@ libgcc routines for ARM cpu. @ Division routines, written by Richard Earnshaw, (rearnsha@armltd.co.uk) /* Copyright 1995, 1996, 1998, 1999, 2000 Free Software Foundation, Inc. This file is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. In addition to the permissions in the GNU General Public License, the Free Software Foundation gives you unlimited permission to link the compiled version of this file into combinations with other programs, and to distribute those combinations without any restriction coming from the use of this file. (The General Public License restrictions do apply in other respects; for example, they cover modification of the file, and distribution when not linked into a combine executable.) This file 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. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; see the file COPYING. If not, write to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* ------------------------------------------------------------------------ */ /* We need to know what prefix to add to function names. */ #ifndef __USER_LABEL_PREFIX__ #error __USER_LABEL_PREFIX__ not defined #endif /* ANSI concatenation macros. */ #define CONCAT1(a, b) CONCAT2(a, b) #define CONCAT2(a, b) a ## b /* Use the right prefix for global labels. */ #define SYM(x) CONCAT1 (__USER_LABEL_PREFIX__, x) #ifdef __ELF__ #ifdef __thumb__ #define __PLT__ /* Not supported in Thumb assembler (for now). */ #else #define __PLT__ (PLT) #endif #define TYPE(x) .type SYM(x),function #define SIZE(x) .size SYM(x), . - SYM(x) #else #define __PLT__ #define TYPE(x) #define SIZE(x) #endif /* Function end macros. Variants for 26 bit APCS and interworking. */ #ifdef __APCS_26__ # define RET movs pc, lr # define RETc(x) mov##x##s pc, lr # define RETCOND ^ .macro ARM_LDIV0 Ldiv0: str lr, [sp, #-4]! bl SYM (__div0) __PLT__ mov r0, #0 @ About as wrong as it could be. ldmia sp!, {pc}^ .endm #else # ifdef __THUMB_INTERWORK__ # define RET bx lr # define RETc(x) bx##x lr .macro THUMB_LDIV0 Ldiv0: push { lr } bl SYM (__div0) mov r0, #0 @ About as wrong as it could be. pop { r1 } bx r1 .endm .macro ARM_LDIV0 Ldiv0: str lr, [sp, #-4]! bl SYM (__div0) __PLT__ mov r0, #0 @ About as wrong as it could be. ldr lr, [sp], #4 bx lr .endm # else # define RET mov pc, lr # define RETc(x) mov##x pc, lr .macro THUMB_LDIV0 Ldiv0: push { lr } bl SYM (__div0) mov r0, #0 @ About as wrong as it could be. pop { pc } .endm .macro ARM_LDIV0 Ldiv0: str lr, [sp, #-4]! bl SYM (__div0) __PLT__ mov r0, #0 @ About as wrong as it could be. ldmia sp!, {pc} .endm # endif # define RETCOND #endif .macro FUNC_END name Ldiv0: #ifdef __thumb__ THUMB_LDIV0 #else ARM_LDIV0 #endif SIZE (__\name) .endm .macro THUMB_FUNC_START name .globl SYM (\name) TYPE (\name) .thumb_func SYM (\name): .endm /* Function start macros. Variants for ARM and Thumb. */ #ifdef __thumb__ #define THUMB_FUNC .thumb_func #define THUMB_CODE .force_thumb #else #define THUMB_FUNC #define THUMB_CODE #endif .macro FUNC_START name .text .globl SYM (__\name) TYPE (__\name) .align 0 THUMB_CODE THUMB_FUNC SYM (__\name): .endm /* Register aliases. */ work .req r4 @ XXXX is this safe ? dividend .req r0 divisor .req r1 overdone .req r2 result .req r2 curbit .req r3 ip .req r12 sp .req r13 lr .req r14 pc .req r15 /* ------------------------------------------------------------------------ */ /* Bodies of the divsion and modulo routines. */ /* ------------------------------------------------------------------------ */ .macro ARM_DIV_MOD_BODY modulo Loop1: @ Unless the divisor is very big, shift it up in multiples of @ four bits, since this is the amount of unwinding in the main @ division loop. Continue shifting until the divisor is @ larger than the dividend. cmp divisor, #0x10000000 cmplo divisor, dividend movlo divisor, divisor, lsl #4 movlo curbit, curbit, lsl #4 blo Loop1 Lbignum: @ For very big divisors, we must shift it a bit at a time, or @ we will be in danger of overflowing. cmp divisor, #0x80000000 cmplo divisor, dividend movlo divisor, divisor, lsl #1 movlo curbit, curbit, lsl #1 blo Lbignum Loop3: @ Test for possible subtractions. On the final pass, this may @ subtract too much from the dividend ... .if \modulo @ ... so keep track of which subtractions are done in OVERDONE. @ We can fix them up afterwards. mov overdone, #0 cmp dividend, divisor subhs dividend, dividend, divisor cmp dividend, divisor, lsr #1 subhs dividend, dividend, divisor, lsr #1 orrhs overdone, overdone, curbit, ror #1 cmp dividend, divisor, lsr #2 subhs dividend, dividend, divisor, lsr #2 orrhs overdone, overdone, curbit, ror #2 cmp dividend, divisor, lsr #3 subhs dividend, dividend, divisor, lsr #3 orrhs overdone, overdone, curbit, ror #3 mov ip, curbit .else @ ... so keep track of which subtractions are done in RESULT. @ The result will be ok, since the "bit" will have been @ shifted out at the bottom. cmp dividend, divisor subhs dividend, dividend, divisor orrhs result, result, curbit cmp dividend, divisor, lsr #1 subhs dividend, dividend, divisor, lsr #1 orrhs result, result, curbit, lsr #1 cmp dividend, divisor, lsr #2 subhs dividend, dividend, divisor, lsr #2 orrhs result, result, curbit, lsr #2 cmp dividend, divisor, lsr #3 subhs dividend, dividend, divisor, lsr #3 orrhs result, result, curbit, lsr #3 .endif cmp dividend, #0 @ Early termination? movnes curbit, curbit, lsr #4 @ No, any more bits to do? movne divisor, divisor, lsr #4 bne Loop3 .if \modulo Lfixup_dividend: @ Any subtractions that we should not have done will be recorded in @ the top three bits of OVERDONE. Exactly which were not needed @ are governed by the position of the bit, stored in IP. ands overdone, overdone, #0xe0000000 @ If we terminated early, because dividend became zero, then the @ bit in ip will not be in the bottom nibble, and we should not @ perform the additions below. We must test for this though @ (rather relying upon the TSTs to prevent the additions) since @ the bit in ip could be in the top two bits which might then match @ with one of the smaller RORs. tstne ip, #0x7 beq Lgot_result tst overdone, ip, ror #3 addne dividend, dividend, divisor, lsr #3 tst overdone, ip, ror #2 addne dividend, dividend, divisor, lsr #2 tst overdone, ip, ror #1 addne dividend, dividend, divisor, lsr #1 .endif Lgot_result: .endm /* ------------------------------------------------------------------------ */ .macro THUMB_DIV_MOD_BODY modulo @ Load the constant 0x10000000 into our work register. mov work, #1 lsl work, #28 Loop1: @ Unless the divisor is very big, shift it up in multiples of @ four bits, since this is the amount of unwinding in the main @ division loop. Continue shifting until the divisor is @ larger than the dividend. cmp divisor, work bhs Lbignum cmp divisor, dividend bhs Lbignum lsl divisor, #4 lsl curbit, #4 b Loop1 Lbignum: @ Set work to 0x80000000 lsl work, #3 Loop2: @ For very big divisors, we must shift it a bit at a time, or @ we will be in danger of overflowing. cmp divisor, work bhs Loop3 cmp divisor, dividend bhs Loop3 lsl divisor, #1 lsl curbit, #1 b Loop2 Loop3: @ Test for possible subtractions ... .if \modulo @ ... On the final pass, this may subtract too much from the dividend, @ so keep track of which subtractions are done, we can fix them up @ afterwards. mov overdone, #0 cmp dividend, divisor blo Lover1 sub dividend, dividend, divisor Lover1: lsr work, divisor, #1 cmp dividend, work blo Lover2 sub dividend, dividend, work mov ip, curbit mov work, #1 ror curbit, work orr overdone, curbit mov curbit, ip Lover2: lsr work, divisor, #2 cmp dividend, work blo Lover3 sub dividend, dividend, work mov ip, curbit mov work, #2 ror curbit, work orr overdone, curbit mov curbit, ip Lover3: lsr work, divisor, #3 cmp dividend, work blo Lover4 sub dividend, dividend, work mov ip, curbit mov work, #3 ror curbit, work orr overdone, curbit mov curbit, ip Lover4: mov ip, curbit .else @ ... and note which bits are done in the result. On the final pass, @ this may subtract too much from the dividend, but the result will be ok, @ since the "bit" will have been shifted out at the bottom. cmp dividend, divisor blo Lover1 sub dividend, dividend, divisor orr result, result, curbit Lover1: lsr work, divisor, #1 cmp dividend, work blo Lover2 sub dividend, dividend, work lsr work, curbit, #1 orr result, work Lover2: lsr work, divisor, #2 cmp dividend, work blo Lover3 sub dividend, dividend, work lsr work, curbit, #2 orr result, work Lover3: lsr work, divisor, #3 cmp dividend, work blo Lover4 sub dividend, dividend, work lsr work, curbit, #3 orr result, work Lover4: .endif cmp dividend, #0 @ Early termination? beq Lover5 lsr curbit, #4 @ No, any more bits to do? beq Lover5 lsr divisor, #4 b Loop3 Lover5: .if \modulo @ Any subtractions that we should not have done will be recorded in @ the top three bits of "overdone". Exactly which were not needed @ are governed by the position of the bit, stored in ip. mov work, #0xe lsl work, #28 and overdone, work beq Lgot_result @ If we terminated early, because dividend became zero, then the @ bit in ip will not be in the bottom nibble, and we should not @ perform the additions below. We must test for this though @ (rather relying upon the TSTs to prevent the additions) since @ the bit in ip could be in the top two bits which might then match @ with one of the smaller RORs. mov curbit, ip mov work, #0x7 tst curbit, work beq Lgot_result mov curbit, ip mov work, #3 ror curbit, work tst overdone, curbit beq Lover6 lsr work, divisor, #3 add dividend, work Lover6: mov curbit, ip mov work, #2 ror curbit, work tst overdone, curbit beq Lover7 lsr work, divisor, #2 add dividend, work Lover7: mov curbit, ip mov work, #1 ror curbit, work tst overdone, curbit beq Lgot_result lsr work, divisor, #1 add dividend, work .endif Lgot_result: .endm /* ------------------------------------------------------------------------ */ /* Start of the Real Functions */ /* ------------------------------------------------------------------------ */ #ifdef L_udivsi3 FUNC_START udivsi3 #ifdef __thumb__ cmp divisor, #0 beq Ldiv0 mov curbit, #1 mov result, #0 push { work } cmp dividend, divisor blo Lgot_result THUMB_DIV_MOD_BODY 0 mov r0, result pop { work } RET #else /* ARM version. */ cmp divisor, #0 beq Ldiv0 mov curbit, #1 mov result, #0 cmp dividend, divisor blo Lgot_result ARM_DIV_MOD_BODY 0 mov r0, result RET #endif /* ARM version */ FUNC_END udivsi3 #endif /* L_udivsi3 */ /* ------------------------------------------------------------------------ */ #ifdef L_umodsi3 FUNC_START umodsi3 #ifdef __thumb__ cmp divisor, #0 beq Ldiv0 mov curbit, #1 cmp dividend, divisor bhs Lover10 RET Lover10: push { work } THUMB_DIV_MOD_BODY 1 pop { work } RET #else /* ARM version. */ cmp divisor, #0 beq Ldiv0 cmp divisor, #1 cmpne dividend, divisor moveq dividend, #0 RETc(lo) mov curbit, #1 ARM_DIV_MOD_BODY 1 RET #endif /* ARM version. */ FUNC_END umodsi3 #endif /* L_umodsi3 */ /* ------------------------------------------------------------------------ */ #ifdef L_divsi3 FUNC_START divsi3 #ifdef __thumb__ cmp divisor, #0 beq Ldiv0 push { work } mov work, dividend eor work, divisor @ Save the sign of the result. mov ip, work mov curbit, #1 mov result, #0 cmp divisor, #0 bpl Lover10 neg divisor, divisor @ Loops below use unsigned. Lover10: cmp dividend, #0 bpl Lover11 neg dividend, dividend Lover11: cmp dividend, divisor blo Lgot_result THUMB_DIV_MOD_BODY 0 mov r0, result mov work, ip cmp work, #0 bpl Lover12 neg r0, r0 Lover12: pop { work } RET #else /* ARM version. */ eor ip, dividend, divisor @ Save the sign of the result. mov curbit, #1 mov result, #0 cmp divisor, #0 rsbmi divisor, divisor, #0 @ Loops below use unsigned. beq Ldiv0 cmp dividend, #0 rsbmi dividend, dividend, #0 cmp dividend, divisor blo Lgot_result ARM_DIV_MOD_BODY 0 mov r0, result cmp ip, #0 rsbmi r0, r0, #0 RET #endif /* ARM version */ FUNC_END divsi3 #endif /* L_divsi3 */ /* ------------------------------------------------------------------------ */ #ifdef L_modsi3 FUNC_START modsi3 #ifdef __thumb__ mov curbit, #1 cmp divisor, #0 beq Ldiv0 bpl Lover10 neg divisor, divisor @ Loops below use unsigned. Lover10: push { work } @ Need to save the sign of the dividend, unfortunately, we need @ work later on. Must do this after saving the original value of @ the work register, because we will pop this value off first. push { dividend } cmp dividend, #0 bpl Lover11 neg dividend, dividend Lover11: cmp dividend, divisor blo Lgot_result THUMB_DIV_MOD_BODY 1 pop { work } cmp work, #0 bpl Lover12 neg dividend, dividend Lover12: pop { work } RET #else /* ARM version. */ cmp divisor, #0 rsbmi divisor, divisor, #0 @ Loops below use unsigned. beq Ldiv0 @ Need to save the sign of the dividend, unfortunately, we need @ ip later on; this is faster than pushing lr and using that. str dividend, [sp, #-4]! cmp dividend, #0 @ Test dividend against zero rsbmi dividend, dividend, #0 @ If negative make positive cmp dividend, divisor @ else if zero return zero blo Lgot_result @ if smaller return dividend mov curbit, #1 ARM_DIV_MOD_BODY 1 ldr ip, [sp], #4 cmp ip, #0 rsbmi dividend, dividend, #0 RET #endif /* ARM version */ FUNC_END modsi3 #endif /* L_modsi3 */ /* ------------------------------------------------------------------------ */ #ifdef L_dvmd_tls FUNC_START div0 RET SIZE (__div0) #endif /* L_divmodsi_tools */ /* ------------------------------------------------------------------------ */ #ifdef L_dvmd_lnx @ GNU/Linux division-by zero handler. Used in place of L_dvmd_tls #include #define SIGFPE 8 @ cant use as it @ contains too much C rubbish FUNC_START div0 stmfd sp!, {r1, lr} swi __NR_getpid cmn r0, #1000 ldmhsfd sp!, {r1, pc}RETCOND @ not much we can do mov r1, #SIGFPE swi __NR_kill #ifdef __THUMB_INTERWORK__ ldmfd sp!, {r1, lr} bx lr #else ldmfd sp!, {r1, pc}RETCOND #endif SIZE (__div0) #endif /* L_dvmd_lnx */ /* ------------------------------------------------------------------------ */ /* These next two sections are here despite the fact that they contain Thumb assembler because their presence allows interworked code to be linked even when the GCC library is this one. */ /* Do not build the interworking functions when the target architecture does not support Thumb instructions. (This can be a multilib option). */ #if defined L_call_via_rX && (defined __ARM_ARCH_4T__ || defined __ARM_ARCH_5T__ || defined __ARM_ARCH_5TE__) /* These labels & instructions are used by the Arm/Thumb interworking code. The address of function to be called is loaded into a register and then one of these labels is called via a BL instruction. This puts the return address into the link register with the bottom bit set, and the code here switches to the correct mode before executing the function. */ .text .align 0 .force_thumb .macro call_via register THUMB_FUNC_START _call_via_\register bx \register nop SIZE (_call_via_\register) .endm call_via r0 call_via r1 call_via r2 call_via r3 call_via r4 call_via r5 call_via r6 call_via r7 call_via r8 call_via r9 call_via sl call_via fp call_via ip call_via sp call_via lr #endif /* L_call_via_rX */ /* ------------------------------------------------------------------------ */ /* Do not build the interworking functions when the target architecture does not support Thumb instructions. (This can be a multilib option). */ #if defined L_interwork_call_via_rX && (defined __ARM_ARCH_4T__ || defined __ARM_ARCH_5T__ || defined __ARM_ARCH_5TE__) /* These labels & instructions are used by the Arm/Thumb interworking code, when the target address is in an unknown instruction set. The address of function to be called is loaded into a register and then one of these labels is called via a BL instruction. This puts the return address into the link register with the bottom bit set, and the code here switches to the correct mode before executing the function. Unfortunately the target code cannot be relied upon to return via a BX instruction, so instead we have to store the resturn address on the stack and allow the called function to return here instead. Upon return we recover the real return address and use a BX to get back to Thumb mode. */ .text .align 0 .code 32 .globl _arm_return _arm_return: ldmia r13!, {r12} bx r12 .code 16 .macro interwork register .code 16 THUMB_FUNC_START _interwork_call_via_\register bx pc nop .code 32 .globl .Lchange_\register .Lchange_\register: tst \register, #1 stmeqdb r13!, {lr} adreq lr, _arm_return bx \register SIZE (_interwork_call_via_\register) .endm interwork r0 interwork r1 interwork r2 interwork r3 interwork r4 interwork r5 interwork r6 interwork r7 interwork r8 interwork r9 interwork sl interwork fp interwork ip interwork sp /* The LR case has to be handled a little differently... */ .code 16 THUMB_FUNC_START _interwork_call_via_lr bx pc nop .code 32 .globl .Lchange_lr .Lchange_lr: tst lr, #1 stmeqdb r13!, {lr} mov ip, lr adreq lr, _arm_return bx ip SIZE (_interwork_call_via_lr) #endif /* L_interwork_call_via_rX */