizeOf (Param->Type)); } } /* Next parameter */ Param = Param->NextSym; } /* Need a starting curly brace */ ConsumeLCurly (); /* Parse local variable declarations if any */ DeclareLocals (); /* Remember the current stack pointer. All variables allocated elsewhere * must be dropped when doing a return from an inner block. */ CurrentFunc->TopLevelSP = StackPtr; /* Now process statements in this block */ while (CurTok.Tok != TOK_RCURLY && CurTok.Tok != TOK_CEOF) { Statement (0); } /* If this is not a void function, and not the main function in a C99 * environment returning int, output a warning if we didn't see a return * statement. */ if (!F_HasVoidReturn (CurrentFunc) && !F_HasReturn (CurrentFunc) && !C99MainFunc) { Warning ("Control reaches end of non-void function"); } /* If this is the main function in a C99 environment returning an int, let * it always return zero. Note: Actual return statements jump to the return * label defined below. * The code is removed by the optimizer if unused. */ if (C99MainFunc) { g_getimmed (CF_INT | CF_CONST, 0, 0); } /* Output the function exit code label */ g_defcodelabel (F_GetRetLab (CurrentFunc)); /* Restore the register variables */ F_RestoreRegVars (CurrentFunc); /* Generate the exit code */ g_leave (); /* Emit references to imports/exports */ EmitExternals (); /* Emit function debug info */ F_EmitDebugInfo (); EmitDebugInfo (); /* Leave the lexical level */ LeaveFunctionLevel (); /* Eat the closing brace */ ConsumeRCurly (); /* Restore the old literal pool, remembering the one for the function */ Func->V.F.LitPool = PopLiteralPool (); /* Switch back to the old segments */ PopSegments (); /* Reset the current function pointer */ FreeFunction (CurrentFunc); CurrentFunc = 0; }