120 lines
3.2 KiB
ArmAsm
120 lines
3.2 KiB
ArmAsm
.section .text..SHmedia32,"ax"
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.align 2
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.global __udivdi3
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__udivdi3:
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shlri r3,1,r4
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nsb r4,r22
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shlld r3,r22,r6
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shlri r6,49,r5
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movi 0xffffffffffffbaf1,r21 /* .l shift count 17. */
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sub r21,r5,r1
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mmulfx.w r1,r1,r4
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mshflo.w r1,r63,r1
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sub r63,r22,r20 // r63 == 64 % 64
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mmulfx.w r5,r4,r4
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pta large_divisor,tr0
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addi r20,32,r9
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msub.w r1,r4,r1
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madd.w r1,r1,r1
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mmulfx.w r1,r1,r4
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shlri r6,32,r7
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bgt/u r9,r63,tr0 // large_divisor
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mmulfx.w r5,r4,r4
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shlri r2,32+14,r19
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addi r22,-31,r0
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msub.w r1,r4,r1
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mulu.l r1,r7,r4
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addi r1,-3,r5
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mulu.l r5,r19,r5
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sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
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shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
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the case may be, %0000000000000000 000.11111111111, still */
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muls.l r1,r4,r4 /* leaving at least one sign bit. */
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mulu.l r5,r3,r8
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mshalds.l r1,r21,r1
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shari r4,26,r4
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shlld r8,r0,r8
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add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
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sub r2,r8,r2
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/* Can do second step of 64 : 32 div now, using r1 and the rest in r2. */
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shlri r2,22,r21
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mulu.l r21,r1,r21
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shlld r5,r0,r8
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addi r20,30-22,r0
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shlrd r21,r0,r21
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mulu.l r21,r3,r5
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add r8,r21,r8
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mcmpgt.l r21,r63,r21 // See Note 1
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addi r20,30,r0
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mshfhi.l r63,r21,r21
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sub r2,r5,r2
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andc r2,r21,r2
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/* small divisor: need a third divide step */
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mulu.l r2,r1,r7
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ptabs r18,tr0
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addi r2,1,r2
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shlrd r7,r0,r7
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mulu.l r7,r3,r5
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add r8,r7,r8
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sub r2,r3,r2
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cmpgt r2,r5,r5
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add r8,r5,r2
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/* could test r3 here to check for divide by zero. */
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blink tr0,r63
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large_divisor:
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mmulfx.w r5,r4,r4
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shlrd r2,r9,r25
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shlri r25,32,r8
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msub.w r1,r4,r1
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mulu.l r1,r7,r4
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addi r1,-3,r5
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mulu.l r5,r8,r5
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sub r63,r4,r4 // Negate to make sure r1 ends up <= 1/r2
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shlri r4,2,r4 /* chop off leading %0000000000000000 001.00000000000 - or, as
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the case may be, %0000000000000000 000.11111111111, still */
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muls.l r1,r4,r4 /* leaving at least one sign bit. */
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shlri r5,14-1,r8
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mulu.l r8,r7,r5
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mshalds.l r1,r21,r1
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shari r4,26,r4
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add r1,r4,r1 // 31 bit unsigned reciprocal now in r1 (msb equiv. 0.5)
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sub r25,r5,r25
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/* Can do second step of 64 : 32 div now, using r1 and the rest in r25. */
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shlri r25,22,r21
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mulu.l r21,r1,r21
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pta no_lo_adj,tr0
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addi r22,32,r0
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shlri r21,40,r21
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mulu.l r21,r7,r5
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add r8,r21,r8
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shlld r2,r0,r2
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sub r25,r5,r25
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bgtu/u r7,r25,tr0 // no_lo_adj
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addi r8,1,r8
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sub r25,r7,r25
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no_lo_adj:
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mextr4 r2,r25,r2
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/* large_divisor: only needs a few adjustments. */
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mulu.l r8,r6,r5
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ptabs r18,tr0
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/* bubble */
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cmpgtu r5,r2,r5
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sub r8,r5,r2
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blink tr0,r63
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/* Note 1: To shift the result of the second divide stage so that the result
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always fits into 32 bits, yet we still reduce the rest sufficiently
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would require a lot of instructions to do the shifts just right. Using
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the full 64 bit shift result to multiply with the divisor would require
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four extra instructions for the upper 32 bits (shift / mulu / shift / sub).
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Fortunately, if the upper 32 bits of the shift result are nonzero, we
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know that the rest after taking this partial result into account will
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fit into 32 bits. So we just clear the upper 32 bits of the rest if the
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upper 32 bits of the partial result are nonzero. */
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