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[/] [openrisc/] [trunk/] [gnu-old/] [gcc-4.2.2/] [gcc/] [config/] [arm/] [ieee754-df.S] - Rev 816
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/* ieee754-df.S double-precision floating point support for ARMCopyright (C) 2003, 2004, 2005 Free Software Foundation, Inc.Contributed by Nicolas Pitre (nico@cam.org)This file 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 into combinations with other programs,and to distribute those combinations without any restriction comingfrom the use of this file. (The General Public License restrictionsdo apply in other respects; for example, they cover modification ofthe file, and distribution when not linked into a combineexecutable.)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. *//** Notes:** The goal of this code is to be as fast as possible. This is* not meant to be easy to understand for the casual reader.* For slightly simpler code please see the single precision version* of this file.** Only the default rounding mode is intended for best performances.* Exceptions aren't supported yet, but that can be added quite easily* if necessary without impacting performances.*/@ For FPA, float words are always big-endian.@ For VFP, floats words follow the memory system mode.#if defined(__VFP_FP__) && !defined(__ARMEB__)#define xl r0#define xh r1#define yl r2#define yh r3#else#define xh r0#define xl r1#define yh r2#define yl r3#endif#ifdef L_negdf2ARM_FUNC_START negdf2ARM_FUNC_ALIAS aeabi_dneg negdf2@ flip sign biteor xh, xh, #0x80000000RETFUNC_END aeabi_dnegFUNC_END negdf2#endif#ifdef L_addsubdf3ARM_FUNC_START aeabi_drsubeor xh, xh, #0x80000000 @ flip sign bit of first argb 1fARM_FUNC_START subdf3ARM_FUNC_ALIAS aeabi_dsub subdf3eor yh, yh, #0x80000000 @ flip sign bit of second arg#if defined(__INTERWORKING_STUBS__)b 1f @ Skip Thumb-code prologue#endifARM_FUNC_START adddf3ARM_FUNC_ALIAS aeabi_dadd adddf31: stmfd sp!, {r4, r5, lr}@ Look for zeroes, equal values, INF, or NAN.mov r4, xh, lsl #1mov r5, yh, lsl #1teq r4, r5teqeq xl, ylorrnes ip, r4, xlorrnes ip, r5, ylmvnnes ip, r4, asr #21mvnnes ip, r5, asr #21beq LSYM(Lad_s)@ Compute exponent difference. Make largest exponent in r4,@ corresponding arg in xh-xl, and positive exponent difference in r5.mov r4, r4, lsr #21rsbs r5, r4, r5, lsr #21rsblt r5, r5, #0ble 1fadd r4, r4, r5eor yl, xl, yleor yh, xh, yheor xl, yl, xleor xh, yh, xheor yl, xl, yleor yh, xh, yh1:@ If exponent difference is too large, return largest argument@ already in xh-xl. We need up to 54 bit to handle proper rounding@ of 0x1p54 - 1.1.cmp r5, #54RETLDM "r4, r5" hi@ Convert mantissa to signed integer.tst xh, #0x80000000mov xh, xh, lsl #12mov ip, #0x00100000orr xh, ip, xh, lsr #12beq 1frsbs xl, xl, #0rsc xh, xh, #01:tst yh, #0x80000000mov yh, yh, lsl #12orr yh, ip, yh, lsr #12beq 1frsbs yl, yl, #0rsc yh, yh, #01:@ If exponent == difference, one or both args were denormalized.@ Since this is not common case, rescale them off line.teq r4, r5beq LSYM(Lad_d)LSYM(Lad_x):@ Compensate for the exponent overlapping the mantissa MSB added latersub r4, r4, #1@ Shift yh-yl right per r5, add to xh-xl, keep leftover bits into ip.rsbs lr, r5, #32blt 1fmov ip, yl, lsl lradds xl, xl, yl, lsr r5adc xh, xh, #0adds xl, xl, yh, lsl lradcs xh, xh, yh, asr r5b 2f1: sub r5, r5, #32add lr, lr, #32cmp yl, #1mov ip, yh, lsl lrorrcs ip, ip, #2 @ 2 not 1, to allow lsr #1 lateradds xl, xl, yh, asr r5adcs xh, xh, yh, asr #312:@ We now have a result in xh-xl-ip.@ Keep absolute value in xh-xl-ip, sign in r5 (the n bit was set above)and r5, xh, #0x80000000bpl LSYM(Lad_p)rsbs ip, ip, #0rscs xl, xl, #0rsc xh, xh, #0@ Determine how to normalize the result.LSYM(Lad_p):cmp xh, #0x00100000bcc LSYM(Lad_a)cmp xh, #0x00200000bcc LSYM(Lad_e)@ Result needs to be shifted right.movs xh, xh, lsr #1movs xl, xl, rrxmov ip, ip, rrxadd r4, r4, #1@ Make sure we did not bust our exponent.mov r2, r4, lsl #21cmn r2, #(2 << 21)bcs LSYM(Lad_o)@ Our result is now properly aligned into xh-xl, remaining bits in ip.@ Round with MSB of ip. If halfway between two numbers, round towards@ LSB of xl = 0.@ Pack final result together.LSYM(Lad_e):cmp ip, #0x80000000moveqs ip, xl, lsr #1adcs xl, xl, #0adc xh, xh, r4, lsl #20orr xh, xh, r5RETLDM "r4, r5"@ Result must be shifted left and exponent adjusted.LSYM(Lad_a):movs ip, ip, lsl #1adcs xl, xl, xladc xh, xh, xhtst xh, #0x00100000sub r4, r4, #1bne LSYM(Lad_e)@ No rounding necessary since ip will always be 0 at this point.LSYM(Lad_l):#if __ARM_ARCH__ < 5teq xh, #0movne r3, #20moveq r3, #52moveq xh, xlmoveq xl, #0mov r2, xhcmp r2, #(1 << 16)movhs r2, r2, lsr #16subhs r3, r3, #16cmp r2, #(1 << 8)movhs r2, r2, lsr #8subhs r3, r3, #8cmp r2, #(1 << 4)movhs r2, r2, lsr #4subhs r3, r3, #4cmp r2, #(1 << 2)subhs r3, r3, #2sublo r3, r3, r2, lsr #1sub r3, r3, r2, lsr #3#elseteq xh, #0moveq xh, xlmoveq xl, #0clz r3, xhaddeq r3, r3, #32sub r3, r3, #11#endif@ determine how to shift the value.subs r2, r3, #32bge 2fadds r2, r2, #12ble 1f@ shift value left 21 to 31 bits, or actually right 11 to 1 bits@ since a register switch happened above.add ip, r2, #20rsb r2, r2, #12mov xl, xh, lsl ipmov xh, xh, lsr r2b 3f@ actually shift value left 1 to 20 bits, which might also represent@ 32 to 52 bits if counting the register switch that happened earlier.1: add r2, r2, #202: rsble ip, r2, #32mov xh, xh, lsl r2orrle xh, xh, xl, lsr ipmovle xl, xl, lsl r2@ adjust exponent accordingly.3: subs r4, r4, r3addge xh, xh, r4, lsl #20orrge xh, xh, r5RETLDM "r4, r5" ge@ Exponent too small, denormalize result.@ Find out proper shift value.mvn r4, r4subs r4, r4, #31bge 2fadds r4, r4, #12bgt 1f@ shift result right of 1 to 20 bits, sign is in r5.add r4, r4, #20rsb r2, r4, #32mov xl, xl, lsr r4orr xl, xl, xh, lsl r2orr xh, r5, xh, lsr r4RETLDM "r4, r5"@ shift result right of 21 to 31 bits, or left 11 to 1 bits after@ a register switch from xh to xl.1: rsb r4, r4, #12rsb r2, r4, #32mov xl, xl, lsr r2orr xl, xl, xh, lsl r4mov xh, r5RETLDM "r4, r5"@ Shift value right of 32 to 64 bits, or 0 to 32 bits after a switch@ from xh to xl.2: mov xl, xh, lsr r4mov xh, r5RETLDM "r4, r5"@ Adjust exponents for denormalized arguments.@ Note that r4 must not remain equal to 0.LSYM(Lad_d):teq r4, #0eor yh, yh, #0x00100000eoreq xh, xh, #0x00100000addeq r4, r4, #1subne r5, r5, #1b LSYM(Lad_x)LSYM(Lad_s):mvns ip, r4, asr #21mvnnes ip, r5, asr #21beq LSYM(Lad_i)teq r4, r5teqeq xl, ylbeq 1f@ Result is x + 0.0 = x or 0.0 + y = y.orrs ip, r4, xlmoveq xh, yhmoveq xl, ylRETLDM "r4, r5"1: teq xh, yh@ Result is x - x = 0.movne xh, #0movne xl, #0RETLDM "r4, r5" ne@ Result is x + x = 2x.movs ip, r4, lsr #21bne 2fmovs xl, xl, lsl #1adcs xh, xh, xhorrcs xh, xh, #0x80000000RETLDM "r4, r5"2: adds r4, r4, #(2 << 21)addcc xh, xh, #(1 << 20)RETLDM "r4, r5" ccand r5, xh, #0x80000000@ Overflow: return INF.LSYM(Lad_o):orr xh, r5, #0x7f000000orr xh, xh, #0x00f00000mov xl, #0RETLDM "r4, r5"@ At least one of x or y is INF/NAN.@ if xh-xl != INF/NAN: return yh-yl (which is INF/NAN)@ if yh-yl != INF/NAN: return xh-xl (which is INF/NAN)@ if either is NAN: return NAN@ if opposite sign: return NAN@ otherwise return xh-xl (which is INF or -INF)LSYM(Lad_i):mvns ip, r4, asr #21movne xh, yhmovne xl, ylmvneqs ip, r5, asr #21movne yh, xhmovne yl, xlorrs r4, xl, xh, lsl #12orreqs r5, yl, yh, lsl #12teqeq xh, yhorrne xh, xh, #0x00080000 @ quiet NANRETLDM "r4, r5"FUNC_END aeabi_dsubFUNC_END subdf3FUNC_END aeabi_daddFUNC_END adddf3ARM_FUNC_START floatunsidfARM_FUNC_ALIAS aeabi_ui2d floatunsidfteq r0, #0moveq r1, #0RETc(eq)stmfd sp!, {r4, r5, lr}mov r4, #0x400 @ initial exponentadd r4, r4, #(52-1 - 1)mov r5, #0 @ sign bit is 0.ifnc xl, r0mov xl, r0.endifmov xh, #0b LSYM(Lad_l)FUNC_END aeabi_ui2dFUNC_END floatunsidfARM_FUNC_START floatsidfARM_FUNC_ALIAS aeabi_i2d floatsidfteq r0, #0moveq r1, #0RETc(eq)stmfd sp!, {r4, r5, lr}mov r4, #0x400 @ initial exponentadd r4, r4, #(52-1 - 1)ands r5, r0, #0x80000000 @ sign bit in r5rsbmi r0, r0, #0 @ absolute value.ifnc xl, r0mov xl, r0.endifmov xh, #0b LSYM(Lad_l)FUNC_END aeabi_i2dFUNC_END floatsidfARM_FUNC_START extendsfdf2ARM_FUNC_ALIAS aeabi_f2d extendsfdf2movs r2, r0, lsl #1 @ toss sign bitmov xh, r2, asr #3 @ stretch exponentmov xh, xh, rrx @ retrieve sign bitmov xl, r2, lsl #28 @ retrieve remaining bitsandnes r3, r2, #0xff000000 @ isolate exponentteqne r3, #0xff000000 @ if not 0, check if INF or NANeorne xh, xh, #0x38000000 @ fixup exponent otherwise.RETc(ne) @ and return it.teq r2, #0 @ if actually 0teqne r3, #0xff000000 @ or INF or NANRETc(eq) @ we are done already.@ value was denormalized. We can normalize it now.stmfd sp!, {r4, r5, lr}mov r4, #0x380 @ setup corresponding exponentand r5, xh, #0x80000000 @ move sign bit in r5bic xh, xh, #0x80000000b LSYM(Lad_l)FUNC_END aeabi_f2dFUNC_END extendsfdf2ARM_FUNC_START floatundidfARM_FUNC_ALIAS aeabi_ul2d floatundidforrs r2, r0, r1#if !defined (__VFP_FP__) && !defined(__SOFTFP__)mvfeqd f0, #0.0#endifRETc(eq)#if !defined (__VFP_FP__) && !defined(__SOFTFP__)@ For hard FPA code we want to return via the tail below so that@ we can return the result in f0 as well as in r0/r1 for backwards@ compatibility.adr ip, LSYM(f0_ret)stmfd sp!, {r4, r5, ip, lr}#elsestmfd sp!, {r4, r5, lr}#endifmov r5, #0b 2fARM_FUNC_START floatdidfARM_FUNC_ALIAS aeabi_l2d floatdidforrs r2, r0, r1#if !defined (__VFP_FP__) && !defined(__SOFTFP__)mvfeqd f0, #0.0#endifRETc(eq)#if !defined (__VFP_FP__) && !defined(__SOFTFP__)@ For hard FPA code we want to return via the tail below so that@ we can return the result in f0 as well as in r0/r1 for backwards@ compatibility.adr ip, LSYM(f0_ret)stmfd sp!, {r4, r5, ip, lr}#elsestmfd sp!, {r4, r5, lr}#endifands r5, ah, #0x80000000 @ sign bit in r5bpl 2frsbs al, al, #0rsc ah, ah, #02:mov r4, #0x400 @ initial exponentadd r4, r4, #(52-1 - 1)@ FPA little-endian: must swap the word order..ifnc xh, ahmov ip, almov xh, ahmov xl, ip.endifmovs ip, xh, lsr #22beq LSYM(Lad_p)@ The value is too big. Scale it down a bit...mov r2, #3movs ip, ip, lsr #3addne r2, r2, #3movs ip, ip, lsr #3addne r2, r2, #3add r2, r2, ip, lsr #3rsb r3, r2, #32mov ip, xl, lsl r3mov xl, xl, lsr r2orr xl, xl, xh, lsl r3mov xh, xh, lsr r2add r4, r4, r2b LSYM(Lad_p)#if !defined (__VFP_FP__) && !defined(__SOFTFP__)@ Legacy code expects the result to be returned in f0. Copy it@ there as well.LSYM(f0_ret):stmfd sp!, {r0, r1}ldfd f0, [sp], #8RETLDM#endifFUNC_END floatdidfFUNC_END aeabi_l2dFUNC_END floatundidfFUNC_END aeabi_ul2d#endif /* L_addsubdf3 */#ifdef L_muldivdf3ARM_FUNC_START muldf3ARM_FUNC_ALIAS aeabi_dmul muldf3stmfd sp!, {r4, r5, r6, lr}@ Mask out exponents, trap any zero/denormal/INF/NAN.mov ip, #0xfforr ip, ip, #0x700ands r4, ip, xh, lsr #20andnes r5, ip, yh, lsr #20teqne r4, ipteqne r5, ipbleq LSYM(Lml_s)@ Add exponents togetheradd r4, r4, r5@ Determine final sign.eor r6, xh, yh@ Convert mantissa to unsigned integer.@ If power of two, branch to a separate path.bic xh, xh, ip, lsl #21bic yh, yh, ip, lsl #21orrs r5, xl, xh, lsl #12orrnes r5, yl, yh, lsl #12orr xh, xh, #0x00100000orr yh, yh, #0x00100000beq LSYM(Lml_1)#if __ARM_ARCH__ < 4@ Put sign bit in r6, which will be restored in yl later.and r6, r6, #0x80000000@ Well, no way to make it shorter without the umull instruction.stmfd sp!, {r6, r7, r8, r9, sl, fp}mov r7, xl, lsr #16mov r8, yl, lsr #16mov r9, xh, lsr #16mov sl, yh, lsr #16bic xl, xl, r7, lsl #16bic yl, yl, r8, lsl #16bic xh, xh, r9, lsl #16bic yh, yh, sl, lsl #16mul ip, xl, ylmul fp, xl, r8mov lr, #0adds ip, ip, fp, lsl #16adc lr, lr, fp, lsr #16mul fp, r7, yladds ip, ip, fp, lsl #16adc lr, lr, fp, lsr #16mul fp, xl, slmov r5, #0adds lr, lr, fp, lsl #16adc r5, r5, fp, lsr #16mul fp, r7, yhadds lr, lr, fp, lsl #16adc r5, r5, fp, lsr #16mul fp, xh, r8adds lr, lr, fp, lsl #16adc r5, r5, fp, lsr #16mul fp, r9, yladds lr, lr, fp, lsl #16adc r5, r5, fp, lsr #16mul fp, xh, slmul r6, r9, sladds r5, r5, fp, lsl #16adc r6, r6, fp, lsr #16mul fp, r9, yhadds r5, r5, fp, lsl #16adc r6, r6, fp, lsr #16mul fp, xl, yhadds lr, lr, fpmul fp, r7, sladcs r5, r5, fpmul fp, xh, yladc r6, r6, #0adds lr, lr, fpmul fp, r9, r8adcs r5, r5, fpmul fp, r7, r8adc r6, r6, #0adds lr, lr, fpmul fp, xh, yhadcs r5, r5, fpadc r6, r6, #0ldmfd sp!, {yl, r7, r8, r9, sl, fp}#else@ Here is the actual multiplication.umull ip, lr, xl, ylmov r5, #0umlal lr, r5, xh, yland yl, r6, #0x80000000umlal lr, r5, xl, yhmov r6, #0umlal r5, r6, xh, yh#endif@ The LSBs in ip are only significant for the final rounding.@ Fold them into lr.teq ip, #0orrne lr, lr, #1@ Adjust result upon the MSB position.sub r4, r4, #0xffcmp r6, #(1 << (20-11))sbc r4, r4, #0x300bcs 1fmovs lr, lr, lsl #1adcs r5, r5, r5adc r6, r6, r61:@ Shift to final position, add sign to result.orr xh, yl, r6, lsl #11orr xh, xh, r5, lsr #21mov xl, r5, lsl #11orr xl, xl, lr, lsr #21mov lr, lr, lsl #11@ Check exponent range for under/overflow.subs ip, r4, #(254 - 1)cmphi ip, #0x700bhi LSYM(Lml_u)@ Round the result, merge final exponent.cmp lr, #0x80000000moveqs lr, xl, lsr #1adcs xl, xl, #0adc xh, xh, r4, lsl #20RETLDM "r4, r5, r6"@ Multiplication by 0x1p*: let''s shortcut a lot of code.LSYM(Lml_1):and r6, r6, #0x80000000orr xh, r6, xhorr xl, xl, yleor xh, xh, yhsubs r4, r4, ip, lsr #1rsbgts r5, r4, iporrgt xh, xh, r4, lsl #20RETLDM "r4, r5, r6" gt@ Under/overflow: fix things up for the code below.orr xh, xh, #0x00100000mov lr, #0subs r4, r4, #1LSYM(Lml_u):@ Overflow?bgt LSYM(Lml_o)@ Check if denormalized result is possible, otherwise return signed 0.cmn r4, #(53 + 1)movle xl, #0bicle xh, xh, #0x7fffffffRETLDM "r4, r5, r6" le@ Find out proper shift value.rsb r4, r4, #0subs r4, r4, #32bge 2fadds r4, r4, #12bgt 1f@ shift result right of 1 to 20 bits, preserve sign bit, round, etc.add r4, r4, #20rsb r5, r4, #32mov r3, xl, lsl r5mov xl, xl, lsr r4orr xl, xl, xh, lsl r5and r2, xh, #0x80000000bic xh, xh, #0x80000000adds xl, xl, r3, lsr #31adc xh, r2, xh, lsr r4orrs lr, lr, r3, lsl #1biceq xl, xl, r3, lsr #31RETLDM "r4, r5, r6"@ shift result right of 21 to 31 bits, or left 11 to 1 bits after@ a register switch from xh to xl. Then round.1: rsb r4, r4, #12rsb r5, r4, #32mov r3, xl, lsl r4mov xl, xl, lsr r5orr xl, xl, xh, lsl r4bic xh, xh, #0x7fffffffadds xl, xl, r3, lsr #31adc xh, xh, #0orrs lr, lr, r3, lsl #1biceq xl, xl, r3, lsr #31RETLDM "r4, r5, r6"@ Shift value right of 32 to 64 bits, or 0 to 32 bits after a switch@ from xh to xl. Leftover bits are in r3-r6-lr for rounding.2: rsb r5, r4, #32orr lr, lr, xl, lsl r5mov r3, xl, lsr r4orr r3, r3, xh, lsl r5mov xl, xh, lsr r4bic xh, xh, #0x7fffffffbic xl, xl, xh, lsr r4add xl, xl, r3, lsr #31orrs lr, lr, r3, lsl #1biceq xl, xl, r3, lsr #31RETLDM "r4, r5, r6"@ One or both arguments are denormalized.@ Scale them leftwards and preserve sign bit.LSYM(Lml_d):teq r4, #0bne 2fand r6, xh, #0x800000001: movs xl, xl, lsl #1adc xh, xh, xhtst xh, #0x00100000subeq r4, r4, #1beq 1borr xh, xh, r6teq r5, #0movne pc, lr2: and r6, yh, #0x800000003: movs yl, yl, lsl #1adc yh, yh, yhtst yh, #0x00100000subeq r5, r5, #1beq 3borr yh, yh, r6mov pc, lrLSYM(Lml_s):@ Isolate the INF and NAN cases awayteq r4, ipand r5, ip, yh, lsr #20teqne r5, ipbeq 1f@ Here, one or more arguments are either denormalized or zero.orrs r6, xl, xh, lsl #1orrnes r6, yl, yh, lsl #1bne LSYM(Lml_d)@ Result is 0, but determine sign anyway.LSYM(Lml_z):eor xh, xh, yhbic xh, xh, #0x7fffffffmov xl, #0RETLDM "r4, r5, r6"1: @ One or both args are INF or NAN.orrs r6, xl, xh, lsl #1moveq xl, ylmoveq xh, yhorrnes r6, yl, yh, lsl #1beq LSYM(Lml_n) @ 0 * INF or INF * 0 -> NANteq r4, ipbne 1forrs r6, xl, xh, lsl #12bne LSYM(Lml_n) @ NAN * <anything> -> NAN1: teq r5, ipbne LSYM(Lml_i)orrs r6, yl, yh, lsl #12movne xl, ylmovne xh, yhbne LSYM(Lml_n) @ <anything> * NAN -> NAN@ Result is INF, but we need to determine its sign.LSYM(Lml_i):eor xh, xh, yh@ Overflow: return INF (sign already in xh).LSYM(Lml_o):and xh, xh, #0x80000000orr xh, xh, #0x7f000000orr xh, xh, #0x00f00000mov xl, #0RETLDM "r4, r5, r6"@ Return a quiet NAN.LSYM(Lml_n):orr xh, xh, #0x7f000000orr xh, xh, #0x00f80000RETLDM "r4, r5, r6"FUNC_END aeabi_dmulFUNC_END muldf3ARM_FUNC_START divdf3ARM_FUNC_ALIAS aeabi_ddiv divdf3stmfd sp!, {r4, r5, r6, lr}@ Mask out exponents, trap any zero/denormal/INF/NAN.mov ip, #0xfforr ip, ip, #0x700ands r4, ip, xh, lsr #20andnes r5, ip, yh, lsr #20teqne r4, ipteqne r5, ipbleq LSYM(Ldv_s)@ Substract divisor exponent from dividend''s.sub r4, r4, r5@ Preserve final sign into lr.eor lr, xh, yh@ Convert mantissa to unsigned integer.@ Dividend -> r5-r6, divisor -> yh-yl.orrs r5, yl, yh, lsl #12mov xh, xh, lsl #12beq LSYM(Ldv_1)mov yh, yh, lsl #12mov r5, #0x10000000orr yh, r5, yh, lsr #4orr yh, yh, yl, lsr #24mov yl, yl, lsl #8orr r5, r5, xh, lsr #4orr r5, r5, xl, lsr #24mov r6, xl, lsl #8@ Initialize xh with final sign bit.and xh, lr, #0x80000000@ Ensure result will land to known bit position.@ Apply exponent bias accordingly.cmp r5, yhcmpeq r6, yladc r4, r4, #(255 - 2)add r4, r4, #0x300bcs 1fmovs yh, yh, lsr #1mov yl, yl, rrx1:@ Perform first substraction to align result to a nibble.subs r6, r6, ylsbc r5, r5, yhmovs yh, yh, lsr #1mov yl, yl, rrxmov xl, #0x00100000mov ip, #0x00080000@ The actual division loop.1: subs lr, r6, ylsbcs lr, r5, yhsubcs r6, r6, ylmovcs r5, lrorrcs xl, xl, ipmovs yh, yh, lsr #1mov yl, yl, rrxsubs lr, r6, ylsbcs lr, r5, yhsubcs r6, r6, ylmovcs r5, lrorrcs xl, xl, ip, lsr #1movs yh, yh, lsr #1mov yl, yl, rrxsubs lr, r6, ylsbcs lr, r5, yhsubcs r6, r6, ylmovcs r5, lrorrcs xl, xl, ip, lsr #2movs yh, yh, lsr #1mov yl, yl, rrxsubs lr, r6, ylsbcs lr, r5, yhsubcs r6, r6, ylmovcs r5, lrorrcs xl, xl, ip, lsr #3orrs lr, r5, r6beq 2fmov r5, r5, lsl #4orr r5, r5, r6, lsr #28mov r6, r6, lsl #4mov yh, yh, lsl #3orr yh, yh, yl, lsr #29mov yl, yl, lsl #3movs ip, ip, lsr #4bne 1b@ We are done with a word of the result.@ Loop again for the low word if this pass was for the high word.tst xh, #0x00100000bne 3forr xh, xh, xlmov xl, #0mov ip, #0x80000000b 1b2:@ Be sure result starts in the high word.tst xh, #0x00100000orreq xh, xh, xlmoveq xl, #03:@ Check exponent range for under/overflow.subs ip, r4, #(254 - 1)cmphi ip, #0x700bhi LSYM(Lml_u)@ Round the result, merge final exponent.subs ip, r5, yhsubeqs ip, r6, ylmoveqs ip, xl, lsr #1adcs xl, xl, #0adc xh, xh, r4, lsl #20RETLDM "r4, r5, r6"@ Division by 0x1p*: shortcut a lot of code.LSYM(Ldv_1):and lr, lr, #0x80000000orr xh, lr, xh, lsr #12adds r4, r4, ip, lsr #1rsbgts r5, r4, iporrgt xh, xh, r4, lsl #20RETLDM "r4, r5, r6" gtorr xh, xh, #0x00100000mov lr, #0subs r4, r4, #1b LSYM(Lml_u)@ Result mightt need to be denormalized: put remainder bits@ in lr for rounding considerations.LSYM(Ldv_u):orr lr, r5, r6b LSYM(Lml_u)@ One or both arguments is either INF, NAN or zero.LSYM(Ldv_s):and r5, ip, yh, lsr #20teq r4, ipteqeq r5, ipbeq LSYM(Lml_n) @ INF/NAN / INF/NAN -> NANteq r4, ipbne 1forrs r4, xl, xh, lsl #12bne LSYM(Lml_n) @ NAN / <anything> -> NANteq r5, ipbne LSYM(Lml_i) @ INF / <anything> -> INFmov xl, ylmov xh, yhb LSYM(Lml_n) @ INF / (INF or NAN) -> NAN1: teq r5, ipbne 2forrs r5, yl, yh, lsl #12beq LSYM(Lml_z) @ <anything> / INF -> 0mov xl, ylmov xh, yhb LSYM(Lml_n) @ <anything> / NAN -> NAN2: @ If both are nonzero, we need to normalize and resume above.orrs r6, xl, xh, lsl #1orrnes r6, yl, yh, lsl #1bne LSYM(Lml_d)@ One or both arguments are 0.orrs r4, xl, xh, lsl #1bne LSYM(Lml_i) @ <non_zero> / 0 -> INForrs r5, yl, yh, lsl #1bne LSYM(Lml_z) @ 0 / <non_zero> -> 0b LSYM(Lml_n) @ 0 / 0 -> NANFUNC_END aeabi_ddivFUNC_END divdf3#endif /* L_muldivdf3 */#ifdef L_cmpdf2@ Note: only r0 (return value) and ip are clobbered here.ARM_FUNC_START gtdf2ARM_FUNC_ALIAS gedf2 gtdf2mov ip, #-1b 1fARM_FUNC_START ltdf2ARM_FUNC_ALIAS ledf2 ltdf2mov ip, #1b 1fARM_FUNC_START cmpdf2ARM_FUNC_ALIAS nedf2 cmpdf2ARM_FUNC_ALIAS eqdf2 cmpdf2mov ip, #1 @ how should we specify unordered here?1: str ip, [sp, #-4]@ Trap any INF/NAN first.mov ip, xh, lsl #1mvns ip, ip, asr #21mov ip, yh, lsl #1mvnnes ip, ip, asr #21beq 3f@ Test for equality.@ Note that 0.0 is equal to -0.0.2: orrs ip, xl, xh, lsl #1 @ if x == 0.0 or -0.0orreqs ip, yl, yh, lsl #1 @ and y == 0.0 or -0.0teqne xh, yh @ or xh == yhteqeq xl, yl @ and xl == ylmoveq r0, #0 @ then equal.RETc(eq)@ Clear C flagcmn r0, #0@ Compare sign,teq xh, yh@ Compare values if same signcmppl xh, yhcmpeq xl, yl@ Result:movcs r0, yh, asr #31mvncc r0, yh, asr #31orr r0, r0, #1RET@ Look for a NAN.3: mov ip, xh, lsl #1mvns ip, ip, asr #21bne 4forrs ip, xl, xh, lsl #12bne 5f @ x is NAN4: mov ip, yh, lsl #1mvns ip, ip, asr #21bne 2borrs ip, yl, yh, lsl #12beq 2b @ y is not NAN5: ldr r0, [sp, #-4] @ unordered return codeRETFUNC_END gedf2FUNC_END gtdf2FUNC_END ledf2FUNC_END ltdf2FUNC_END nedf2FUNC_END eqdf2FUNC_END cmpdf2ARM_FUNC_START aeabi_cdrcmplemov ip, r0mov r0, r2mov r2, ipmov ip, r1mov r1, r3mov r3, ipb 6fARM_FUNC_START aeabi_cdcmpeqARM_FUNC_ALIAS aeabi_cdcmple aeabi_cdcmpeq@ The status-returning routines are required to preserve all@ registers except ip, lr, and cpsr.6: stmfd sp!, {r0, lr}ARM_CALL cmpdf2@ Set the Z flag correctly, and the C flag unconditionally.cmp r0, #0@ Clear the C flag if the return value was -1, indicating@ that the first operand was smaller than the second.cmnmi r0, #0RETLDM "r0"FUNC_END aeabi_cdcmpleFUNC_END aeabi_cdcmpeqFUNC_END aeabi_cdrcmpleARM_FUNC_START aeabi_dcmpeqstr lr, [sp, #-8]!ARM_CALL aeabi_cdcmplemoveq r0, #1 @ Equal to.movne r0, #0 @ Less than, greater than, or unordered.RETLDMFUNC_END aeabi_dcmpeqARM_FUNC_START aeabi_dcmpltstr lr, [sp, #-8]!ARM_CALL aeabi_cdcmplemovcc r0, #1 @ Less than.movcs r0, #0 @ Equal to, greater than, or unordered.RETLDMFUNC_END aeabi_dcmpltARM_FUNC_START aeabi_dcmplestr lr, [sp, #-8]!ARM_CALL aeabi_cdcmplemovls r0, #1 @ Less than or equal to.movhi r0, #0 @ Greater than or unordered.RETLDMFUNC_END aeabi_dcmpleARM_FUNC_START aeabi_dcmpgestr lr, [sp, #-8]!ARM_CALL aeabi_cdrcmplemovls r0, #1 @ Operand 2 is less than or equal to operand 1.movhi r0, #0 @ Operand 2 greater than operand 1, or unordered.RETLDMFUNC_END aeabi_dcmpgeARM_FUNC_START aeabi_dcmpgtstr lr, [sp, #-8]!ARM_CALL aeabi_cdrcmplemovcc r0, #1 @ Operand 2 is less than operand 1.movcs r0, #0 @ Operand 2 is greater than or equal to operand 1,@ or they are unordered.RETLDMFUNC_END aeabi_dcmpgt#endif /* L_cmpdf2 */#ifdef L_unorddf2ARM_FUNC_START unorddf2ARM_FUNC_ALIAS aeabi_dcmpun unorddf2mov ip, xh, lsl #1mvns ip, ip, asr #21bne 1forrs ip, xl, xh, lsl #12bne 3f @ x is NAN1: mov ip, yh, lsl #1mvns ip, ip, asr #21bne 2forrs ip, yl, yh, lsl #12bne 3f @ y is NAN2: mov r0, #0 @ arguments are ordered.RET3: mov r0, #1 @ arguments are unordered.RETFUNC_END aeabi_dcmpunFUNC_END unorddf2#endif /* L_unorddf2 */#ifdef L_fixdfsiARM_FUNC_START fixdfsiARM_FUNC_ALIAS aeabi_d2iz fixdfsi@ check exponent range.mov r2, xh, lsl #1adds r2, r2, #(1 << 21)bcs 2f @ value is INF or NANbpl 1f @ value is too smallmov r3, #(0xfffffc00 + 31)subs r2, r3, r2, asr #21bls 3f @ value is too large@ scale valuemov r3, xh, lsl #11orr r3, r3, #0x80000000orr r3, r3, xl, lsr #21tst xh, #0x80000000 @ the sign bitmov r0, r3, lsr r2rsbne r0, r0, #0RET1: mov r0, #0RET2: orrs xl, xl, xh, lsl #12bne 4f @ x is NAN.3: ands r0, xh, #0x80000000 @ the sign bitmoveq r0, #0x7fffffff @ maximum signed positive siRET4: mov r0, #0 @ How should we convert NAN?RETFUNC_END aeabi_d2izFUNC_END fixdfsi#endif /* L_fixdfsi */#ifdef L_fixunsdfsiARM_FUNC_START fixunsdfsiARM_FUNC_ALIAS aeabi_d2uiz fixunsdfsi@ check exponent range.movs r2, xh, lsl #1bcs 1f @ value is negativeadds r2, r2, #(1 << 21)bcs 2f @ value is INF or NANbpl 1f @ value is too smallmov r3, #(0xfffffc00 + 31)subs r2, r3, r2, asr #21bmi 3f @ value is too large@ scale valuemov r3, xh, lsl #11orr r3, r3, #0x80000000orr r3, r3, xl, lsr #21mov r0, r3, lsr r2RET1: mov r0, #0RET2: orrs xl, xl, xh, lsl #12bne 4f @ value is NAN.3: mov r0, #0xffffffff @ maximum unsigned siRET4: mov r0, #0 @ How should we convert NAN?RETFUNC_END aeabi_d2uizFUNC_END fixunsdfsi#endif /* L_fixunsdfsi */#ifdef L_truncdfsf2ARM_FUNC_START truncdfsf2ARM_FUNC_ALIAS aeabi_d2f truncdfsf2@ check exponent range.mov r2, xh, lsl #1subs r3, r2, #((1023 - 127) << 21)subcss ip, r3, #(1 << 21)rsbcss ip, ip, #(254 << 21)bls 2f @ value is out of range1: @ shift and round mantissaand ip, xh, #0x80000000mov r2, xl, lsl #3orr xl, ip, xl, lsr #29cmp r2, #0x80000000adc r0, xl, r3, lsl #2biceq r0, r0, #1RET2: @ either overflow or underflowtst xh, #0x40000000bne 3f @ overflow@ check if denormalized value is possibleadds r2, r3, #(23 << 21)andlt r0, xh, #0x80000000 @ too small, return signed 0.RETc(lt)@ denormalize value so we can resume with the code above afterwards.orr xh, xh, #0x00100000mov r2, r2, lsr #21rsb r2, r2, #24rsb ip, r2, #32movs r3, xl, lsl ipmov xl, xl, lsr r2orrne xl, xl, #1 @ fold r3 for rounding considerations.mov r3, xh, lsl #11mov r3, r3, lsr #11orr xl, xl, r3, lsl ipmov r3, r3, lsr r2mov r3, r3, lsl #1b 1b3: @ chech for NANmvns r3, r2, asr #21bne 5f @ simple overfloworrs r3, xl, xh, lsl #12movne r0, #0x7f000000orrne r0, r0, #0x00c00000RETc(ne) @ return NAN5: @ return INF with signand r0, xh, #0x80000000orr r0, r0, #0x7f000000orr r0, r0, #0x00800000RETFUNC_END aeabi_d2fFUNC_END truncdfsf2#endif /* L_truncdfsf2 */