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author | Wim <wim@42.be> | 2018-11-13 00:02:07 +0100 |
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committer | Wim <wim@42.be> | 2018-11-13 00:02:07 +0100 |
commit | f8dc24bc09fc1981637ac5c4a210780ac5512944 (patch) | |
tree | 0df78ce10744dbf3b25accdcb215a9b7b87b7e89 /vendor/golang.org/x/crypto/poly1305 | |
parent | e9419f10d3d24e24c9cedab93104c418f383782c (diff) | |
download | matterbridge-msglm-f8dc24bc09fc1981637ac5c4a210780ac5512944.tar.gz matterbridge-msglm-f8dc24bc09fc1981637ac5c4a210780ac5512944.tar.bz2 matterbridge-msglm-f8dc24bc09fc1981637ac5c4a210780ac5512944.zip |
Switch back go upstream bwmarrin/discordgo
Commit https://github.com/bwmarrin/discordgo/commit/ffa9956c9b41e8e2a10c26a254389854e016b006 got merged in.
Diffstat (limited to 'vendor/golang.org/x/crypto/poly1305')
-rw-r--r-- | vendor/golang.org/x/crypto/poly1305/sum_noasm.go | 14 | ||||
-rw-r--r-- | vendor/golang.org/x/crypto/poly1305/sum_ref.go | 10 | ||||
-rw-r--r-- | vendor/golang.org/x/crypto/poly1305/sum_s390x.go | 49 | ||||
-rw-r--r-- | vendor/golang.org/x/crypto/poly1305/sum_s390x.s | 400 | ||||
-rw-r--r-- | vendor/golang.org/x/crypto/poly1305/sum_vmsl_s390x.s | 931 |
5 files changed, 1398 insertions, 6 deletions
diff --git a/vendor/golang.org/x/crypto/poly1305/sum_noasm.go b/vendor/golang.org/x/crypto/poly1305/sum_noasm.go new file mode 100644 index 00000000..751eec52 --- /dev/null +++ b/vendor/golang.org/x/crypto/poly1305/sum_noasm.go @@ -0,0 +1,14 @@ +// Copyright 2018 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +// +build s390x,!go1.11 !arm,!amd64,!s390x gccgo appengine nacl + +package poly1305 + +// Sum generates an authenticator for msg using a one-time key and puts the +// 16-byte result into out. Authenticating two different messages with the same +// key allows an attacker to forge messages at will. +func Sum(out *[TagSize]byte, msg []byte, key *[32]byte) { + sumGeneric(out, msg, key) +} diff --git a/vendor/golang.org/x/crypto/poly1305/sum_ref.go b/vendor/golang.org/x/crypto/poly1305/sum_ref.go index b2805a5c..c4d59bd0 100644 --- a/vendor/golang.org/x/crypto/poly1305/sum_ref.go +++ b/vendor/golang.org/x/crypto/poly1305/sum_ref.go @@ -2,16 +2,14 @@ // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. -// +build !amd64,!arm gccgo appengine nacl - package poly1305 import "encoding/binary" -// Sum generates an authenticator for msg using a one-time key and puts the -// 16-byte result into out. Authenticating two different messages with the same -// key allows an attacker to forge messages at will. -func Sum(out *[TagSize]byte, msg []byte, key *[32]byte) { +// sumGeneric generates an authenticator for msg using a one-time key and +// puts the 16-byte result into out. This is the generic implementation of +// Sum and should be called if no assembly implementation is available. +func sumGeneric(out *[TagSize]byte, msg []byte, key *[32]byte) { var ( h0, h1, h2, h3, h4 uint32 // the hash accumulators r0, r1, r2, r3, r4 uint64 // the r part of the key diff --git a/vendor/golang.org/x/crypto/poly1305/sum_s390x.go b/vendor/golang.org/x/crypto/poly1305/sum_s390x.go new file mode 100644 index 00000000..7a266cec --- /dev/null +++ b/vendor/golang.org/x/crypto/poly1305/sum_s390x.go @@ -0,0 +1,49 @@ +// Copyright 2018 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +// +build s390x,go1.11,!gccgo,!appengine + +package poly1305 + +// hasVectorFacility reports whether the machine supports +// the vector facility (vx). +func hasVectorFacility() bool + +// hasVMSLFacility reports whether the machine supports +// Vector Multiply Sum Logical (VMSL). +func hasVMSLFacility() bool + +var hasVX = hasVectorFacility() +var hasVMSL = hasVMSLFacility() + +// poly1305vx is an assembly implementation of Poly1305 that uses vector +// instructions. It must only be called if the vector facility (vx) is +// available. +//go:noescape +func poly1305vx(out *[16]byte, m *byte, mlen uint64, key *[32]byte) + +// poly1305vmsl is an assembly implementation of Poly1305 that uses vector +// instructions, including VMSL. It must only be called if the vector facility (vx) is +// available and if VMSL is supported. +//go:noescape +func poly1305vmsl(out *[16]byte, m *byte, mlen uint64, key *[32]byte) + +// Sum generates an authenticator for m using a one-time key and puts the +// 16-byte result into out. Authenticating two different messages with the same +// key allows an attacker to forge messages at will. +func Sum(out *[16]byte, m []byte, key *[32]byte) { + if hasVX { + var mPtr *byte + if len(m) > 0 { + mPtr = &m[0] + } + if hasVMSL && len(m) > 256 { + poly1305vmsl(out, mPtr, uint64(len(m)), key) + } else { + poly1305vx(out, mPtr, uint64(len(m)), key) + } + } else { + sumGeneric(out, m, key) + } +} diff --git a/vendor/golang.org/x/crypto/poly1305/sum_s390x.s b/vendor/golang.org/x/crypto/poly1305/sum_s390x.s new file mode 100644 index 00000000..356c07a6 --- /dev/null +++ b/vendor/golang.org/x/crypto/poly1305/sum_s390x.s @@ -0,0 +1,400 @@ +// Copyright 2018 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +// +build s390x,go1.11,!gccgo,!appengine + +#include "textflag.h" + +// Implementation of Poly1305 using the vector facility (vx). + +// constants +#define MOD26 V0 +#define EX0 V1 +#define EX1 V2 +#define EX2 V3 + +// temporaries +#define T_0 V4 +#define T_1 V5 +#define T_2 V6 +#define T_3 V7 +#define T_4 V8 + +// key (r) +#define R_0 V9 +#define R_1 V10 +#define R_2 V11 +#define R_3 V12 +#define R_4 V13 +#define R5_1 V14 +#define R5_2 V15 +#define R5_3 V16 +#define R5_4 V17 +#define RSAVE_0 R5 +#define RSAVE_1 R6 +#define RSAVE_2 R7 +#define RSAVE_3 R8 +#define RSAVE_4 R9 +#define R5SAVE_1 V28 +#define R5SAVE_2 V29 +#define R5SAVE_3 V30 +#define R5SAVE_4 V31 + +// message block +#define F_0 V18 +#define F_1 V19 +#define F_2 V20 +#define F_3 V21 +#define F_4 V22 + +// accumulator +#define H_0 V23 +#define H_1 V24 +#define H_2 V25 +#define H_3 V26 +#define H_4 V27 + +GLOBL ·keyMask<>(SB), RODATA, $16 +DATA ·keyMask<>+0(SB)/8, $0xffffff0ffcffff0f +DATA ·keyMask<>+8(SB)/8, $0xfcffff0ffcffff0f + +GLOBL ·bswapMask<>(SB), RODATA, $16 +DATA ·bswapMask<>+0(SB)/8, $0x0f0e0d0c0b0a0908 +DATA ·bswapMask<>+8(SB)/8, $0x0706050403020100 + +GLOBL ·constants<>(SB), RODATA, $64 +// MOD26 +DATA ·constants<>+0(SB)/8, $0x3ffffff +DATA ·constants<>+8(SB)/8, $0x3ffffff +// EX0 +DATA ·constants<>+16(SB)/8, $0x0006050403020100 +DATA ·constants<>+24(SB)/8, $0x1016151413121110 +// EX1 +DATA ·constants<>+32(SB)/8, $0x060c0b0a09080706 +DATA ·constants<>+40(SB)/8, $0x161c1b1a19181716 +// EX2 +DATA ·constants<>+48(SB)/8, $0x0d0d0d0d0d0f0e0d +DATA ·constants<>+56(SB)/8, $0x1d1d1d1d1d1f1e1d + +// h = (f*g) % (2**130-5) [partial reduction] +#define MULTIPLY(f0, f1, f2, f3, f4, g0, g1, g2, g3, g4, g51, g52, g53, g54, h0, h1, h2, h3, h4) \ + VMLOF f0, g0, h0 \ + VMLOF f0, g1, h1 \ + VMLOF f0, g2, h2 \ + VMLOF f0, g3, h3 \ + VMLOF f0, g4, h4 \ + VMLOF f1, g54, T_0 \ + VMLOF f1, g0, T_1 \ + VMLOF f1, g1, T_2 \ + VMLOF f1, g2, T_3 \ + VMLOF f1, g3, T_4 \ + VMALOF f2, g53, h0, h0 \ + VMALOF f2, g54, h1, h1 \ + VMALOF f2, g0, h2, h2 \ + VMALOF f2, g1, h3, h3 \ + VMALOF f2, g2, h4, h4 \ + VMALOF f3, g52, T_0, T_0 \ + VMALOF f3, g53, T_1, T_1 \ + VMALOF f3, g54, T_2, T_2 \ + VMALOF f3, g0, T_3, T_3 \ + VMALOF f3, g1, T_4, T_4 \ + VMALOF f4, g51, h0, h0 \ + VMALOF f4, g52, h1, h1 \ + VMALOF f4, g53, h2, h2 \ + VMALOF f4, g54, h3, h3 \ + VMALOF f4, g0, h4, h4 \ + VAG T_0, h0, h0 \ + VAG T_1, h1, h1 \ + VAG T_2, h2, h2 \ + VAG T_3, h3, h3 \ + VAG T_4, h4, h4 + +// carry h0->h1 h3->h4, h1->h2 h4->h0, h0->h1 h2->h3, h3->h4 +#define REDUCE(h0, h1, h2, h3, h4) \ + VESRLG $26, h0, T_0 \ + VESRLG $26, h3, T_1 \ + VN MOD26, h0, h0 \ + VN MOD26, h3, h3 \ + VAG T_0, h1, h1 \ + VAG T_1, h4, h4 \ + VESRLG $26, h1, T_2 \ + VESRLG $26, h4, T_3 \ + VN MOD26, h1, h1 \ + VN MOD26, h4, h4 \ + VESLG $2, T_3, T_4 \ + VAG T_3, T_4, T_4 \ + VAG T_2, h2, h2 \ + VAG T_4, h0, h0 \ + VESRLG $26, h2, T_0 \ + VESRLG $26, h0, T_1 \ + VN MOD26, h2, h2 \ + VN MOD26, h0, h0 \ + VAG T_0, h3, h3 \ + VAG T_1, h1, h1 \ + VESRLG $26, h3, T_2 \ + VN MOD26, h3, h3 \ + VAG T_2, h4, h4 + +// expand in0 into d[0] and in1 into d[1] +#define EXPAND(in0, in1, d0, d1, d2, d3, d4) \ + VGBM $0x0707, d1 \ // d1=tmp + VPERM in0, in1, EX2, d4 \ + VPERM in0, in1, EX0, d0 \ + VPERM in0, in1, EX1, d2 \ + VN d1, d4, d4 \ + VESRLG $26, d0, d1 \ + VESRLG $30, d2, d3 \ + VESRLG $4, d2, d2 \ + VN MOD26, d0, d0 \ + VN MOD26, d1, d1 \ + VN MOD26, d2, d2 \ + VN MOD26, d3, d3 + +// pack h4:h0 into h1:h0 (no carry) +#define PACK(h0, h1, h2, h3, h4) \ + VESLG $26, h1, h1 \ + VESLG $26, h3, h3 \ + VO h0, h1, h0 \ + VO h2, h3, h2 \ + VESLG $4, h2, h2 \ + VLEIB $7, $48, h1 \ + VSLB h1, h2, h2 \ + VO h0, h2, h0 \ + VLEIB $7, $104, h1 \ + VSLB h1, h4, h3 \ + VO h3, h0, h0 \ + VLEIB $7, $24, h1 \ + VSRLB h1, h4, h1 + +// if h > 2**130-5 then h -= 2**130-5 +#define MOD(h0, h1, t0, t1, t2) \ + VZERO t0 \ + VLEIG $1, $5, t0 \ + VACCQ h0, t0, t1 \ + VAQ h0, t0, t0 \ + VONE t2 \ + VLEIG $1, $-4, t2 \ + VAQ t2, t1, t1 \ + VACCQ h1, t1, t1 \ + VONE t2 \ + VAQ t2, t1, t1 \ + VN h0, t1, t2 \ + VNC t0, t1, t1 \ + VO t1, t2, h0 + +// func poly1305vx(out *[16]byte, m *byte, mlen uint64, key *[32]key) +TEXT ·poly1305vx(SB), $0-32 + // This code processes up to 2 blocks (32 bytes) per iteration + // using the algorithm described in: + // NEON crypto, Daniel J. Bernstein & Peter Schwabe + // https://cryptojedi.org/papers/neoncrypto-20120320.pdf + LMG out+0(FP), R1, R4 // R1=out, R2=m, R3=mlen, R4=key + + // load MOD26, EX0, EX1 and EX2 + MOVD $·constants<>(SB), R5 + VLM (R5), MOD26, EX2 + + // setup r + VL (R4), T_0 + MOVD $·keyMask<>(SB), R6 + VL (R6), T_1 + VN T_0, T_1, T_0 + EXPAND(T_0, T_0, R_0, R_1, R_2, R_3, R_4) + + // setup r*5 + VLEIG $0, $5, T_0 + VLEIG $1, $5, T_0 + + // store r (for final block) + VMLOF T_0, R_1, R5SAVE_1 + VMLOF T_0, R_2, R5SAVE_2 + VMLOF T_0, R_3, R5SAVE_3 + VMLOF T_0, R_4, R5SAVE_4 + VLGVG $0, R_0, RSAVE_0 + VLGVG $0, R_1, RSAVE_1 + VLGVG $0, R_2, RSAVE_2 + VLGVG $0, R_3, RSAVE_3 + VLGVG $0, R_4, RSAVE_4 + + // skip r**2 calculation + CMPBLE R3, $16, skip + + // calculate r**2 + MULTIPLY(R_0, R_1, R_2, R_3, R_4, R_0, R_1, R_2, R_3, R_4, R5SAVE_1, R5SAVE_2, R5SAVE_3, R5SAVE_4, H_0, H_1, H_2, H_3, H_4) + REDUCE(H_0, H_1, H_2, H_3, H_4) + VLEIG $0, $5, T_0 + VLEIG $1, $5, T_0 + VMLOF T_0, H_1, R5_1 + VMLOF T_0, H_2, R5_2 + VMLOF T_0, H_3, R5_3 + VMLOF T_0, H_4, R5_4 + VLR H_0, R_0 + VLR H_1, R_1 + VLR H_2, R_2 + VLR H_3, R_3 + VLR H_4, R_4 + + // initialize h + VZERO H_0 + VZERO H_1 + VZERO H_2 + VZERO H_3 + VZERO H_4 + +loop: + CMPBLE R3, $32, b2 + VLM (R2), T_0, T_1 + SUB $32, R3 + MOVD $32(R2), R2 + EXPAND(T_0, T_1, F_0, F_1, F_2, F_3, F_4) + VLEIB $4, $1, F_4 + VLEIB $12, $1, F_4 + +multiply: + VAG H_0, F_0, F_0 + VAG H_1, F_1, F_1 + VAG H_2, F_2, F_2 + VAG H_3, F_3, F_3 + VAG H_4, F_4, F_4 + MULTIPLY(F_0, F_1, F_2, F_3, F_4, R_0, R_1, R_2, R_3, R_4, R5_1, R5_2, R5_3, R5_4, H_0, H_1, H_2, H_3, H_4) + REDUCE(H_0, H_1, H_2, H_3, H_4) + CMPBNE R3, $0, loop + +finish: + // sum vectors + VZERO T_0 + VSUMQG H_0, T_0, H_0 + VSUMQG H_1, T_0, H_1 + VSUMQG H_2, T_0, H_2 + VSUMQG H_3, T_0, H_3 + VSUMQG H_4, T_0, H_4 + + // h may be >= 2*(2**130-5) so we need to reduce it again + REDUCE(H_0, H_1, H_2, H_3, H_4) + + // carry h1->h4 + VESRLG $26, H_1, T_1 + VN MOD26, H_1, H_1 + VAQ T_1, H_2, H_2 + VESRLG $26, H_2, T_2 + VN MOD26, H_2, H_2 + VAQ T_2, H_3, H_3 + VESRLG $26, H_3, T_3 + VN MOD26, H_3, H_3 + VAQ T_3, H_4, H_4 + + // h is now < 2*(2**130-5) + // pack h into h1 (hi) and h0 (lo) + PACK(H_0, H_1, H_2, H_3, H_4) + + // if h > 2**130-5 then h -= 2**130-5 + MOD(H_0, H_1, T_0, T_1, T_2) + + // h += s + MOVD $·bswapMask<>(SB), R5 + VL (R5), T_1 + VL 16(R4), T_0 + VPERM T_0, T_0, T_1, T_0 // reverse bytes (to big) + VAQ T_0, H_0, H_0 + VPERM H_0, H_0, T_1, H_0 // reverse bytes (to little) + VST H_0, (R1) + + RET + +b2: + CMPBLE R3, $16, b1 + + // 2 blocks remaining + SUB $17, R3 + VL (R2), T_0 + VLL R3, 16(R2), T_1 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, T_1 + EXPAND(T_0, T_1, F_0, F_1, F_2, F_3, F_4) + CMPBNE R3, $16, 2(PC) + VLEIB $12, $1, F_4 + VLEIB $4, $1, F_4 + + // setup [r²,r] + VLVGG $1, RSAVE_0, R_0 + VLVGG $1, RSAVE_1, R_1 + VLVGG $1, RSAVE_2, R_2 + VLVGG $1, RSAVE_3, R_3 + VLVGG $1, RSAVE_4, R_4 + VPDI $0, R5_1, R5SAVE_1, R5_1 + VPDI $0, R5_2, R5SAVE_2, R5_2 + VPDI $0, R5_3, R5SAVE_3, R5_3 + VPDI $0, R5_4, R5SAVE_4, R5_4 + + MOVD $0, R3 + BR multiply + +skip: + VZERO H_0 + VZERO H_1 + VZERO H_2 + VZERO H_3 + VZERO H_4 + + CMPBEQ R3, $0, finish + +b1: + // 1 block remaining + SUB $1, R3 + VLL R3, (R2), T_0 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, T_0 + VZERO T_1 + EXPAND(T_0, T_1, F_0, F_1, F_2, F_3, F_4) + CMPBNE R3, $16, 2(PC) + VLEIB $4, $1, F_4 + VLEIG $1, $1, R_0 + VZERO R_1 + VZERO R_2 + VZERO R_3 + VZERO R_4 + VZERO R5_1 + VZERO R5_2 + VZERO R5_3 + VZERO R5_4 + + // setup [r, 1] + VLVGG $0, RSAVE_0, R_0 + VLVGG $0, RSAVE_1, R_1 + VLVGG $0, RSAVE_2, R_2 + VLVGG $0, RSAVE_3, R_3 + VLVGG $0, RSAVE_4, R_4 + VPDI $0, R5SAVE_1, R5_1, R5_1 + VPDI $0, R5SAVE_2, R5_2, R5_2 + VPDI $0, R5SAVE_3, R5_3, R5_3 + VPDI $0, R5SAVE_4, R5_4, R5_4 + + MOVD $0, R3 + BR multiply + +TEXT ·hasVectorFacility(SB), NOSPLIT, $24-1 + MOVD $x-24(SP), R1 + XC $24, 0(R1), 0(R1) // clear the storage + MOVD $2, R0 // R0 is the number of double words stored -1 + WORD $0xB2B01000 // STFLE 0(R1) + XOR R0, R0 // reset the value of R0 + MOVBZ z-8(SP), R1 + AND $0x40, R1 + BEQ novector + +vectorinstalled: + // check if the vector instruction has been enabled + VLEIB $0, $0xF, V16 + VLGVB $0, V16, R1 + CMPBNE R1, $0xF, novector + MOVB $1, ret+0(FP) // have vx + RET + +novector: + MOVB $0, ret+0(FP) // no vx + RET diff --git a/vendor/golang.org/x/crypto/poly1305/sum_vmsl_s390x.s b/vendor/golang.org/x/crypto/poly1305/sum_vmsl_s390x.s new file mode 100644 index 00000000..e548020b --- /dev/null +++ b/vendor/golang.org/x/crypto/poly1305/sum_vmsl_s390x.s @@ -0,0 +1,931 @@ +// Copyright 2018 The Go Authors. All rights reserved. +// Use of this source code is governed by a BSD-style +// license that can be found in the LICENSE file. + +// +build s390x,go1.11,!gccgo,!appengine + +#include "textflag.h" + +// Implementation of Poly1305 using the vector facility (vx) and the VMSL instruction. + +// constants +#define EX0 V1 +#define EX1 V2 +#define EX2 V3 + +// temporaries +#define T_0 V4 +#define T_1 V5 +#define T_2 V6 +#define T_3 V7 +#define T_4 V8 +#define T_5 V9 +#define T_6 V10 +#define T_7 V11 +#define T_8 V12 +#define T_9 V13 +#define T_10 V14 + +// r**2 & r**4 +#define R_0 V15 +#define R_1 V16 +#define R_2 V17 +#define R5_1 V18 +#define R5_2 V19 +// key (r) +#define RSAVE_0 R7 +#define RSAVE_1 R8 +#define RSAVE_2 R9 +#define R5SAVE_1 R10 +#define R5SAVE_2 R11 + +// message block +#define M0 V20 +#define M1 V21 +#define M2 V22 +#define M3 V23 +#define M4 V24 +#define M5 V25 + +// accumulator +#define H0_0 V26 +#define H1_0 V27 +#define H2_0 V28 +#define H0_1 V29 +#define H1_1 V30 +#define H2_1 V31 + +GLOBL ·keyMask<>(SB), RODATA, $16 +DATA ·keyMask<>+0(SB)/8, $0xffffff0ffcffff0f +DATA ·keyMask<>+8(SB)/8, $0xfcffff0ffcffff0f + +GLOBL ·bswapMask<>(SB), RODATA, $16 +DATA ·bswapMask<>+0(SB)/8, $0x0f0e0d0c0b0a0908 +DATA ·bswapMask<>+8(SB)/8, $0x0706050403020100 + +GLOBL ·constants<>(SB), RODATA, $48 +// EX0 +DATA ·constants<>+0(SB)/8, $0x18191a1b1c1d1e1f +DATA ·constants<>+8(SB)/8, $0x0000050403020100 +// EX1 +DATA ·constants<>+16(SB)/8, $0x18191a1b1c1d1e1f +DATA ·constants<>+24(SB)/8, $0x00000a0908070605 +// EX2 +DATA ·constants<>+32(SB)/8, $0x18191a1b1c1d1e1f +DATA ·constants<>+40(SB)/8, $0x0000000f0e0d0c0b + +GLOBL ·c<>(SB), RODATA, $48 +// EX0 +DATA ·c<>+0(SB)/8, $0x0000050403020100 +DATA ·c<>+8(SB)/8, $0x0000151413121110 +// EX1 +DATA ·c<>+16(SB)/8, $0x00000a0908070605 +DATA ·c<>+24(SB)/8, $0x00001a1918171615 +// EX2 +DATA ·c<>+32(SB)/8, $0x0000000f0e0d0c0b +DATA ·c<>+40(SB)/8, $0x0000001f1e1d1c1b + +GLOBL ·reduce<>(SB), RODATA, $32 +// 44 bit +DATA ·reduce<>+0(SB)/8, $0x0 +DATA ·reduce<>+8(SB)/8, $0xfffffffffff +// 42 bit +DATA ·reduce<>+16(SB)/8, $0x0 +DATA ·reduce<>+24(SB)/8, $0x3ffffffffff + +// h = (f*g) % (2**130-5) [partial reduction] +// uses T_0...T_9 temporary registers +// input: m02_0, m02_1, m02_2, m13_0, m13_1, m13_2, r_0, r_1, r_2, r5_1, r5_2, m4_0, m4_1, m4_2, m5_0, m5_1, m5_2 +// temp: t0, t1, t2, t3, t4, t5, t6, t7, t8, t9 +// output: m02_0, m02_1, m02_2, m13_0, m13_1, m13_2 +#define MULTIPLY(m02_0, m02_1, m02_2, m13_0, m13_1, m13_2, r_0, r_1, r_2, r5_1, r5_2, m4_0, m4_1, m4_2, m5_0, m5_1, m5_2, t0, t1, t2, t3, t4, t5, t6, t7, t8, t9) \ + \ // Eliminate the dependency for the last 2 VMSLs + VMSLG m02_0, r_2, m4_2, m4_2 \ + VMSLG m13_0, r_2, m5_2, m5_2 \ // 8 VMSLs pipelined + VMSLG m02_0, r_0, m4_0, m4_0 \ + VMSLG m02_1, r5_2, V0, T_0 \ + VMSLG m02_0, r_1, m4_1, m4_1 \ + VMSLG m02_1, r_0, V0, T_1 \ + VMSLG m02_1, r_1, V0, T_2 \ + VMSLG m02_2, r5_1, V0, T_3 \ + VMSLG m02_2, r5_2, V0, T_4 \ + VMSLG m13_0, r_0, m5_0, m5_0 \ + VMSLG m13_1, r5_2, V0, T_5 \ + VMSLG m13_0, r_1, m5_1, m5_1 \ + VMSLG m13_1, r_0, V0, T_6 \ + VMSLG m13_1, r_1, V0, T_7 \ + VMSLG m13_2, r5_1, V0, T_8 \ + VMSLG m13_2, r5_2, V0, T_9 \ + VMSLG m02_2, r_0, m4_2, m4_2 \ + VMSLG m13_2, r_0, m5_2, m5_2 \ + VAQ m4_0, T_0, m02_0 \ + VAQ m4_1, T_1, m02_1 \ + VAQ m5_0, T_5, m13_0 \ + VAQ m5_1, T_6, m13_1 \ + VAQ m02_0, T_3, m02_0 \ + VAQ m02_1, T_4, m02_1 \ + VAQ m13_0, T_8, m13_0 \ + VAQ m13_1, T_9, m13_1 \ + VAQ m4_2, T_2, m02_2 \ + VAQ m5_2, T_7, m13_2 \ + +// SQUARE uses three limbs of r and r_2*5 to output square of r +// uses T_1, T_5 and T_7 temporary registers +// input: r_0, r_1, r_2, r5_2 +// temp: TEMP0, TEMP1, TEMP2 +// output: p0, p1, p2 +#define SQUARE(r_0, r_1, r_2, r5_2, p0, p1, p2, TEMP0, TEMP1, TEMP2) \ + VMSLG r_0, r_0, p0, p0 \ + VMSLG r_1, r5_2, V0, TEMP0 \ + VMSLG r_2, r5_2, p1, p1 \ + VMSLG r_0, r_1, V0, TEMP1 \ + VMSLG r_1, r_1, p2, p2 \ + VMSLG r_0, r_2, V0, TEMP2 \ + VAQ TEMP0, p0, p0 \ + VAQ TEMP1, p1, p1 \ + VAQ TEMP2, p2, p2 \ + VAQ TEMP0, p0, p0 \ + VAQ TEMP1, p1, p1 \ + VAQ TEMP2, p2, p2 \ + +// carry h0->h1->h2->h0 || h3->h4->h5->h3 +// uses T_2, T_4, T_5, T_7, T_8, T_9 +// t6, t7, t8, t9, t10, t11 +// input: h0, h1, h2, h3, h4, h5 +// temp: t0, t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11 +// output: h0, h1, h2, h3, h4, h5 +#define REDUCE(h0, h1, h2, h3, h4, h5, t0, t1, t2, t3, t4, t5, t6, t7, t8, t9, t10, t11) \ + VLM (R12), t6, t7 \ // 44 and 42 bit clear mask + VLEIB $7, $0x28, t10 \ // 5 byte shift mask + VREPIB $4, t8 \ // 4 bit shift mask + VREPIB $2, t11 \ // 2 bit shift mask + VSRLB t10, h0, t0 \ // h0 byte shift + VSRLB t10, h1, t1 \ // h1 byte shift + VSRLB t10, h2, t2 \ // h2 byte shift + VSRLB t10, h3, t3 \ // h3 byte shift + VSRLB t10, h4, t4 \ // h4 byte shift + VSRLB t10, h5, t5 \ // h5 byte shift + VSRL t8, t0, t0 \ // h0 bit shift + VSRL t8, t1, t1 \ // h2 bit shift + VSRL t11, t2, t2 \ // h2 bit shift + VSRL t8, t3, t3 \ // h3 bit shift + VSRL t8, t4, t4 \ // h4 bit shift + VESLG $2, t2, t9 \ // h2 carry x5 + VSRL t11, t5, t5 \ // h5 bit shift + VN t6, h0, h0 \ // h0 clear carry + VAQ t2, t9, t2 \ // h2 carry x5 + VESLG $2, t5, t9 \ // h5 carry x5 + VN t6, h1, h1 \ // h1 clear carry + VN t7, h2, h2 \ // h2 clear carry + VAQ t5, t9, t5 \ // h5 carry x5 + VN t6, h3, h3 \ // h3 clear carry + VN t6, h4, h4 \ // h4 clear carry + VN t7, h5, h5 \ // h5 clear carry + VAQ t0, h1, h1 \ // h0->h1 + VAQ t3, h4, h4 \ // h3->h4 + VAQ t1, h2, h2 \ // h1->h2 + VAQ t4, h5, h5 \ // h4->h5 + VAQ t2, h0, h0 \ // h2->h0 + VAQ t5, h3, h3 \ // h5->h3 + VREPG $1, t6, t6 \ // 44 and 42 bit masks across both halves + VREPG $1, t7, t7 \ + VSLDB $8, h0, h0, h0 \ // set up [h0/1/2, h3/4/5] + VSLDB $8, h1, h1, h1 \ + VSLDB $8, h2, h2, h2 \ + VO h0, h3, h3 \ + VO h1, h4, h4 \ + VO h2, h5, h5 \ + VESRLG $44, h3, t0 \ // 44 bit shift right + VESRLG $44, h4, t1 \ + VESRLG $42, h5, t2 \ + VN t6, h3, h3 \ // clear carry bits + VN t6, h4, h4 \ + VN t7, h5, h5 \ + VESLG $2, t2, t9 \ // multiply carry by 5 + VAQ t9, t2, t2 \ + VAQ t0, h4, h4 \ + VAQ t1, h5, h5 \ + VAQ t2, h3, h3 \ + +// carry h0->h1->h2->h0 +// input: h0, h1, h2 +// temp: t0, t1, t2, t3, t4, t5, t6, t7, t8 +// output: h0, h1, h2 +#define REDUCE2(h0, h1, h2, t0, t1, t2, t3, t4, t5, t6, t7, t8) \ + VLEIB $7, $0x28, t3 \ // 5 byte shift mask + VREPIB $4, t4 \ // 4 bit shift mask + VREPIB $2, t7 \ // 2 bit shift mask + VGBM $0x003F, t5 \ // mask to clear carry bits + VSRLB t3, h0, t0 \ + VSRLB t3, h1, t1 \ + VSRLB t3, h2, t2 \ + VESRLG $4, t5, t5 \ // 44 bit clear mask + VSRL t4, t0, t0 \ + VSRL t4, t1, t1 \ + VSRL t7, t2, t2 \ + VESRLG $2, t5, t6 \ // 42 bit clear mask + VESLG $2, t2, t8 \ + VAQ t8, t2, t2 \ + VN t5, h0, h0 \ + VN t5, h1, h1 \ + VN t6, h2, h2 \ + VAQ t0, h1, h1 \ + VAQ t1, h2, h2 \ + VAQ t2, h0, h0 \ + VSRLB t3, h0, t0 \ + VSRLB t3, h1, t1 \ + VSRLB t3, h2, t2 \ + VSRL t4, t0, t0 \ + VSRL t4, t1, t1 \ + VSRL t7, t2, t2 \ + VN t5, h0, h0 \ + VN t5, h1, h1 \ + VESLG $2, t2, t8 \ + VN t6, h2, h2 \ + VAQ t0, h1, h1 \ + VAQ t8, t2, t2 \ + VAQ t1, h2, h2 \ + VAQ t2, h0, h0 \ + +// expands two message blocks into the lower halfs of the d registers +// moves the contents of the d registers into upper halfs +// input: in1, in2, d0, d1, d2, d3, d4, d5 +// temp: TEMP0, TEMP1, TEMP2, TEMP3 +// output: d0, d1, d2, d3, d4, d5 +#define EXPACC(in1, in2, d0, d1, d2, d3, d4, d5, TEMP0, TEMP1, TEMP2, TEMP3) \ + VGBM $0xff3f, TEMP0 \ + VGBM $0xff1f, TEMP1 \ + VESLG $4, d1, TEMP2 \ + VESLG $4, d4, TEMP3 \ + VESRLG $4, TEMP0, TEMP0 \ + VPERM in1, d0, EX0, d0 \ + VPERM in2, d3, EX0, d3 \ + VPERM in1, d2, EX2, d2 \ + VPERM in2, d5, EX2, d5 \ + VPERM in1, TEMP2, EX1, d1 \ + VPERM in2, TEMP3, EX1, d4 \ + VN TEMP0, d0, d0 \ + VN TEMP0, d3, d3 \ + VESRLG $4, d1, d1 \ + VESRLG $4, d4, d4 \ + VN TEMP1, d2, d2 \ + VN TEMP1, d5, d5 \ + VN TEMP0, d1, d1 \ + VN TEMP0, d4, d4 \ + +// expands one message block into the lower halfs of the d registers +// moves the contents of the d registers into upper halfs +// input: in, d0, d1, d2 +// temp: TEMP0, TEMP1, TEMP2 +// output: d0, d1, d2 +#define EXPACC2(in, d0, d1, d2, TEMP0, TEMP1, TEMP2) \ + VGBM $0xff3f, TEMP0 \ + VESLG $4, d1, TEMP2 \ + VGBM $0xff1f, TEMP1 \ + VPERM in, d0, EX0, d0 \ + VESRLG $4, TEMP0, TEMP0 \ + VPERM in, d2, EX2, d2 \ + VPERM in, TEMP2, EX1, d1 \ + VN TEMP0, d0, d0 \ + VN TEMP1, d2, d2 \ + VESRLG $4, d1, d1 \ + VN TEMP0, d1, d1 \ + +// pack h2:h0 into h1:h0 (no carry) +// input: h0, h1, h2 +// output: h0, h1, h2 +#define PACK(h0, h1, h2) \ + VMRLG h1, h2, h2 \ // copy h1 to upper half h2 + VESLG $44, h1, h1 \ // shift limb 1 44 bits, leaving 20 + VO h0, h1, h0 \ // combine h0 with 20 bits from limb 1 + VESRLG $20, h2, h1 \ // put top 24 bits of limb 1 into h1 + VLEIG $1, $0, h1 \ // clear h2 stuff from lower half of h1 + VO h0, h1, h0 \ // h0 now has 88 bits (limb 0 and 1) + VLEIG $0, $0, h2 \ // clear upper half of h2 + VESRLG $40, h2, h1 \ // h1 now has upper two bits of result + VLEIB $7, $88, h1 \ // for byte shift (11 bytes) + VSLB h1, h2, h2 \ // shift h2 11 bytes to the left + VO h0, h2, h0 \ // combine h0 with 20 bits from limb 1 + VLEIG $0, $0, h1 \ // clear upper half of h1 + +// if h > 2**130-5 then h -= 2**130-5 +// input: h0, h1 +// temp: t0, t1, t2 +// output: h0 +#define MOD(h0, h1, t0, t1, t2) \ + VZERO t0 \ + VLEIG $1, $5, t0 \ + VACCQ h0, t0, t1 \ + VAQ h0, t0, t0 \ + VONE t2 \ + VLEIG $1, $-4, t2 \ + VAQ t2, t1, t1 \ + VACCQ h1, t1, t1 \ + VONE t2 \ + VAQ t2, t1, t1 \ + VN h0, t1, t2 \ + VNC t0, t1, t1 \ + VO t1, t2, h0 \ + +// func poly1305vmsl(out *[16]byte, m *byte, mlen uint64, key *[32]key) +TEXT ·poly1305vmsl(SB), $0-32 + // This code processes 6 + up to 4 blocks (32 bytes) per iteration + // using the algorithm described in: + // NEON crypto, Daniel J. Bernstein & Peter Schwabe + // https://cryptojedi.org/papers/neoncrypto-20120320.pdf + // And as moddified for VMSL as described in + // Accelerating Poly1305 Cryptographic Message Authentication on the z14 + // O'Farrell et al, CASCON 2017, p48-55 + // https://ibm.ent.box.com/s/jf9gedj0e9d2vjctfyh186shaztavnht + + LMG out+0(FP), R1, R4 // R1=out, R2=m, R3=mlen, R4=key + VZERO V0 // c + + // load EX0, EX1 and EX2 + MOVD $·constants<>(SB), R5 + VLM (R5), EX0, EX2 // c + + // setup r + VL (R4), T_0 + MOVD $·keyMask<>(SB), R6 + VL (R6), T_1 + VN T_0, T_1, T_0 + VZERO T_2 // limbs for r + VZERO T_3 + VZERO T_4 + EXPACC2(T_0, T_2, T_3, T_4, T_1, T_5, T_7) + + // T_2, T_3, T_4: [0, r] + + // setup r*20 + VLEIG $0, $0, T_0 + VLEIG $1, $20, T_0 // T_0: [0, 20] + VZERO T_5 + VZERO T_6 + VMSLG T_0, T_3, T_5, T_5 + VMSLG T_0, T_4, T_6, T_6 + + // store r for final block in GR + VLGVG $1, T_2, RSAVE_0 // c + VLGVG $1, T_3, RSAVE_1 // c + VLGVG $1, T_4, RSAVE_2 // c + VLGVG $1, T_5, R5SAVE_1 // c + VLGVG $1, T_6, R5SAVE_2 // c + + // initialize h + VZERO H0_0 + VZERO H1_0 + VZERO H2_0 + VZERO H0_1 + VZERO H1_1 + VZERO H2_1 + + // initialize pointer for reduce constants + MOVD $·reduce<>(SB), R12 + + // calculate r**2 and 20*(r**2) + VZERO R_0 + VZERO R_1 + VZERO R_2 + SQUARE(T_2, T_3, T_4, T_6, R_0, R_1, R_2, T_1, T_5, T_7) + REDUCE2(R_0, R_1, R_2, M0, M1, M2, M3, M4, R5_1, R5_2, M5, T_1) + VZERO R5_1 + VZERO R5_2 + VMSLG T_0, R_1, R5_1, R5_1 + VMSLG T_0, R_2, R5_2, R5_2 + + // skip r**4 calculation if 3 blocks or less + CMPBLE R3, $48, b4 + + // calculate r**4 and 20*(r**4) + VZERO T_8 + VZERO T_9 + VZERO T_10 + SQUARE(R_0, R_1, R_2, R5_2, T_8, T_9, T_10, T_1, T_5, T_7) + REDUCE2(T_8, T_9, T_10, M0, M1, M2, M3, M4, T_2, T_3, M5, T_1) + VZERO T_2 + VZERO T_3 + VMSLG T_0, T_9, T_2, T_2 + VMSLG T_0, T_10, T_3, T_3 + + // put r**2 to the right and r**4 to the left of R_0, R_1, R_2 + VSLDB $8, T_8, T_8, T_8 + VSLDB $8, T_9, T_9, T_9 + VSLDB $8, T_10, T_10, T_10 + VSLDB $8, T_2, T_2, T_2 + VSLDB $8, T_3, T_3, T_3 + + VO T_8, R_0, R_0 + VO T_9, R_1, R_1 + VO T_10, R_2, R_2 + VO T_2, R5_1, R5_1 + VO T_3, R5_2, R5_2 + + CMPBLE R3, $80, load // less than or equal to 5 blocks in message + + // 6(or 5+1) blocks + SUB $81, R3 + VLM (R2), M0, M4 + VLL R3, 80(R2), M5 + ADD $1, R3 + MOVBZ $1, R0 + CMPBGE R3, $16, 2(PC) + VLVGB R3, R0, M5 + MOVD $96(R2), R2 + EXPACC(M0, M1, H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_0, T_1, T_2, T_3) + EXPACC(M2, M3, H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_0, T_1, T_2, T_3) + VLEIB $2, $1, H2_0 + VLEIB $2, $1, H2_1 + VLEIB $10, $1, H2_0 + VLEIB $10, $1, H2_1 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO T_4 + VZERO T_10 + EXPACC(M4, M5, M0, M1, M2, M3, T_4, T_10, T_0, T_1, T_2, T_3) + VLR T_4, M4 + VLEIB $10, $1, M2 + CMPBLT R3, $16, 2(PC) + VLEIB $10, $1, T_10 + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, T_10, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, M2, M3, M4, T_4, T_5, T_2, T_7, T_8, T_9) + VMRHG V0, H0_1, H0_0 + VMRHG V0, H1_1, H1_0 + VMRHG V0, H2_1, H2_0 + VMRLG V0, H0_1, H0_1 + VMRLG V0, H1_1, H1_1 + VMRLG V0, H2_1, H2_1 + + SUB $16, R3 + CMPBLE R3, $0, square + +load: + // load EX0, EX1 and EX2 + MOVD $·c<>(SB), R5 + VLM (R5), EX0, EX2 + +loop: + CMPBLE R3, $64, add // b4 // last 4 or less blocks left + + // next 4 full blocks + VLM (R2), M2, M5 + SUB $64, R3 + MOVD $64(R2), R2 + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, T_0, T_1, T_3, T_4, T_5, T_2, T_7, T_8, T_9) + + // expacc in-lined to create [m2, m3] limbs + VGBM $0x3f3f, T_0 // 44 bit clear mask + VGBM $0x1f1f, T_1 // 40 bit clear mask + VPERM M2, M3, EX0, T_3 + VESRLG $4, T_0, T_0 // 44 bit clear mask ready + VPERM M2, M3, EX1, T_4 + VPERM M2, M3, EX2, T_5 + VN T_0, T_3, T_3 + VESRLG $4, T_4, T_4 + VN T_1, T_5, T_5 + VN T_0, T_4, T_4 + VMRHG H0_1, T_3, H0_0 + VMRHG H1_1, T_4, H1_0 + VMRHG H2_1, T_5, H2_0 + VMRLG H0_1, T_3, H0_1 + VMRLG H1_1, T_4, H1_1 + VMRLG H2_1, T_5, H2_1 + VLEIB $10, $1, H2_0 + VLEIB $10, $1, H2_1 + VPERM M4, M5, EX0, T_3 + VPERM M4, M5, EX1, T_4 + VPERM M4, M5, EX2, T_5 + VN T_0, T_3, T_3 + VESRLG $4, T_4, T_4 + VN T_1, T_5, T_5 + VN T_0, T_4, T_4 + VMRHG V0, T_3, M0 + VMRHG V0, T_4, M1 + VMRHG V0, T_5, M2 + VMRLG V0, T_3, M3 + VMRLG V0, T_4, M4 + VMRLG V0, T_5, M5 + VLEIB $10, $1, M2 + VLEIB $10, $1, M5 + + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + CMPBNE R3, $0, loop + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, M3, M4, M5, T_4, T_5, T_2, T_7, T_8, T_9) + VMRHG V0, H0_1, H0_0 + VMRHG V0, H1_1, H1_0 + VMRHG V0, H2_1, H2_0 + VMRLG V0, H0_1, H0_1 + VMRLG V0, H1_1, H1_1 + VMRLG V0, H2_1, H2_1 + + // load EX0, EX1, EX2 + MOVD $·constants<>(SB), R5 + VLM (R5), EX0, EX2 + + // sum vectors + VAQ H0_0, H0_1, H0_0 + VAQ H1_0, H1_1, H1_0 + VAQ H2_0, H2_1, H2_0 + + // h may be >= 2*(2**130-5) so we need to reduce it again + // M0...M4 are used as temps here + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, T_9, T_10, H0_1, M5) + +next: // carry h1->h2 + VLEIB $7, $0x28, T_1 + VREPIB $4, T_2 + VGBM $0x003F, T_3 + VESRLG $4, T_3 + + // byte shift + VSRLB T_1, H1_0, T_4 + + // bit shift + VSRL T_2, T_4, T_4 + + // clear h1 carry bits + VN T_3, H1_0, H1_0 + + // add carry + VAQ T_4, H2_0, H2_0 + + // h is now < 2*(2**130-5) + // pack h into h1 (hi) and h0 (lo) + PACK(H0_0, H1_0, H2_0) + + // if h > 2**130-5 then h -= 2**130-5 + MOD(H0_0, H1_0, T_0, T_1, T_2) + + // h += s + MOVD $·bswapMask<>(SB), R5 + VL (R5), T_1 + VL 16(R4), T_0 + VPERM T_0, T_0, T_1, T_0 // reverse bytes (to big) + VAQ T_0, H0_0, H0_0 + VPERM H0_0, H0_0, T_1, H0_0 // reverse bytes (to little) + VST H0_0, (R1) + RET + +add: + // load EX0, EX1, EX2 + MOVD $·constants<>(SB), R5 + VLM (R5), EX0, EX2 + + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, M3, M4, M5, T_4, T_5, T_2, T_7, T_8, T_9) + VMRHG V0, H0_1, H0_0 + VMRHG V0, H1_1, H1_0 + VMRHG V0, H2_1, H2_0 + VMRLG V0, H0_1, H0_1 + VMRLG V0, H1_1, H1_1 + VMRLG V0, H2_1, H2_1 + CMPBLE R3, $64, b4 + +b4: + CMPBLE R3, $48, b3 // 3 blocks or less + + // 4(3+1) blocks remaining + SUB $49, R3 + VLM (R2), M0, M2 + VLL R3, 48(R2), M3 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, M3 + MOVD $64(R2), R2 + EXPACC(M0, M1, H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_0, T_1, T_2, T_3) + VLEIB $10, $1, H2_0 + VLEIB $10, $1, H2_1 + VZERO M0 + VZERO M1 + VZERO M4 + VZERO M5 + VZERO T_4 + VZERO T_10 + EXPACC(M2, M3, M0, M1, M4, M5, T_4, T_10, T_0, T_1, T_2, T_3) + VLR T_4, M2 + VLEIB $10, $1, M4 + CMPBNE R3, $16, 2(PC) + VLEIB $10, $1, T_10 + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M4, M5, M2, T_10, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, M3, M4, M5, T_4, T_5, T_2, T_7, T_8, T_9) + VMRHG V0, H0_1, H0_0 + VMRHG V0, H1_1, H1_0 + VMRHG V0, H2_1, H2_0 + VMRLG V0, H0_1, H0_1 + VMRLG V0, H1_1, H1_1 + VMRLG V0, H2_1, H2_1 + SUB $16, R3 + CMPBLE R3, $0, square // this condition must always hold true! + +b3: + CMPBLE R3, $32, b2 + + // 3 blocks remaining + + // setup [r²,r] + VSLDB $8, R_0, R_0, R_0 + VSLDB $8, R_1, R_1, R_1 + VSLDB $8, R_2, R_2, R_2 + VSLDB $8, R5_1, R5_1, R5_1 + VSLDB $8, R5_2, R5_2, R5_2 + + VLVGG $1, RSAVE_0, R_0 + VLVGG $1, RSAVE_1, R_1 + VLVGG $1, RSAVE_2, R_2 + VLVGG $1, R5SAVE_1, R5_1 + VLVGG $1, R5SAVE_2, R5_2 + + // setup [h0, h1] + VSLDB $8, H0_0, H0_0, H0_0 + VSLDB $8, H1_0, H1_0, H1_0 + VSLDB $8, H2_0, H2_0, H2_0 + VO H0_1, H0_0, H0_0 + VO H1_1, H1_0, H1_0 + VO H2_1, H2_0, H2_0 + VZERO H0_1 + VZERO H1_1 + VZERO H2_1 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + + // H*[r**2, r] + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, H0_1, H1_1, T_10, M5) + + SUB $33, R3 + VLM (R2), M0, M1 + VLL R3, 32(R2), M2 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, M2 + + // H += m0 + VZERO T_1 + VZERO T_2 + VZERO T_3 + EXPACC2(M0, T_1, T_2, T_3, T_4, T_5, T_6) + VLEIB $10, $1, T_3 + VAG H0_0, T_1, H0_0 + VAG H1_0, T_2, H1_0 + VAG H2_0, T_3, H2_0 + + VZERO M0 + VZERO M3 + VZERO M4 + VZERO M5 + VZERO T_10 + + // (H+m0)*r + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M3, M4, M5, V0, T_10, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M3, M4, M5, T_10, H0_1, H1_1, H2_1, T_9) + + // H += m1 + VZERO V0 + VZERO T_1 + VZERO T_2 + VZERO T_3 + EXPACC2(M1, T_1, T_2, T_3, T_4, T_5, T_6) + VLEIB $10, $1, T_3 + VAQ H0_0, T_1, H0_0 + VAQ H1_0, T_2, H1_0 + VAQ H2_0, T_3, H2_0 + REDUCE2(H0_0, H1_0, H2_0, M0, M3, M4, M5, T_9, H0_1, H1_1, H2_1, T_10) + + // [H, m2] * [r**2, r] + EXPACC2(M2, H0_0, H1_0, H2_0, T_1, T_2, T_3) + CMPBNE R3, $16, 2(PC) + VLEIB $10, $1, H2_0 + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, H0_1, H1_1, M5, T_10) + SUB $16, R3 + CMPBLE R3, $0, next // this condition must always hold true! + +b2: + CMPBLE R3, $16, b1 + + // 2 blocks remaining + + // setup [r²,r] + VSLDB $8, R_0, R_0, R_0 + VSLDB $8, R_1, R_1, R_1 + VSLDB $8, R_2, R_2, R_2 + VSLDB $8, R5_1, R5_1, R5_1 + VSLDB $8, R5_2, R5_2, R5_2 + + VLVGG $1, RSAVE_0, R_0 + VLVGG $1, RSAVE_1, R_1 + VLVGG $1, RSAVE_2, R_2 + VLVGG $1, R5SAVE_1, R5_1 + VLVGG $1, R5SAVE_2, R5_2 + + // setup [h0, h1] + VSLDB $8, H0_0, H0_0, H0_0 + VSLDB $8, H1_0, H1_0, H1_0 + VSLDB $8, H2_0, H2_0, H2_0 + VO H0_1, H0_0, H0_0 + VO H1_1, H1_0, H1_0 + VO H2_1, H2_0, H2_0 + VZERO H0_1 + VZERO H1_1 + VZERO H2_1 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + + // H*[r**2, r] + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, T_10, M0, M1, M2, M3, M4, T_4, T_5, T_2, T_7, T_8, T_9) + VMRHG V0, H0_1, H0_0 + VMRHG V0, H1_1, H1_0 + VMRHG V0, H2_1, H2_0 + VMRLG V0, H0_1, H0_1 + VMRLG V0, H1_1, H1_1 + VMRLG V0, H2_1, H2_1 + + // move h to the left and 0s at the right + VSLDB $8, H0_0, H0_0, H0_0 + VSLDB $8, H1_0, H1_0, H1_0 + VSLDB $8, H2_0, H2_0, H2_0 + + // get message blocks and append 1 to start + SUB $17, R3 + VL (R2), M0 + VLL R3, 16(R2), M1 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, M1 + VZERO T_6 + VZERO T_7 + VZERO T_8 + EXPACC2(M0, T_6, T_7, T_8, T_1, T_2, T_3) + EXPACC2(M1, T_6, T_7, T_8, T_1, T_2, T_3) + VLEIB $2, $1, T_8 + CMPBNE R3, $16, 2(PC) + VLEIB $10, $1, T_8 + + // add [m0, m1] to h + VAG H0_0, T_6, H0_0 + VAG H1_0, T_7, H1_0 + VAG H2_0, T_8, H2_0 + + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + VZERO T_10 + VZERO M0 + + // at this point R_0 .. R5_2 look like [r**2, r] + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M2, M3, M4, M5, T_10, M0, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M2, M3, M4, M5, T_9, H0_1, H1_1, H2_1, T_10) + SUB $16, R3, R3 + CMPBLE R3, $0, next + +b1: + CMPBLE R3, $0, next + + // 1 block remaining + + // setup [r²,r] + VSLDB $8, R_0, R_0, R_0 + VSLDB $8, R_1, R_1, R_1 + VSLDB $8, R_2, R_2, R_2 + VSLDB $8, R5_1, R5_1, R5_1 + VSLDB $8, R5_2, R5_2, R5_2 + + VLVGG $1, RSAVE_0, R_0 + VLVGG $1, RSAVE_1, R_1 + VLVGG $1, RSAVE_2, R_2 + VLVGG $1, R5SAVE_1, R5_1 + VLVGG $1, R5SAVE_2, R5_2 + + // setup [h0, h1] + VSLDB $8, H0_0, H0_0, H0_0 + VSLDB $8, H1_0, H1_0, H1_0 + VSLDB $8, H2_0, H2_0, H2_0 + VO H0_1, H0_0, H0_0 + VO H1_1, H1_0, H1_0 + VO H2_1, H2_0, H2_0 + VZERO H0_1 + VZERO H1_1 + VZERO H2_1 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + + // H*[r**2, r] + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, T_9, T_10, H0_1, M5) + + // set up [0, m0] limbs + SUB $1, R3 + VLL R3, (R2), M0 + ADD $1, R3 + MOVBZ $1, R0 + CMPBEQ R3, $16, 2(PC) + VLVGB R3, R0, M0 + VZERO T_1 + VZERO T_2 + VZERO T_3 + EXPACC2(M0, T_1, T_2, T_3, T_4, T_5, T_6)// limbs: [0, m] + CMPBNE R3, $16, 2(PC) + VLEIB $10, $1, T_3 + + // h+m0 + VAQ H0_0, T_1, H0_0 + VAQ H1_0, T_2, H1_0 + VAQ H2_0, T_3, H2_0 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, T_9, T_10, H0_1, M5) + + BR next + +square: + // setup [r²,r] + VSLDB $8, R_0, R_0, R_0 + VSLDB $8, R_1, R_1, R_1 + VSLDB $8, R_2, R_2, R_2 + VSLDB $8, R5_1, R5_1, R5_1 + VSLDB $8, R5_2, R5_2, R5_2 + + VLVGG $1, RSAVE_0, R_0 + VLVGG $1, RSAVE_1, R_1 + VLVGG $1, RSAVE_2, R_2 + VLVGG $1, R5SAVE_1, R5_1 + VLVGG $1, R5SAVE_2, R5_2 + + // setup [h0, h1] + VSLDB $8, H0_0, H0_0, H0_0 + VSLDB $8, H1_0, H1_0, H1_0 + VSLDB $8, H2_0, H2_0, H2_0 + VO H0_1, H0_0, H0_0 + VO H1_1, H1_0, H1_0 + VO H2_1, H2_0, H2_0 + VZERO H0_1 + VZERO H1_1 + VZERO H2_1 + + VZERO M0 + VZERO M1 + VZERO M2 + VZERO M3 + VZERO M4 + VZERO M5 + + // (h0*r**2) + (h1*r) + MULTIPLY(H0_0, H1_0, H2_0, H0_1, H1_1, H2_1, R_0, R_1, R_2, R5_1, R5_2, M0, M1, M2, M3, M4, M5, T_0, T_1, T_2, T_3, T_4, T_5, T_6, T_7, T_8, T_9) + REDUCE2(H0_0, H1_0, H2_0, M0, M1, M2, M3, M4, T_9, T_10, H0_1, M5) + BR next + +TEXT ·hasVMSLFacility(SB), NOSPLIT, $24-1 + MOVD $x-24(SP), R1 + XC $24, 0(R1), 0(R1) // clear the storage + MOVD $2, R0 // R0 is the number of double words stored -1 + WORD $0xB2B01000 // STFLE 0(R1) + XOR R0, R0 // reset the value of R0 + MOVBZ z-8(SP), R1 + AND $0x01, R1 + BEQ novmsl + +vectorinstalled: + // check if the vector instruction has been enabled + VLEIB $0, $0xF, V16 + VLGVB $0, V16, R1 + CMPBNE R1, $0xF, novmsl + MOVB $1, ret+0(FP) // have vx + RET + +novmsl: + MOVB $0, ret+0(FP) // no vx + RET |