/* D E S I G N A T O R E V A L U A T I O N */ /* Code generation for designators. This file contains some routines that generate code common to address as well as value computations, and leave a description in a "desig" structure. It also contains routines to load an address, load a value or perform a store. */ #include "parameters.h" #include "debug.h" #include #include #include "LLlex.h" #include "def.h" #include "desig.h" #include "main.h" /* next line DEBUG */ #include "idf.h" #include "node.h" #include "scope.h" #include "type.h" struct desig InitDesig = {DSG_INIT, 0, 0, NULLDEF, 0}; struct withdesig *WithDesigs; STATIC int properly(ds, size, al) register struct desig *ds; arith size; { /* Check if it is allowed to load or store the value indicated by "ds" with LOI/STI. - if the size is not either a multiple or a dividor of the wordsize, then not. - if the alignment is at least "word" then OK. - if size is dividor of word_size and alignment >= size then OK. - otherwise check alignment of address. This can only be done with DSG_FIXED. */ arith szmodword = size % word_size; /* 0 if multiple of wordsize */ arith wordmodsz = word_size % size; /* 0 if dividor of wordsize */ if( szmodword && wordmodsz ) return 0; if( al >= word_align ) return 1; if( szmodword && al >= szmodword ) return 1; return ds->dsg_kind == DSG_FIXED && ((! szmodword && ds->dsg_offset % word_align == 0) || (! wordmodsz && ds->dsg_offset % size == 0)); } CodeCopy(lhs, rhs, sz, psize) register struct desig *lhs, *rhs; arith sz, *psize; { struct desig l, r; l = *lhs; r = *rhs; *psize -= sz; lhs->dsg_offset += sz; rhs->dsg_offset += sz; CodeAddress(&r); C_loi(sz); CodeAddress(&l); C_sti(sz); } CodeMove(rhs, left, rtp) register struct desig *rhs; register struct node *left; struct type *rtp; { struct desig dsl; register struct desig *lhs = &dsl; register struct type *ltp = left->nd_type; dsl = InitDesig; /* Generate code for an assignment. Testing of type compatibility and the like is already done. Go through some (considerable) trouble to see if a BLM can be generated. */ switch( rhs->dsg_kind ) { case DSG_LOADED: CodeDesig(left, lhs); if( rtp->tp_fund == T_STRINGCONST ) { CodeAddress(lhs); C_blm(lhs->dsg_packed ? ltp->tp_psize : ltp->tp_size); return; } CodeStore(lhs, ltp); return; case DSG_PLOADED: case DSG_PFIXED: CodeAddress(rhs); CodeValue(rhs, rtp); CodeDStore(left); return; case DSG_FIXED: { arith tpsize; CodeDesig(left, lhs); tpsize = lhs->dsg_packed ? ltp->tp_psize : ltp->tp_size; if( lhs->dsg_kind == DSG_FIXED && lhs->dsg_offset % word_size == rhs->dsg_offset % word_size ) { arith size = tpsize; if( size > 6 * word_size ) { /* Do a block move */ struct desig l, r; l = *lhs; r = *rhs; CodeAddress(&r); CodeAddress(&l); C_blm(size); } else { register arith sz; for( sz = 2 * word_size; sz; sz -= word_size) { while( size >= sz ) /* Then copy dwords, words. Depend on peephole optimizer */ CodeCopy(lhs, rhs, sz, &size); } } return; } if( lhs->dsg_kind == DSG_PLOADED || lhs->dsg_kind == DSG_INDEXED ) { CodeAddress(lhs); } } default: crash("(CodeMove)"); /*NOTREACHED*/ } } CodeValue(ds, tp) register struct desig *ds; register struct type *tp; { /* Generate code to load the value of the designator described in "ds" */ arith size = ds->dsg_packed ? tp->tp_psize : tp->tp_size; int algn = ds->dsg_packed ? tp->tp_palign : tp->tp_align; switch( ds->dsg_kind ) { case DSG_LOADED: return; case DSG_FIXED: if( ds->dsg_offset % word_size == 0 ) { if ( size == word_size ) { if( ds->dsg_name ) C_loe_dnam(ds->dsg_name, ds->dsg_offset); else C_lol(ds->dsg_offset); break; } else if ( size == word_size * 2) { if( ds->dsg_name ) C_lde_dnam(ds->dsg_name, ds->dsg_offset); else C_ldl(ds->dsg_offset); break; } } /* Fall through */ case DSG_PLOADED: case DSG_PFIXED: if( properly(ds, size, algn) ) { CodeAddress(ds); C_loi(size); break; } crash("(CodeValue)"); break; case DSG_INDEXED: C_lar(word_size); break; default: crash("(CodeValue)"); /*NOTREACHED*/ } if (size < word_size && tp->tp_fund == T_SUBRANGE && BaseType(tp)->tp_fund == T_INTEGER && tp->sub_lb < 0) { C_loc(size); C_loc(word_size); C_cii(); } ds->dsg_kind = DSG_LOADED; } CodeStore(ds, tp) register struct desig *ds; register struct type *tp; { /* Generate code to store the value on the stack in the designator described in "ds" */ struct desig save; arith size = ds->dsg_packed ? tp->tp_psize : tp->tp_size; int algn = ds->dsg_packed ? tp->tp_palign : tp->tp_align; save = *ds; switch( ds->dsg_kind ) { case DSG_FIXED: if( ds->dsg_offset % word_size == 0 ) { if ( size == word_size ) { if( ds->dsg_name ) C_ste_dnam(ds->dsg_name, ds->dsg_offset); else C_stl(ds->dsg_offset); break; } else if ( size == word_size * 2) { if( ds->dsg_name ) C_sde_dnam(ds->dsg_name, ds->dsg_offset); else C_sdl(ds->dsg_offset); break; } } /* Fall through */ case DSG_PLOADED: case DSG_PFIXED: CodeAddress(&save); if( properly(ds, size, algn) ) { C_sti(size); break; } crash("(CodeStore)"); break; case DSG_INDEXED: C_sar(word_size); break; default: crash("(CodeStore)"); /*NOTREACHED*/ } ds->dsg_kind = DSG_INIT; } CodeAddress(ds) register struct desig *ds; { /* Generate code to load the address of the designator described in "ds" */ switch( ds->dsg_kind ) { case DSG_PLOADED: if( ds->dsg_offset ) C_adp(ds->dsg_offset); break; case DSG_FIXED: if( ds->dsg_name ) { C_lae_dnam(ds->dsg_name, ds->dsg_offset); break; } C_lal(ds->dsg_offset); if( ds->dsg_def ) ds->dsg_def->df_flags |= D_NOREG; break; case DSG_PFIXED: if ( word_size == pointer_size ) { if( ds->dsg_name ) C_loe_dnam(ds->dsg_name, ds->dsg_offset); else C_lol(ds->dsg_offset); break; } else { if( ds->dsg_name ) C_lde_dnam(ds->dsg_name, ds->dsg_offset); else C_ldl(ds->dsg_offset); break; } case DSG_INDEXED: C_aar(word_size); break; default: crash("(CodeAddress)"); /*NOTREACHED*/ } ds->dsg_offset = 0; ds->dsg_kind = DSG_PLOADED; } CodeFieldDesig(df, ds) register struct def *df; register struct desig *ds; { /* Generate code for a field designator. Only the code common for address as well as value computation is generated, and the resulting information on where to find the designator is placed in "ds". "df" indicates the definition of the field. */ if( ds->dsg_kind == DSG_INIT ) { /* In a WITH statement. We must find the designator in the WITH statement, and act as if the field is a selection of this designator. So, first find the right WITH statement, which is the first one of the proper record type, which is recognized by its scope indication. */ register struct withdesig *wds = WithDesigs; assert(wds != 0); while( wds->w_scope != df->df_scope ) { wds = wds->w_next; assert(wds != 0); } /* Found it. Now, act like it was a selection. */ *ds = wds->w_desig; assert(ds->dsg_kind == DSG_PFIXED); } switch( ds->dsg_kind ) { case DSG_PLOADED: case DSG_FIXED: ds->dsg_offset += df->fld_off; break; case DSG_PFIXED: case DSG_INDEXED: CodeAddress(ds); ds->dsg_kind = DSG_PLOADED; ds->dsg_offset = df->fld_off; break; default: crash("(CodeFieldDesig)"); } ds->dsg_packed = df->fld_flags & F_PACKED; } CodeVarDesig(df, ds) register struct def *df; register struct desig *ds; { /* Generate code for a variable represented by a "def" structure. Of course, there are numerous cases: the variable is local, it is a value parameter, it is a var parameter, it is one of those of an enclosing procedure, or it is global. */ register struct scope *sc = df->df_scope; assert(ds->dsg_kind == DSG_INIT); if( df->var_name ) { /* this variable has been given a name, so it is global. It is directly accessible. */ ds->dsg_name = df->var_name; ds->dsg_offset = 0; ds->dsg_kind = DSG_FIXED; return; } if( sc->sc_level != proclevel ) { /* the variable is local to a statically enclosing procedure. */ assert(proclevel > sc->sc_level); df->df_flags |= D_NOREG; if( df->df_flags & (D_VARPAR|D_VALPAR) ) { /* value or var parameter */ C_lxa((arith) (proclevel - sc->sc_level)); if( (df->df_flags & D_VARPAR) || IsConformantArray(df->df_type) ) { /* var parameter or conformant array. For conformant array's, the address is passed. */ C_adp(df->var_off); C_loi(pointer_size); ds->dsg_offset = 0; ds->dsg_kind = DSG_PLOADED; return; } } else C_lxl((arith) (proclevel - sc->sc_level)); ds->dsg_kind = DSG_PLOADED; ds->dsg_offset = df->var_off; return; } /* Now, finally, we have a local variable or a local parameter */ if( (df->df_flags & D_VARPAR) || IsConformantArray(df->df_type) ) /* a var parameter; address directly accessible. */ ds->dsg_kind = DSG_PFIXED; else ds->dsg_kind = DSG_FIXED; ds->dsg_offset = df->var_off; ds->dsg_def = df; } CodeBoundDesig(df, ds) register struct def *df; register struct desig *ds; { /* Generate code for the lower- and upperbound of a conformant array */ assert(ds->dsg_kind == DSG_INIT); if( df->df_scope->sc_level < proclevel ) { C_lxa((arith) (proclevel - df->df_scope->sc_level)); C_lof(df->bnd_type->arr_cfdescr); if( df->df_kind == D_UBOUND ) { C_lxa((arith) (proclevel - df->df_scope->sc_level)); C_lof(df->bnd_type->arr_cfdescr+word_size); C_adi(word_size); } } else { C_lol(df->bnd_type->arr_cfdescr); if( df->df_kind == D_UBOUND ) { C_lol(df->bnd_type->arr_cfdescr+word_size); C_adi(word_size); } } ds->dsg_kind = DSG_LOADED; } CodeFuncDesig(df, ds) register struct def *df; register struct desig *ds; { /* generate code to store the function result */ if( df->df_scope->sc_level + 1 < proclevel ) { /* Assignment to function-identifier in the declaration-part of the function (i.e. in the statement-part of a nested function or procedure). */ if( !options['R'] ) { C_loc((arith)1); C_lxl((arith) (proclevel - df->df_scope->sc_level - 1)); C_adp(df->prc_bool); C_sti(int_size); } C_lxl((arith) (proclevel - df->df_scope->sc_level - 1)); ds->dsg_kind = DSG_PLOADED; } else { /* Assignment to function-identifier in the statement-part of the function. */ if( !options['R'] ) { C_loc((arith)1); C_stl(df->prc_bool); } ds->dsg_kind = DSG_FIXED; } assert(df->prc_res < 0); ds->dsg_offset = df->prc_res; } CodeDesig(nd, ds) register struct node *nd; register struct desig *ds; { /* Generate code for a designator. Use divide and conquer principle */ register struct def *df; switch( nd->nd_class ) { /* Divide */ case Def: df = nd->nd_def; switch( (int) df->df_kind ) { case D_FIELD: CodeFieldDesig(df, ds); break; case D_VARIABLE: CodeVarDesig(df, ds); break; case D_LBOUND: case D_UBOUND: CodeBoundDesig(df, ds); break; case D_FUNCTION: CodeFuncDesig(df, ds); break; default: crash("(CodeDesig) Def"); } break; case LinkDef: assert(nd->nd_symb == '.'); CodeDesig(nd->nd_left, ds); CodeFieldDesig(nd->nd_def, ds); break; case Arrsel: { struct type *tp; assert(nd->nd_symb == '['); CodeDesig(nd->nd_left, ds); CodeAddress(ds); CodePExpr(nd->nd_right); /* Now load address of descriptor */ tp = nd->nd_left->nd_type; if( IsConformantArray(tp) ) { if( tp->arr_sclevel < proclevel ) { C_lxa((arith) (proclevel - tp->arr_sclevel)); C_adp(tp->arr_cfdescr); } else C_lal(tp->arr_cfdescr); } else C_lae_dlb(tp->arr_ardescr, (arith) 0); if( options['A'] ) { C_cal("_rcka"); } ds->dsg_kind = DSG_INDEXED; ds->dsg_packed = IsPacked(tp); break; } case Arrow: assert(nd->nd_symb == '^'); if( nd->nd_right->nd_type->tp_fund == T_FILE ) { CodeDAddress(nd->nd_right); C_cal("_wdw"); C_asp(pointer_size); C_lfr(pointer_size); ds->dsg_kind = DSG_PLOADED; ds->dsg_packed = 1; break; } CodeDesig(nd->nd_right, ds); switch(ds->dsg_kind) { case DSG_LOADED: ds->dsg_kind = DSG_PLOADED; break; case DSG_INDEXED: case DSG_PLOADED: case DSG_PFIXED: CodeValue(ds, nd->nd_right->nd_type); ds->dsg_kind = DSG_PLOADED; ds->dsg_offset = 0; break; case DSG_FIXED: ds->dsg_kind = DSG_PFIXED; break; default: crash("(CodeDesig) Uoper"); } break; default: crash("(CodeDesig) class"); } }