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[/] [openrisc/] [trunk/] [gnu-old/] [gcc-4.2.2/] [gcc/] [config/] [m68hc11/] [larith.asm] - Rev 820
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/* libgcc routines for M68HC11 & M68HC12.Copyright (C) 1999, 2000, 2001, 2002, 2003 Free Software Foundation, Inc.This file is part of GCC.GCC is free software; you can redistribute it and/or modify itunder the terms of the GNU General Public License as published by theFree Software Foundation; either version 2, or (at your option) anylater version.In addition to the permissions in the GNU General Public License, theFree Software Foundation gives you unlimited permission to link thecompiled version of this file with other programs, and to distributethose programs without any restriction coming from the use of thisfile. (The General Public License restrictions do apply in otherrespects; for example, they cover modification of the file, anddistribution when not linked into another program.)This file is distributed in the hope that it will be useful, butWITHOUT ANY WARRANTY; without even the implied warranty ofMERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNUGeneral Public License for more details.You should have received a copy of the GNU General Public Licensealong with this program; see the file COPYING. If not, write tothe Free Software Foundation, 51 Franklin Street, Fifth Floor,Boston, MA 02110-1301, USA. *//* As a special exception, if you link this library with other files,some of which are compiled with GCC, to produce an executable,this library does not by itself cause the resulting executableto be covered by the GNU General Public License.This exception does not however invalidate any other reasons whythe executable file might be covered by the GNU General Public License. */.file "larith.asm"#ifdef __HAVE_SHORT_INT__.mode mshort#else.mode mlong#endif.macro declare_near name.globl \name.type \name,@function.size \name,.Lend-\name\name:.endm#if defined(__USE_RTC__)# define ARG(N) N+1.macro ret#if defined(mc68hc12)rtc#elsejmp __return_32#endif.endm.macro declare name.globl \name.type \name,@function.size \name,.Lend-\name.far \name\name:.endm.macro farsym name.far NAME.endm#else# define ARG(N) N.macro retrts.endm.macro farsym name.endm.macro declare name.globl \name.type \name,@function.size \name,.Lend-\name\name:.endm#endif.sect .text#define REG(NAME) \NAME: .dc.w 1; \.type NAME,@object ; \.size NAME,2#ifdef L_regs_min/* Pseudo hard registers used by gcc.They should be located in page0. */.sect .softregs.globl _.tmp.globl _.z,_.xyREG(_.tmp)REG(_.z)REG(_.xy)#endif#ifdef L_regs_frame.sect .softregs.globl _.frameREG(_.frame)#endif#ifdef L_regs_d1_2.sect .softregs.globl _.d1,_.d2REG(_.d1)REG(_.d2)#endif#ifdef L_regs_d3_4.sect .softregs.globl _.d3,_.d4REG(_.d3)REG(_.d4)#endif#ifdef L_regs_d5_6.sect .softregs.globl _.d5,_.d6REG(_.d5)REG(_.d6)#endif#ifdef L_regs_d7_8.sect .softregs.globl _.d7,_.d8REG(_.d7)REG(_.d8)#endif#ifdef L_regs_d9_16/* Pseudo hard registers used by gcc.They should be located in page0. */.sect .softregs.globl _.d9,_.d10,_.d11,_.d12,_.d13,_.d14.globl _.d15,_.d16REG(_.d9)REG(_.d10)REG(_.d11)REG(_.d12)REG(_.d13)REG(_.d14)REG(_.d15)REG(_.d16)#endif#ifdef L_regs_d17_32/* Pseudo hard registers used by gcc.They should be located in page0. */.sect .softregs.globl _.d17,_.d18,_.d19,_.d20,_.d21,_.d22.globl _.d23,_.d24,_.d25,_.d26,_.d27,_.d28.globl _.d29,_.d30,_.d31,_.d32REG(_.d17)REG(_.d18)REG(_.d19)REG(_.d20)REG(_.d21)REG(_.d22)REG(_.d23)REG(_.d24)REG(_.d25)REG(_.d26)REG(_.d27)REG(_.d28)REG(_.d29)REG(_.d30)REG(_.d31)REG(_.d32)#endif#ifdef L_premain;;;; Specific initialization for 68hc11 before the main.;; Nothing special for a generic routine; Just enable interrupts.;;declare_near __premainclratap ; Clear both I and X.rts#endif#ifdef L__exit;;;; Exit operation. Just loop forever and wait for interrupts.;; (no other place to go);; This operation is split in several pieces collected together by;; the linker script. This allows to support destructors at the;; exit stage while not impacting program sizes when there is no;; destructors.;;;; _exit:;; *(.fini0) /* Beginning of finish code (_exit symbol). */;; *(.fini1) /* Place holder for applications. */;; *(.fini2) /* C++ destructors. */;; *(.fini3) /* Place holder for applications. */;; *(.fini4) /* Runtime exit. */;;.sect .fini0,"ax",@progbits.globl _exit.globl exit.weak exitfarsym exitfarsym _exitexit:_exit:.sect .fini4,"ax",@progbitsfatal:cliwaibra fatal#endif#ifdef L_abort;;;; Abort operation. This is defined for the GCC testsuite.;;declare abortldd #255 ;#ifdef mc68hc12trap #0x30#else.byte 0xCD ; Generate an illegal instruction trap.byte 0x03 ; The simulator catches this and stops.#endifjmp _exit#endif#ifdef L_cleanup;;;; Cleanup operation used by exit().;;declare _cleanupret#endif;-----------------------------------------; required gcclib code;-----------------------------------------#ifdef L_memcpydeclare memcpydeclare __memcpy.weak memcpy;;;;;; void* memcpy(void*, const void*, size_t);;;;;; D = dst Pmode;;; 2,sp = src Pmode;;; 4,sp = size HImode (size_t);;;#ifdef mc68hc12ldx ARG(2),spldy ARG(4),sppshdxgdylsrdbcc Startmovb 1,x+,1,y+Start:beq DoneLoop:movw 2,x+,2,y+dbne d,LoopDone:puldret#elsexgdytsxldd ARG(4),xldx ARG(2),x ; SRC = X, DST = Ycpd #0beq Endpshyinca ; Correction for the deca belowL0:psha ; Save high-counter partL1:ldaa 0,x ; Copy up to 256 bytesstaa 0,yinxinydecbbne L1puladecabne L0puly ; Restore Y to return the DSTEnd:xgdyret#endif#endif#ifdef L_memsetdeclare memsetdeclare __memset;;;;;; void* memset(void*, int value, size_t);;;#ifndef __HAVE_SHORT_INT__;;; D = dst Pmode;;; 2,sp = src SImode;;; 6,sp = size HImode (size_t)val = ARG(5)size = ARG(6)#else;;; D = dst Pmode;;; 2,sp = src SImode;;; 6,sp = size HImode (size_t)val = ARG(3)size = ARG(4)#endif#ifdef mc68hc12xgdxldab val,spldy size,sppshxbeq EndLoop:stab 1,x+dbne y,LoopEnd:puldret#elsexgdxtsyldab val,yldy size,y ; DST = X, CNT = Ybeq EndpshxL0:stab 0,x ; Fill up to 256 bytesinxdeybne L0pulx ; Restore X to return the DSTEnd:xgdxret#endif#endif#ifdef L_adddi3declare ___adddi3tsxxgdyldd ARG(8),x ; Add LSBaddd ARG(16),xstd 6,y ; Save (carry preserved)ldd ARG(6),xadcb ARG(15),xadca ARG(14),xstd 4,yldd ARG(4),xadcb ARG(13),xadca ARG(12),xstd 2,yldd ARG(2),xadcb ARG(11),x ; Add MSBadca ARG(10),xstd 0,yxgdyret#endif#ifdef L_subdi3declare ___subdi3tsxxgdyldd ARG(8),x ; Subtract LSBsubd ARG(16),xstd 6,y ; Save, borrow preservedldd ARG(6),xsbcb ARG(15),xsbca ARG(14),xstd 4,yldd ARG(4),xsbcb ARG(13),xsbca ARG(12),xstd 2,yldd ARG(2),x ; Subtract MSBsbcb ARG(11),xsbca ARG(10),xstd 0,yxgdy ;ret#endif#ifdef L_notdi2declare ___notdi2tsyxgdxldd ARG(8),ycomacombstd 6,xldd ARG(6),ycomacombstd 4,xldd ARG(4),ycomacombstd 2,xldd ARG(2),ycomacombstd 0,xxgdxret#endif#ifdef L_negsi2declare_near ___negsi2combcomaxgdxcombcomainxxgdxbne doneinxdone:rts#endif#ifdef L_one_cmplsi2declare_near ___one_cmplsi2combcomaxgdxcombcomaxgdxrts#endif#ifdef L_ashlsi3declare_near ___ashlsi3xgdyclraandb #0x1fxgdybeq ReturnLoop:lsldxgdxrolbrolaxgdxdeybne LoopReturn:rts#endif#ifdef L_ashrsi3declare_near ___ashrsi3xgdyclraandb #0x1fxgdybeq ReturnLoop:xgdxasrarorbxgdxrorarorbdeybne LoopReturn:rts#endif#ifdef L_lshrsi3declare_near ___lshrsi3xgdyclraandb #0x1fxgdybeq ReturnLoop:xgdxlsrdxgdxrorarorbdeybne LoopReturn:rts#endif#ifdef L_lshrhi3declare_near ___lshrhi3cpx #16bge Return_zerocpx #0beq ReturnLoop:lsrddexbne LoopReturn:rtsReturn_zero:clraclrbrts#endif#ifdef L_lshlhi3declare_near ___lshlhi3cpx #16bge Return_zerocpx #0beq ReturnLoop:lslddexbne LoopReturn:rtsReturn_zero:clraclrbrts#endif#ifdef L_rotrhi3declare_near ___rotrhi3___rotrhi3:xgdxclraandb #0x0fxgdxbeq ReturnLoop:taprorbroradexbne LoopReturn:rts#endif#ifdef L_rotlhi3declare_near ___rotlhi3___rotlhi3:xgdxclraandb #0x0fxgdxbeq ReturnLoop:asrbrolbrolarolbdexbne LoopReturn:rts#endif#ifdef L_ashrhi3declare_near ___ashrhi3cpx #16bge Return_minus_1_or_zerocpx #0beq ReturnLoop:asrarorbdexbne LoopReturn:rtsReturn_minus_1_or_zero:clrbtstabpl Return_zerocombReturn_zero:tbarts#endif#ifdef L_ashrqi3declare_near ___ashrqi3cmpa #8bge Return_minus_1_or_zerotstabeq ReturnLoop:asrbdecabne LoopReturn:rtsReturn_minus_1_or_zero:clrbtstbbpl Return_zerocomaReturn_zero:tabrts#endif#ifdef L_lshlqi3declare_near ___lshlqi3cmpa #8bge Return_zerotstabeq ReturnLoop:lslbdecabne LoopReturn:rtsReturn_zero:clrbrts#endif#ifdef L_divmodhi4#ifndef mc68hc12/* 68HC12 signed divisions are generated inline (idivs). */declare_near __divmodhi4;;; D = numerator;; X = denominator;;;; Result: D = D / X;; X = D % X;;tstabpl Numerator_poscomb ; D = -D <=> D = (~D) + 1comaxgdxinxtstabpl Numerator_neg_denominator_posNumerator_neg_denominator_neg:comb ; X = -Xcomaaddd #1xgdxidivcomacombxgdx ; Remainder <= 0 and result >= 0inxrtsNumerator_pos_denominator_pos:xgdxidivxgdx ; Both values are >= 0rtsNumerator_pos:xgdxtstabpl Numerator_pos_denominator_posNumerator_pos_denominator_neg:coma ; X = -Xcombxgdxinxidivxgdx ; Remainder >= 0 but result <= 0comacombaddd #1rtsNumerator_neg_denominator_pos:xgdxidivcoma ; One value is > 0 and the other < 0comb ; Change the sign of result and remainderxgdxinxcomacombaddd #1rts#endif /* !mc68hc12 */#endif#ifdef L_mulqi3declare_near ___mulqi3;; short __mulqi3(signed char a, signed char b);;; signed char a -> register A; signed char b -> register B;; returns the signed result of A * B in register D.;tstabmi A_negtstbbmi B_negmulrtsB_neg:negbbra A_or_B_negA_neg:negatstbbmi AB_negA_or_B_neg:mulcomacombaddd #1rtsAB_neg:negbmulrts#endif#ifdef L_mulhi3declare_near ___mulhi3;;; unsigned short ___mulhi3(unsigned short a, unsigned short b);; a = register D; b = register X;#ifdef mc68hc12pshx ; Preserve Xexg x,yemulexg x,ypulxrts#else#ifdef NO_TMP;; 16 bit multiplication without temp memory location.; (smaller but slower);pshx ; (4)ins ; (3)pshb ; (3)psha ; (3)pshx ; (4)pula ; (4)pulx ; (5)mul ; (10) B.high * A.lowxgdx ; (3)mul ; (10) B.low * A.highabx ; (3)pula ; (4)pulb ; (4)mul ; (10) B.low * A.lowpshx ; (4)tsx ; (3)adda 1,x ; (4)pulx ; (5)rts ; (5) 20 bytes; ---; 91 cycles#elsestx *_.tmp ; (4)pshb ; (3)ldab *_.tmp+1 ; (3)mul ; (10) A.high * B.lowldaa *_.tmp ; (3)stab *_.tmp ; (3)pulb ; (4)pshb ; (4)mul ; (10) A.low * B.highaddb *_.tmp ; (4)stab *_.tmp ; (3)ldaa *_.tmp+1 ; (3)pulb ; (4)mul ; (10) A.low * B.lowadda *_.tmp ; (4)rts ; (5) 24/32 bytes; 77/85 cycles#endif#endif#endif#ifdef L_mulhi32;;; unsigned long __mulhi32(unsigned short a, unsigned short b);; a = register D; b = value on stack;; +---------------+; | B low | <- 7,x; +---------------+; | B high | <- 6,x; +---------------+; | PC low |; +---------------+; | PC high |; +---------------+; | Tmp low |; +---------------+; | Tmp high |; +---------------+; | A low |; +---------------+; | A high |; +---------------+ <- 0,x;;; <B-low> 5,x; <B-high> 4,x; <ret> 2,x; <A-low> 1,x; <A-high> 0,x;declare_near __mulhi32#ifdef mc68hc12ldy 2,spemulexg x,yrts#elsepshx ; Room for temp valuepshbpshatsxldab 6,xmulxgdy ; A.high * B.highldab 7,xpulamul ; A.high * B.lowstd 2,xldaa 1,xldab 6,xmul ; A.low * B.highaddd 2,xstab 2,xtababybcc Nldab #0xffabyinyN:ldab 7,xpulamul ; A.low * B.lowadda 2,xpulx ; Drop temp locationpshy ; Put high part in Xpulxbcc RetinxRet:rts#endif#endif#ifdef L_mulsi3;; <B-low> 8,y; <B-high> 6,y; <ret> 4,y; <tmp> 2,y; <A-low> 0,y;; D,X -> A; Stack -> B;; The result is:;; (((A.low * B.high) + (A.high * B.low)) << 16) + (A.low * B.low);;;declare __mulsi3#ifdef mc68hc12pshd ; Save A.lowldy ARG(4),spemul ; A.low * B.highldy ARG(6),spexg x,demul ; A.high * B.lowleax d,xldy ARG(6),sppuldemul ; A.low * B.lowexg d,yleax d,xexg d,yret#elseB_low = ARG(8)B_high = ARG(6)A_low = 0A_high = 2pshxpshbpshatsy;; If B.low is 0, optimize into: (A.low * B.high) << 16;ldd B_low,ybeq B_low_zero;; If A.high is 0, optimize into: (A.low * B.high) << 16 + (A.low * B.low);cpx #0beq A_high_zerobsr ___mulhi3 ; A.high * B.low;; If A.low is 0, optimize into: (A.high * B.low) << 16;ldx A_low,ybeq A_low_zero ; X = 0, D = A.high * B.lowstd 2,y;; If B.high is 0, we can avoid the (A.low * B.high) << 16 term.;ldd B_high,ybeq B_high_zerobsr ___mulhi3 ; A.low * B.highaddd 2,ystd 2,y;; Here, we know that A.low and B.low are not 0.;B_high_zero:ldd B_low,y ; A.low is on the stackbsr __mulhi32 ; A.low * B.lowxgdxtsy ; Y was clobbered, get it backaddd 2,yA_low_zero: ; See A_low_zero_non_optimized belowxgdxReturn:insinsinsinsret;;; A_low_zero_non_optimized:;; At this step, X = 0 and D = (A.high * B.low); Optimize into: (A.high * B.low) << 16;; xgdx; clra ; Since X was 0, clearing D is superfuous.; clrb; bra Return; ----------------; B.low == 0, the result is: (A.low * B.high) << 16;; At this step:; D = B.low = 0; X = A.high ?; A.low is at A_low,y ?; B.low is at B_low,y ?;B_low_zero:ldd A_low,ybeq Zero1ldx B_high,ybeq Zero2bsr ___mulhi3Zero1:xgdxZero2:clraclrbbra Return; ----------------; A.high is 0, optimize into: (A.low * B.high) << 16 + (A.low * B.low);; At this step:; D = B.low != 0; X = A.high = 0; A.low is at A_low,y ?; B.low is at B_low,y ?;A_high_zero:ldd A_low,y ; A.lowbeq Zero1ldx B_high,y ; B.highbeq A_low_B_lowbsr ___mulhi3std 2,ybra B_high_zero ; Do the (A.low * B.low) and the add.; ----------------; A.high and B.high are 0 optimize into: (A.low * B.low);; At this step:; D = B.high = 0; X = A.low != 0; A.low is at A_low,y != 0; B.high is at B_high,y = 0;A_low_B_low:ldd B_low,y ; A.low is on the stackbsr __mulhi32bra Return#endif#endif#ifdef L_map_data.sect .install2,"ax",@progbits.globl __map_data_section.globl __data_image#ifdef mc68hc12.globl __data_section_size#endif__map_data_section:#ifdef mc68hc12ldx #__data_imageldy #__data_section_startldd #__data_section_sizebeq DoneLoop:movb 1,x+,1,y+dbne d,Loop#elseldx #__data_imageldy #__data_section_startbra Start_mapLoop:ldaa 0,xstaa 0,yinxinyStart_map:cpx #__data_image_endblo Loop#endifDone:#endif#ifdef L_init_bss.sect .install2,"ax",@progbits.globl __init_bss_section__init_bss_section:ldd #__bss_sizebeq Doneldx #__bss_startLoop:#ifdef mc68hc12clr 1,x+dbne d,Loop#elseclr 0,xinxsubd #1bne Loop#endifDone:#endif#ifdef L_ctor; End of constructor table.sect .install3,"ax",@progbits.globl __do_global_ctors__do_global_ctors:; Start from the end - sizeof(void*)ldx #__CTOR_END__-2ctors_loop:cpx #__CTOR_LIST__blo ctors_donepshxldx 0,xjsr 0,xpulxdexdexbra ctors_loopctors_done:#endif#ifdef L_dtor.sect .fini3,"ax",@progbits.globl __do_global_dtors;;;; This piece of code is inserted in the _exit() code by the linker.;;__do_global_dtors:pshb ; Save exit codepshaldx #__DTOR_LIST__dtors_loop:cpx #__DTOR_END__bhs dtors_donepshxldx 0,xjsr 0,xpulxinxinxbra dtors_loopdtors_done:pula ; Restore exit codepulb#endif#ifdef L_far_tramp#ifdef mc68hc12.sect .tramp,"ax",@progbits.globl __far_trampoline;; This is a trampoline used by the linker to invoke a function;; using rtc to return and being called with jsr/bsr.;; The trampoline generated is:;;;; foo_tramp:;; ldy #foo;; call __far_trampoline,page(foo);;;; The linker transforms:;;;; jsr foo;;;; into;; jsr foo_tramp;;;; The linker generated trampoline and _far_trampoline must be in;; non-banked memory.;;__far_trampoline:movb 0,sp, 2,sp ; Copy page register below the caller's returnleas 2,sp ; address.jmp 0,y ; We have a 'call/rtc' stack layout now; and can jump to the far handler; (whose memory bank is mapped due to the; call to the trampoline).#endif#ifdef mc68hc11.sect .tramp,"ax",@progbits.globl __far_trampoline;; Trampoline generated by gcc for 68HC11:;;;; pshb;; ldab #%page(func);; ldy #%addr(func);; jmp __far_trampoline;;__far_trampoline:psha ; (2) Save function parameter (high);; <Read current page in A>psha ; (2);; <Set currenge page from B>pshx ; (4)tsx ; (3)ldab 4,x ; (4) Restore function parameter (low)ldaa 2,x ; (4) Get saved page numberstaa 4,x ; (4) Save it below return PCpulx ; (5)pula ; (3)pula ; (3) Restore function parameter (high)jmp 0,y ; (4)#endif#endif#ifdef L_call_far#ifdef mc68hc11.sect .tramp,"ax",@progbits.globl __call_a16.globl __call_a32;;;; The call methods are used for 68HC11 to support memory bank switching.;; Every far call is redirected to these call methods. Its purpose is to:;;;; 1/ Save the current page on the stack (1 byte to follow 68HC12 call frame);; 2/ Install the new page;; 3/ Jump to the real function;;;; The page switching (get/save) is board dependent. The default provided;; here does nothing (just create the appropriate call frame).;;;; Call sequence (10 bytes, 13 cycles):;;;; ldx #page ; (3);; ldy #func ; (4);; jsr __call_a16 ; (6);;;; Call trampoline (11 bytes, 19 cycles):;;__call_a16:;; xgdx ; (3);; <Read current page in A> ; (3) ldaa _current_pagepsha ; (2);; <Set current page from B> ; (4) staa _current_page;; xgdx ; (3)jmp 0,y ; (4);;;; Call sequence (10 bytes, 14 cycles):;;;; pshb ; (2);; ldab #page ; (2);; ldy #func ; (4);; jsr __call_a32 ; (6);;;; Call trampoline (87 bytes, 57 cycles):;;__call_a32:pshx ; (4)psha ; (2);; <Read current page in A> ; (3) ldaa _current_pagepsha ; (2);; <Set current page from B> ; (4) staa _current_pagetsx ; (3)ldab 6,x ; (4) Restore function parameterldaa 5,x ; (4) Move PC return at good placestaa 6,x ; (4)ldaa 4,x ; (4)staa 5,x ; (4)pula ; (3)staa 4,x ; (4)pula ; (3)pulx ; (5)jmp 0,y ; (4)#endif#endif#ifdef L_return_far#ifdef mc68hc11.sect .tramp,"ax",@progbits.globl __return_void.globl __return_16.globl __return_32__return_void:;; pulb;; <Set current page from B> (Board specific);; rts__return_16:;; xgdx;; pulb;; <Set current page from B> (Board specific);; xgdx;; rts__return_32:;; xgdy;; pulb;; <Set current page from B> (Board specific);; xgdy;; rtsinsrts#endif#endif.Lend:;-----------------------------------------; end required gcclib code;-----------------------------------------
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