{ This file is part of the Free Pascal run time library. Copyright (c) 1999-2000 by the Free Pascal development team Include file with set operations called by the compiler See the file COPYING.FPC, included in this distribution, for details about the copyright. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. **********************************************************************} { the following code is exactly big endian set-related, but specific to the old scheme whereby sets were either 4 or 32 bytes. I've left the routines here so if someone wants to, they can create equivalents of the new varset helpers from rtl/inc/genset.inc } {$ifdef FPC_OLD_BIGENDIAN_SETS} {$define FPC_SYSTEM_HAS_FPC_SET_LOAD_SMALL} function fpc_set_load_small(l: fpc_small_set): fpc_normal_set;assembler;[public,alias:'FPC_SET_LOAD_SMALL']; compilerproc; { load a normal set p from a smallset l } var saveedi : longint; asm movl %edi,saveedi movl __RESULT,%edi movl l,%eax {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} stosl xorl %eax,%eax movl $7,%ecx rep stosl movl saveedi,%edi end; {$define FPC_SYSTEM_HAS_FPC_SET_CREATE_ELEMENT} function fpc_set_create_element(b : byte): fpc_normal_set;assembler;[public,alias:'FPC_SET_CREATE_ELEMENT']; compilerproc; { create a new set in p from an element b } var saveedi : longint; asm movl %edi,saveedi movl __RESULT,%edi movzbl b,%edx xorl %eax,%eax movl $8,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} rep stosl leal -32(%edi),%eax btsl %edx,(%eax) movl saveedi,%edi end; {$define FPC_SYSTEM_HAS_FPC_SET_SET_BYTE} function fpc_set_set_byte(const source: fpc_normal_set; b : byte): fpc_normal_set;assembler; compilerproc; { add the element b to the set pointed by source } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi movl source,%esi movl __RESULT,%edi movzbl b,%edx movl $8,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} rep movsl leal -32(%edi),%eax btsl %edx,(%eax) movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_UNSET_BYTE} function fpc_set_unset_byte(const source: fpc_normal_set; b : byte): fpc_normal_set;assembler; compilerproc; { add the element b to the set pointed by source } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi movl source,%esi movl __RESULT,%edi movzbl b,%edx movl $8,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} rep movsl leal -32(%edi),%eax btrl %edx,(%eax) movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_SET_RANGE} function fpc_set_set_range(const orgset: fpc_normal_set; l,h : byte): fpc_normal_set;assembler; compilerproc; { adds the range [l..h] to the set pointed to by p } var saveh : byte; saveesi,saveedi,saveebx : longint; asm movl %edi,saveedi movl %esi,saveesi movl %ebx,saveebx movl __RESULT,%edi // target set address in edi movl orgset, %esi // source set address in esi movzbl l,%eax // lowest bit to be set in eax movzbl h,%ebx // highest in ebx movb %bl,saveh movl $8,%ecx // we have to copy 32 bytes cmpl %eax,%ebx // high < low? {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} rep // copy source to dest (it's possible to do the range movsl // setting and copying simultanuously of course, but // that would result in many more jumps and code) movl %eax,%ecx // lowest also in ecx jb .Lset_range_done // if high > low, then dest := source shrl $3,%eax // divide by 8 to get starting and ending byte shrl $3,%ebx // address andb $31,%cl // low five bits of lo determine start of bit mask andl $0x0fffffffc,%eax // clear two lowest bits to get start/end longint subl $32,%edi // get back to start of dest andl $0x0fffffffc,%ebx // address * 4 movl $0x0ffffffff,%edx // edx = bitmask to be inserted shll %cl,%edx // shift bitmask to clear bits below lo addl %eax,%edi // go to starting pos in set subl %eax,%ebx // are bit lo and hi in the same longint? jz .Lset_range_hi // yes, keep current mask and adjust for hi bit orl %edx,(%edi) // no, store current mask movl $0x0ffffffff,%edx // new mask addl $4,%edi // next longint of set subl $4,%ebx // bit hi in this longint? jz .Lset_range_hi // yes, keep full mask and adjust for hi bit .Lset_range_loop: movl %edx,(%edi) // no, fill longints in between with full mask addl $4,%edi subl $4,%ebx jnz .Lset_range_loop .Lset_range_hi: movb saveh,%cl // this is ok, h is on the stack movl %edx,%ebx // save current bitmask andb $31,%cl subb $31,%cl // cl := (31 - (hi and 31)) = shift count to negb %cl // adjust bitmask for hi bit shrl %cl,%edx // shift bitmask to clear bits higher than hi andl %edx,%ebx // combine both bitmasks orl %ebx,(%edi) // store to set .Lset_range_done: movl saveedi,%edi movl saveesi,%esi movl saveebx,%ebx end; {$define FPC_SYSTEM_HAS_FPC_SET_IN_BYTE} function fpc_set_in_byte(const p: fpc_normal_set; b: byte): boolean; assembler; [public,alias:'FPC_SET_IN_BYTE']; compilerproc; { tests if the element b is in the set p the carryflag is set if it present } asm {$ifdef REGCALL} xchgl %edx,%eax andl $0xff,%eax {$else} movl p,%edx movzbl b,%eax {$endif} btl %eax,(%edx) end; {$define FPC_SYSTEM_HAS_FPC_SET_ADD_SETS} function fpc_set_add_sets(const set1,set2: fpc_normal_set): fpc_normal_set;assembler;[public,alias:'FPC_SET_ADD_SETS']; compilerproc; { adds set1 and set2 into set dest } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi {$ifdef REGCALL} movl set1,%esi movl __RESULT,%edi movl set2,%edx {$else} movl set1,%esi movl set2,%edx movl __RESULT,%edi {$endif} {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} movl $8,%ecx .LMADDSETS1: lodsl orl (%edx),%eax stosl addl $4,%edx decl %ecx jnz .LMADDSETS1 movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_MUL_SETS} function fpc_set_mul_sets(const set1,set2: fpc_normal_set): fpc_normal_set;assembler;[public,alias:'FPC_SET_MUL_SETS']; compilerproc; { multiplies (takes common elements of) set1 and set2 result put in dest } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi {$ifdef REGCALL} movl set1,%esi movl __RESULT,%edi movl set2,%edx {$else} movl set1,%esi movl set2,%edx movl __RESULT,%edi {$endif} {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} movl $8,%ecx .LMMULSETS1: lodsl andl (%edx),%eax stosl addl $4,%edx decl %ecx jnz .LMMULSETS1 movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_SUB_SETS} function fpc_set_sub_sets(const set1,set2: fpc_normal_set): fpc_normal_set;assembler;[public,alias:'FPC_SET_SUB_SETS']; compilerproc; { computes the diff from set1 to set2 result in dest } var saveesi,saveedi,saveebx : longint; asm movl %edi,saveedi movl %esi,saveesi movl %ebx,saveebx {$ifdef REGCALL} movl set1,%esi movl __RESULT,%edi movl set2,%ebx {$else} movl set1,%esi movl set2,%ebx movl __RESULT,%edi {$endif} {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} movl $8,%ecx .LMSUBSETS1: lodsl movl (%ebx),%edx notl %edx andl %edx,%eax stosl addl $4,%ebx decl %ecx jnz .LMSUBSETS1 movl saveedi,%edi movl saveesi,%esi movl saveebx,%ebx end; {$define FPC_SYSTEM_HAS_FPC_SET_SYMDIF_SETS} function fpc_set_symdif_sets(const set1,set2: fpc_normal_set): fpc_normal_set;assembler;[public,alias:'FPC_SET_SYMDIF_SETS']; compilerproc; { computes the symetric diff from set1 to set2 result in dest } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi {$ifdef REGCALL} movl set1,%esi movl __RESULT,%edi movl set2,%edx {$else} movl set1,%esi movl set2,%edx movl __RESULT,%edi {$endif} {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} movl $8,%ecx .LMSYMDIFSETS1: lodsl xorl (%edx),%eax stosl addl $4,%edx decl %ecx jnz .LMSYMDIFSETS1 movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_COMP_SETS} function fpc_set_comp_sets(const set1,set2: fpc_normal_set): boolean;assembler;[public,alias:'FPC_SET_COMP_SETS']; compilerproc; { compares set1 and set2 zeroflag is set if they are equal } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi movl set1,%esi movl set2,%edi movl $8,%ecx .LMCOMPSETS1: movl (%esi),%eax movl (%edi),%edx cmpl %edx,%eax jne .LMCOMPSETEND addl $4,%esi addl $4,%edi decl %ecx jnz .LMCOMPSETS1 { we are here only if the two sets are equal we have zero flag set, and that what is expected } .LMCOMPSETEND: seteb %al movl saveedi,%edi movl saveesi,%esi end; {$define FPC_SYSTEM_HAS_FPC_SET_CONTAINS_SET} function fpc_set_contains_sets(const set1,set2: fpc_normal_set): boolean;assembler;[public,alias:'FPC_SET_CONTAINS_SETS']; compilerproc; { on exit, zero flag is set if set1 <= set2 (set2 contains set1) } var saveesi,saveedi : longint; asm movl %edi,saveedi movl %esi,saveesi movl set1,%esi movl set2,%edi movl $8,%ecx .LMCONTAINSSETS1: movl (%esi),%eax movl (%edi),%edx andl %eax,%edx cmpl %edx,%eax {set1 and set2 = set1?} jne .LMCONTAINSSETEND addl $4,%esi addl $4,%edi decl %ecx jnz .LMCONTAINSSETS1 { we are here only if set2 contains set1 we have zero flag set, and that what is expected } .LMCONTAINSSETEND: seteb %al movl saveedi,%edi movl saveesi,%esi end; {$ifdef LARGESETS} {$error Needs to be fixed for register calling first!} procedure fpc_largeset_set_word(p : pointer;b : word);assembler;[public,alias:'FPC_LARGESET_SET_WORD']; compilerproc; { sets the element b in set p works for sets larger than 256 elements not yet use by the compiler so } asm pushl %eax movl p,%edi movw b,%ax andl $0xfff8,%eax shrl $3,%eax addl %eax,%edi movb 12(%ebp),%al andl $7,%eax btsl %eax,(%edi) popl %eax end; procedure fpc_largeset_in_word(p : pointer;b : word);assembler;[public,alias:'FPC_LARGESET_IN_WORD']; compilerproc; { tests if the element b is in the set p the carryflag is set if it present works for sets larger than 256 elements } asm pushl %eax movl p,%edi movw b,%ax andl $0xfff8,%eax shrl $3,%eax addl %eax,%edi movb 12(%ebp),%al andl $7,%eax btl %eax,(%edi) popl %eax end; procedure fpc_largeset_add_sets(set1,set2,dest : pointer;size : longint);assembler;[public,alias:'FPC_LARGESET_ADD_SETS']; compilerproc; { adds set1 and set2 into set dest size is the number of bytes in the set } asm movl set1,%esi movl set2,%ebx movl dest,%edi movl size,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} .LMADDSETSIZES1: lodsl orl (%ebx),%eax stosl addl $4,%ebx decl %ecx jnz .LMADDSETSIZES1 end; procedure fpc_largeset_mul_sets(set1,set2,dest : pointer;size : longint);assembler;[public,alias:'FPC_LARGESET_MUL_SETS']; compilerproc; { multiplies (i.E. takes common elements of) set1 and set2 result put in dest size is the number of bytes in the set } asm movl set1,%esi movl set2,%ebx movl dest,%edi movl size,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} .LMMULSETSIZES1: lodsl andl (%ebx),%eax stosl addl $4,%ebx decl %ecx jnz .LMMULSETSIZES1 end; procedure fpc_largeset_sub_sets(set1,set2,dest : pointer;size : longint);assembler;[public,alias:'FPC_LARGESET_SUB_SETS']; compilerproc; asm movl set1,%esi movl set2,%ebx movl dest,%edi movl size,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} .LMSUBSETSIZES1: lodsl movl (%ebx),%edx notl %edx andl %edx,%eax stosl addl $4,%ebx decl %ecx jnz .LMSUBSETSIZES1 end; procedure fpc_largeset_symdif_sets(set1,set2,dest : pointer;size : longint);assembler;[public,alias:'FPC_LARGESET_SYMDIF_SETS']; compilerproc; { computes the symetric diff from set1 to set2 result in dest } asm movl set1,%esi movl set2,%ebx movl dest,%edi movl size,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} .LMSYMDIFSETSIZE1: lodsl movl (%ebx),%edx xorl %edx,%eax stosl addl $4,%ebx decl %ecx jnz .LMSYMDIFSETSIZE1 end; procedure fpc_largeset_comp_sets(set1,set2 : pointer;size : longint);assembler;[public,alias:'FPC_LARGESET_COMP_SETS']; compilerproc; asm movl set1,%esi movl set2,%edi movl size,%ecx {$ifdef FPC_ENABLED_CLD} cld {$endif FPC_ENABLED_CLD} .LMCOMPSETSIZES1: lodsl movl (%edi),%edx cmpl %edx,%eax jne .LMCOMPSETSIZEEND addl $4,%edi decl %ecx jnz .LMCOMPSETSIZES1 { we are here only if the two sets are equal we have zero flag set, and that what is expected } .LMCOMPSETSIZEEND: end; procedure fpc_largeset_contains_sets(set1,set2 : pointer; size: longint);assembler;[public,alias:'FPC_LARGESET_CONTAINS_SETS']; compilerproc; { on exit, zero flag is set if set1 <= set2 (set2 contains set1) } asm movl set1,%esi movl set2,%edi movl size,%ecx .LMCONTAINSSETS2: movl (%esi),%eax movl (%edi),%edx andl %eax,%edx cmpl %edx,%eax {set1 and set2 = set1?} jne .LMCONTAINSSETEND2 addl $4,%esi addl $4,%edi decl %ecx jnz .LMCONTAINSSETS2 { we are here only if set2 contains set1 we have zero flag set, and that what is expected } .LMCONTAINSSETEND2: end; {$endif LARGESET} {$endif FPC_OLD_BIGENDIAN_SETS}