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# Altivec instruction set, for PSIM, the PowerPC simulator.
# Copyright 2003-2021 Free Software Foundation, Inc.
# Contributed by Red Hat Inc; developed under contract from Motorola.
# Written by matthew green <mrg@redhat.com>.
# This file is part of GDB.
# This program 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 3 of the License, or
# (at your option) any later version.
# This program 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. If not, see <http://www.gnu.org/licenses/>. */
#
# Motorola AltiVec instructions.
#
:cache:av:::VS:VS:
:cache:av::vreg *:vS:VS:(cpu_registers(processor)->altivec.vr + VS)
:cache:av::unsigned32:VS_BITMASK:VS:(1 << VS)
:cache:av:::VA:VA:
:cache:av::vreg *:vA:VA:(cpu_registers(processor)->altivec.vr + VA)
:cache:av::unsigned32:VA_BITMASK:VA:(1 << VA)
:cache:av:::VB:VB:
:cache:av::vreg *:vB:VB:(cpu_registers(processor)->altivec.vr + VB)
:cache:av::unsigned32:VB_BITMASK:VB:(1 << VB)
:cache:av:::VC:VC:
:cache:av::vreg *:vC:VC:(cpu_registers(processor)->altivec.vr + VC)
:cache:av::unsigned32:VC_BITMASK:VC:(1 << VC)
# Flags for model.h
::model-macro:::
#define PPC_INSN_INT_VR(OUT_MASK, IN_MASK, OUT_VMASK, IN_VMASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_int_vr(MY_INDEX, cpu_model(processor), OUT_MASK, IN_MASK, OUT_VMASK, IN_VMASK); \
} while (0)
#define PPC_INSN_VR(OUT_VMASK, IN_VMASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_vr(MY_INDEX, cpu_model(processor), OUT_VMASK, IN_VMASK); \
} while (0)
#define PPC_INSN_VR_CR(OUT_VMASK, IN_VMASK, CR_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_vr_cr(MY_INDEX, cpu_model(processor), OUT_VMASK, IN_VMASK, CR_MASK); \
} while (0)
#define PPC_INSN_VR_VSCR(OUT_VMASK, IN_VMASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_vr_vscr(MY_INDEX, cpu_model(processor), OUT_VMASK, IN_VMASK); \
} while (0)
#define PPC_INSN_FROM_VSCR(VR_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_from_vscr(MY_INDEX, cpu_model(processor), VR_MASK); \
} while (0)
#define PPC_INSN_TO_VSCR(VR_MASK) \
do { \
if (CURRENT_MODEL_ISSUE > 0) \
ppc_insn_to_vscr(MY_INDEX, cpu_model(processor), VR_MASK); \
} while (0)
# Trace waiting for AltiVec registers to become available
void::model-static::model_trace_altivec_busy_p:model_data *model_ptr, unsigned32 vr_busy
int i;
if (vr_busy) {
vr_busy &= model_ptr->vr_busy;
for(i = 0; i < 32; i++) {
if (((1 << i) & vr_busy) != 0) {
TRACE(trace_model, ("Waiting for register v%d.\n", i));
}
}
}
if (model_ptr->vscr_busy)
TRACE(trace_model, ("Waiting for VSCR\n"));
# Trace making AltiVec registers busy
void::model-static::model_trace_altivec_make_busy:model_data *model_ptr, unsigned32 vr_mask, unsigned32 cr_mask
int i;
if (vr_mask) {
for(i = 0; i < 32; i++) {
if (((1 << i) & vr_mask) != 0) {
TRACE(trace_model, ("Register v%d is now busy.\n", i));
}
}
}
if (cr_mask) {
for(i = 0; i < 8; i++) {
if (((1 << i) & cr_mask) != 0) {
TRACE(trace_model, ("Register cr%d is now busy.\n", i));
}
}
}
# Schedule an AltiVec instruction that takes integer input registers and produces output registers
void::model-function::ppc_insn_int_vr:itable_index index, model_data *model_ptr, const unsigned32 out_mask, const unsigned32 in_mask, const unsigned32 out_vmask, const unsigned32 in_vmask
const unsigned32 int_mask = out_mask | in_mask;
const unsigned32 vr_mask = out_vmask | in_vmask;
model_busy *busy_ptr;
if ((model_ptr->int_busy & int_mask) != 0 || (model_ptr->vr_busy & vr_mask)) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->int_busy & int_mask) != 0 || (model_ptr->vr_busy & vr_mask)) {
if (WITH_TRACE && ppc_trace[trace_model]) {
model_trace_busy_p(model_ptr, int_mask, 0, 0, PPC_NO_SPR);
model_trace_altivec_busy_p(model_ptr, vr_mask);
}
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
model_ptr->int_busy |= out_mask;
busy_ptr->int_busy |= out_mask;
model_ptr->vr_busy |= out_vmask;
busy_ptr->vr_busy |= out_vmask;
if (out_mask)
busy_ptr->nr_writebacks = (PPC_ONE_BIT_SET_P(out_vmask)) ? 1 : 2;
if (out_vmask)
busy_ptr->nr_writebacks += (PPC_ONE_BIT_SET_P(out_vmask)) ? 1 : 2;
if (WITH_TRACE && ppc_trace[trace_model]) {
model_trace_make_busy(model_ptr, out_mask, 0, 0);
model_trace_altivec_make_busy(model_ptr, vr_mask, 0);
}
# Schedule an AltiVec instruction that takes vector input registers and produces vector output registers
void::model-function::ppc_insn_vr:itable_index index, model_data *model_ptr, const unsigned32 out_vmask, const unsigned32 in_vmask
const unsigned32 vr_mask = out_vmask | in_vmask;
model_busy *busy_ptr;
if (model_ptr->vr_busy & vr_mask) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while (model_ptr->vr_busy & vr_mask) {
if (WITH_TRACE && ppc_trace[trace_model]) {
model_trace_altivec_busy_p(model_ptr, vr_mask);
}
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
model_ptr->vr_busy |= out_vmask;
busy_ptr->vr_busy |= out_vmask;
if (out_vmask)
busy_ptr->nr_writebacks = (PPC_ONE_BIT_SET_P(out_vmask)) ? 1 : 2;
if (WITH_TRACE && ppc_trace[trace_model]) {
model_trace_altivec_make_busy(model_ptr, vr_mask, 0);
}
# Schedule an AltiVec instruction that takes vector input registers and produces vector output registers, touches CR
void::model-function::ppc_insn_vr_cr:itable_index index, model_data *model_ptr, const unsigned32 out_vmask, const unsigned32 in_vmask, const unsigned32 cr_mask
const unsigned32 vr_mask = out_vmask | in_vmask;
model_busy *busy_ptr;
if ((model_ptr->vr_busy & vr_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->vr_busy & vr_mask) || (model_ptr->cr_fpscr_busy & cr_mask)) {
if (WITH_TRACE && ppc_trace[trace_model]) {
model_trace_busy_p(model_ptr, 0, 0, cr_mask, PPC_NO_SPR);
model_trace_altivec_busy_p(model_ptr, vr_mask);
}
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
model_ptr->cr_fpscr_busy |= cr_mask;
busy_ptr->cr_fpscr_busy |= cr_mask;
model_ptr->vr_busy |= out_vmask;
busy_ptr->vr_busy |= out_vmask;
if (out_vmask)
busy_ptr->nr_writebacks = (PPC_ONE_BIT_SET_P(out_vmask)) ? 1 : 2;
if (cr_mask)
busy_ptr->nr_writebacks++;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_make_busy(model_ptr, vr_mask, cr_mask);
# Schedule an AltiVec instruction that takes vector input registers and produces vector output registers, touches VSCR
void::model-function::ppc_insn_vr_vscr:itable_index index, model_data *model_ptr, const unsigned32 out_vmask, const unsigned32 in_vmask
const unsigned32 vr_mask = out_vmask | in_vmask;
model_busy *busy_ptr;
if ((model_ptr->vr_busy & vr_mask) != 0 || model_ptr->vscr_busy != 0) {
model_new_cycle(model_ptr); /* don't count first dependency as a stall */
while ((model_ptr->vr_busy & vr_mask) != 0 || model_ptr->vscr_busy != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_busy_p(model_ptr, vr_mask);
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
model_ptr->vr_busy |= out_vmask;
busy_ptr->vr_busy |= out_vmask;
model_ptr->vscr_busy = 1;
busy_ptr->vscr_busy = 1;
if (out_vmask)
busy_ptr->nr_writebacks = 1 + (PPC_ONE_BIT_SET_P(out_vmask)) ? 1 : 2;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_make_busy(model_ptr, vr_mask, 0);
# Schedule an MFVSCR instruction that VSCR input register and produces an AltiVec output register
void::model-function::ppc_insn_from_vscr:itable_index index, model_data *model_ptr, const unsigned32 vr_mask
model_busy *busy_ptr;
while ((model_ptr->vr_busy & vr_mask) != 0 || model_ptr->vscr_busy != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_busy_p(model_ptr, vr_mask);
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
model_ptr->cr_fpscr_busy |= vr_mask;
busy_ptr->cr_fpscr_busy |= vr_mask;
if (vr_mask)
busy_ptr->nr_writebacks = 1;
model_ptr->vr_busy |= vr_mask;
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_make_busy(model_ptr, vr_mask, 0);
# Schedule an MTVSCR instruction that one AltiVec input register and produces a vscr output register
void::model-function::ppc_insn_to_vscr:itable_index index, model_data *model_ptr, const unsigned32 vr_mask
model_busy *busy_ptr;
while ((model_ptr->vr_busy & vr_mask) != 0 || model_ptr->vscr_busy != 0) {
if (WITH_TRACE && ppc_trace[trace_model])
model_trace_altivec_busy_p(model_ptr, vr_mask);
model_ptr->nr_stalls_data++;
model_new_cycle(model_ptr);
}
busy_ptr = model_wait_for_unit(index, model_ptr, &model_ptr->timing[index]);
busy_ptr ->vscr_busy = 1;
model_ptr->vscr_busy = 1;
busy_ptr->nr_writebacks = 1;
TRACE(trace_model,("Making VSCR busy.\n"));
# The follow are AltiVec saturate operations
signed8::model-function::altivec_signed_saturate_8:signed16 val, int *sat
signed8 rv;
if (val > 127) {
rv = 127;
*sat = 1;
} else if (val < -128) {
rv = -128;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
signed16::model-function::altivec_signed_saturate_16:signed32 val, int *sat
signed16 rv;
if (val > 32767) {
rv = 32767;
*sat = 1;
} else if (val < -32768) {
rv = -32768;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
signed32::model-function::altivec_signed_saturate_32:signed64 val, int *sat
signed32 rv;
if (val > 2147483647) {
rv = 2147483647;
*sat = 1;
} else if (val < -2147483648LL) {
rv = -2147483648LL;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
unsigned8::model-function::altivec_unsigned_saturate_8:signed16 val, int *sat
unsigned8 rv;
if (val > 255) {
rv = 255;
*sat = 1;
} else if (val < 0) {
rv = 0;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
unsigned16::model-function::altivec_unsigned_saturate_16:signed32 val, int *sat
unsigned16 rv;
if (val > 65535) {
rv = 65535;
*sat = 1;
} else if (val < 0) {
rv = 0;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
unsigned32::model-function::altivec_unsigned_saturate_32:signed64 val, int *sat
unsigned32 rv;
if (val > 4294967295LL) {
rv = 4294967295LL;
*sat = 1;
} else if (val < 0) {
rv = 0;
*sat = 1;
} else {
rv = val;
*sat = 0;
}
return rv;
#
# Load instructions, 6-14 ... 6-22.
#
0.31,6.VS,11.RA,16.RB,21.7,31.0:X:av:lvebx %VD, %RA, %RB:Load Vector Element Byte Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
eb = EA & 0xf;
(*vS).b[AV_BINDEX(eb)] = MEM(unsigned, EA, 1);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.39,31.0:X:av:lvehx %VD, %RA, %RB:Load Vector Element Half Word Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~1;
eb = EA & 0xf;
(*vS).h[AV_HINDEX(eb/2)] = MEM(unsigned, EA, 2);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.71,31.0:X:av:lvewx %VD, %RA, %RB:Load Vector Element Word Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~3;
eb = EA & 0xf;
(*vS).w[eb/4] = MEM(unsigned, EA, 4);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.6,31.0:X:av:lvsl %VD, %RA, %RB:Load Vector for Shift Left
unsigned_word b;
unsigned_word addr;
int i, j;
if (RA_is_0) b = 0;
else b = *rA;
addr = b + *rB;
j = addr & 0xf;
for (i = 0; i < 16; i++)
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
(*vS).b[AV_BINDEX(i)] = j++;
else
(*vS).b[AV_BINDEX(15 - i)] = j++;
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.38,31.0:X:av:lvsr %VD, %RA, %RB:Load Vector for Shift Right
unsigned_word b;
unsigned_word addr;
int i, j;
if (RA_is_0) b = 0;
else b = *rA;
addr = b + *rB;
j = 0x10 - (addr & 0xf);
for (i = 0; i < 16; i++)
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
(*vS).b[AV_BINDEX(i)] = j++;
else
(*vS).b[AV_BINDEX(15 - i)] = j++;
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.103,31.0:X:av:lvx %VD, %RA, %RB:Load Vector Indexed
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG) {
(*vS).w[0] = MEM(unsigned, EA + 0, 4);
(*vS).w[1] = MEM(unsigned, EA + 4, 4);
(*vS).w[2] = MEM(unsigned, EA + 8, 4);
(*vS).w[3] = MEM(unsigned, EA + 12, 4);
} else {
(*vS).w[0] = MEM(unsigned, EA + 12, 4);
(*vS).w[1] = MEM(unsigned, EA + 8, 4);
(*vS).w[2] = MEM(unsigned, EA + 4, 4);
(*vS).w[3] = MEM(unsigned, EA + 0, 4);
}
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.359,31.0:X:av:lvxl %VD, %RA, %RB:Load Vector Indexed LRU
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG) {
(*vS).w[0] = MEM(unsigned, EA + 0, 4);
(*vS).w[1] = MEM(unsigned, EA + 4, 4);
(*vS).w[2] = MEM(unsigned, EA + 8, 4);
(*vS).w[3] = MEM(unsigned, EA + 12, 4);
} else {
(*vS).w[0] = MEM(unsigned, EA + 12, 4);
(*vS).w[1] = MEM(unsigned, EA + 8, 4);
(*vS).w[2] = MEM(unsigned, EA + 4, 4);
(*vS).w[3] = MEM(unsigned, EA + 0, 4);
}
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
#
# Move to/from VSCR instructions, 6-23 & 6-24.
#
0.4,6.VS,11.0,16.0,21.1540:VX:av:mfvscr %VS:Move from Vector Status and Control Register
(*vS).w[0] = 0;
(*vS).w[1] = 0;
(*vS).w[2] = 0;
(*vS).w[3] = VSCR;
PPC_INSN_FROM_VSCR(VS_BITMASK);
0.4,6.0,11.0,16.VB,21.1604:VX:av:mtvscr %VB:Move to Vector Status and Control Register
VSCR = (*vB).w[3];
PPC_INSN_TO_VSCR(VB_BITMASK);
#
# Store instructions, 6-25 ... 6-29.
#
0.31,6.VS,11.RA,16.RB,21.135,31.0:X:av:stvebx %VD, %RA, %RB:Store Vector Element Byte Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = b + *rB;
eb = EA & 0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
STORE(EA, 1, (*vS).b[eb]);
else
STORE(EA, 1, (*vS).b[15-eb]);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.167,31.0:X:av:stvehx %VD, %RA, %RB:Store Vector Element Half Word Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~1;
eb = EA & 0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
STORE(EA, 2, (*vS).h[eb/2]);
else
STORE(EA, 2, (*vS).h[7-eb]);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.199,31.0:X:av:stvewx %VD, %RA, %RB:Store Vector Element Word Indexed
unsigned_word b;
unsigned_word EA;
unsigned_word eb;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~3;
eb = EA & 0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
STORE(EA, 4, (*vS).w[eb/4]);
else
STORE(EA, 4, (*vS).w[3-(eb/4)]);
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.231,31.0:X:av:stvx %VD, %RA, %RB:Store Vector Indexed
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG) {
STORE(EA + 0, 4, (*vS).w[0]);
STORE(EA + 4, 4, (*vS).w[1]);
STORE(EA + 8, 4, (*vS).w[2]);
STORE(EA + 12, 4, (*vS).w[3]);
} else {
STORE(EA + 12, 4, (*vS).w[0]);
STORE(EA + 8, 4, (*vS).w[1]);
STORE(EA + 4, 4, (*vS).w[2]);
STORE(EA + 0, 4, (*vS).w[3]);
}
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
0.31,6.VS,11.RA,16.RB,21.487,31.0:X:av:stvxl %VD, %RA, %RB:Store Vector Indexed LRU
unsigned_word b;
unsigned_word EA;
if (RA_is_0) b = 0;
else b = *rA;
EA = (b + *rB) & ~0xf;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG) {
STORE(EA + 0, 4, (*vS).w[0]);
STORE(EA + 4, 4, (*vS).w[1]);
STORE(EA + 8, 4, (*vS).w[2]);
STORE(EA + 12, 4, (*vS).w[3]);
} else {
STORE(EA + 12, 4, (*vS).w[0]);
STORE(EA + 8, 4, (*vS).w[1]);
STORE(EA + 4, 4, (*vS).w[2]);
STORE(EA + 0, 4, (*vS).w[3]);
}
PPC_INSN_INT_VR(0, RA_BITMASK | RB_BITMASK, VS_BITMASK, 0);
#
# Vector Add instructions, 6-30 ... 6-40.
#
0.4,6.VS,11.VA,16.VB,21.384:VX:av:vaddcuw %VD, %VA, %VB:Vector Add Carryout Unsigned Word
unsigned64 temp;
int i;
for (i = 0; i < 4; i++) {
temp = (unsigned64)(*vA).w[i] + (unsigned64)(*vB).w[i];
(*vS).w[i] = temp >> 32;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.10:VX:av:vaddfp %VD, %VA, %VB:Vector Add Floating Point
int i;
unsigned32 f;
sim_fpu a, b, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_add (&d, &a, &b);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.768:VX:av:vaddsbs %VD, %VA, %VB:Vector Add Signed Byte Saturate
int i, sat, tempsat;
signed16 temp;
for (i = 0; i < 16; i++) {
temp = (signed16)(signed8)(*vA).b[i] + (signed16)(signed8)(*vB).b[i];
(*vS).b[i] = altivec_signed_saturate_8(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.832:VX:av:vaddshs %VD, %VA, %VB:Vector Add Signed Half Word Saturate
int i, sat, tempsat;
signed32 temp, a, b;
for (i = 0; i < 8; i++) {
a = (signed32)(signed16)(*vA).h[i];
b = (signed32)(signed16)(*vB).h[i];
temp = a + b;
(*vS).h[i] = altivec_signed_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.896:VX:av:vaddsws %VD, %VA, %VB:Vector Add Signed Word Saturate
int i, sat, tempsat;
signed64 temp;
for (i = 0; i < 4; i++) {
temp = (signed64)(signed32)(*vA).w[i] + (signed64)(signed32)(*vB).w[i];
(*vS).w[i] = altivec_signed_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.0:VX:av:vaddubm %VD, %VA, %VB:Vector Add Unsigned Byte Modulo
int i;
for (i = 0; i < 16; i++)
(*vS).b[i] = ((*vA).b[i] + (*vB).b[i]) & 0xff;
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.512:VX:av:vaddubs %VD, %VA, %VB:Vector Add Unsigned Byte Saturate
int i, sat, tempsat;
signed16 temp;
sat = 0;
for (i = 0; i < 16; i++) {
temp = (signed16)(unsigned8)(*vA).b[i] + (signed16)(unsigned8)(*vB).b[i];
(*vS).b[i] = altivec_unsigned_saturate_8(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.64:VX:av:vadduhm %VD, %VA, %VB:Vector Add Unsigned Half Word Modulo
int i;
for (i = 0; i < 8; i++)
(*vS).h[i] = ((*vA).h[i] + (*vB).h[i]) & 0xffff;
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.576:VX:av:vadduhs %VD, %VA, %VB:Vector Add Unsigned Half Word Saturate
int i, sat, tempsat;
signed32 temp;
for (i = 0; i < 8; i++) {
temp = (signed32)(unsigned16)(*vA).h[i] + (signed32)(unsigned16)(*vB).h[i];
(*vS).h[i] = altivec_unsigned_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.128:VX:av:vadduwm %VD, %VA, %VB:Vector Add Unsigned Word Modulo
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = (*vA).w[i] + (*vB).w[i];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.640:VX:av:vadduws %VD, %VA, %VB:Vector Add Unsigned Word Saturate
int i, sat, tempsat;
signed64 temp;
for (i = 0; i < 4; i++) {
temp = (signed64)(unsigned32)(*vA).w[i] + (signed64)(unsigned32)(*vB).w[i];
(*vS).w[i] = altivec_unsigned_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector AND instructions, 6-41, 6-42
#
0.4,6.VS,11.VA,16.VB,21.1028:VX:av:vand %VD, %VA, %VB:Vector Logical AND
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = (*vA).w[i] & (*vB).w[i];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1092:VX:av:vandc %VD, %VA, %VB:Vector Logical AND with Compliment
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = (*vA).w[i] & ~((*vB).w[i]);
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Average instructions, 6-43, 6-48
#
0.4,6.VS,11.VA,16.VB,21.1282:VX:av:vavgsb %VD, %VA, %VB:Vector Average Signed Byte
int i;
signed16 temp, a, b;
for (i = 0; i < 16; i++) {
a = (signed16)(signed8)(*vA).b[i];
b = (signed16)(signed8)(*vB).b[i];
temp = a + b + 1;
(*vS).b[i] = (temp >> 1) & 0xff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1346:VX:av:vavgsh %VD, %VA, %VB:Vector Average Signed Half Word
int i;
signed32 temp, a, b;
for (i = 0; i < 8; i++) {
a = (signed32)(signed16)(*vA).h[i];
b = (signed32)(signed16)(*vB).h[i];
temp = a + b + 1;
(*vS).h[i] = (temp >> 1) & 0xffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1410:VX:av:vavgsw %VD, %VA, %VB:Vector Average Signed Word
int i;
signed64 temp, a, b;
for (i = 0; i < 4; i++) {
a = (signed64)(signed32)(*vA).w[i];
b = (signed64)(signed32)(*vB).w[i];
temp = a + b + 1;
(*vS).w[i] = (temp >> 1) & 0xffffffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1026:VX:av:vavgub %VD, %VA, %VB:Vector Average Unsigned Byte
int i;
unsigned16 temp, a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
temp = a + b + 1;
(*vS).b[i] = (temp >> 1) & 0xff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1090:VX:av:vavguh %VD, %VA, %VB:Vector Average Unsigned Half Word
int i;
unsigned32 temp, a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
temp = a + b + 1;
(*vS).h[i] = (temp >> 1) & 0xffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1154:VX:av:vavguw %VD, %VA, %VB:Vector Average Unsigned Word
int i;
unsigned64 temp, a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
temp = a + b + 1;
(*vS).w[i] = (temp >> 1) & 0xffffffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Fixed Point Convert instructions, 6-49, 6-50
#
0.4,6.VS,11.UIMM,16.VB,21.842:VX:av:vcfsx %VD, %VB, %UIMM:Vector Convert From Signed Fixed-Point Word
int i;
unsigned32 f;
sim_fpu b, div, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_u32to (&div, 2 << UIMM, sim_fpu_round_default);
sim_fpu_div (&d, &b, &div);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.UIMM,16.VB,21.778:VX:av:vcfux %VD, %VA, %UIMM:Vector Convert From Unsigned Fixed-Point Word
int i;
unsigned32 f;
sim_fpu b, d, div;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_u32to (&div, 2 << UIMM, sim_fpu_round_default);
sim_fpu_div (&d, &b, &div);
sim_fpu_to32u (&f, &d, sim_fpu_round_default);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
#
# Vector Compare instructions, 6-51 ... 6-64
#
0.4,6.VS,11.VA,16.VB,21.RC,22.966:VXR:av:vcmpbpfpx %VD, %VA, %VB:Vector Compare Bounds Floating Point
int i, le, ge;
sim_fpu a, b, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
le = sim_fpu_is_le(&a, &b);
ge = sim_fpu_is_ge(&a, &b);
(*vS).w[i] = (le ? 0 : 1 << 31) | (ge ? 0 : 1 << 30);
}
if (RC)
ALTIVEC_SET_CR6(vS, 0);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.198:VXR:av:vcmpeqfpx %VD, %VA, %VB:Vector Compare Equal-to-Floating Point
int i;
sim_fpu a, b;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
if (sim_fpu_is_eq(&a, &b))
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.6:VXR:av:vcmpequbx %VD, %VA, %VB:Vector Compare Equal-to Unsigned Byte
int i;
for (i = 0; i < 16; i++)
if ((*vA).b[i] == (*vB).b[i])
(*vS).b[i] = 0xff;
else
(*vS).b[i] = 0;
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.70:VXR:av:vcmpequhx %VD, %VA, %VB:Vector Compare Equal-to Unsigned Half Word
int i;
for (i = 0; i < 8; i++)
if ((*vA).h[i] == (*vB).h[i])
(*vS).h[i] = 0xffff;
else
(*vS).h[i] = 0;
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.134:VXR:av:vcmpequwx %VD, %VA, %VB:Vector Compare Equal-to Unsigned Word
int i;
for (i = 0; i < 4; i++)
if ((*vA).w[i] == (*vB).w[i])
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.454:VXR:av:vcmpgefpx %VD, %VA, %VB:Vector Compare Greater-Than-or-Equal-to Floating Point
int i;
sim_fpu a, b;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
if (sim_fpu_is_ge(&a, &b))
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.710:VXR:av:vcmpgtfpx %VD, %VA, %VB:Vector Compare Greater-Than Floating Point
int i;
sim_fpu a, b;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
if (sim_fpu_is_gt(&a, &b))
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.774:VXR:av:vcmpgtsbx %VD, %VA, %VB:Vector Compare Greater-Than Signed Byte
int i;
signed8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a > b)
(*vS).b[i] = 0xff;
else
(*vS).b[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.838:VXR:av:vcmpgtshx %VD, %VA, %VB:Vector Compare Greater-Than Signed Half Word
int i;
signed16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a > b)
(*vS).h[i] = 0xffff;
else
(*vS).h[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.902:VXR:av:vcmpgtswx %VD, %VA, %VB:Vector Compare Greater-Than Signed Word
int i;
signed32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a > b)
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.518:VXR:av:vcmpgtubx %VD, %VA, %VB:Vector Compare Greater-Than Unsigned Byte
int i;
unsigned8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a > b)
(*vS).b[i] = 0xff;
else
(*vS).b[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.582:VXR:av:vcmpgtuhx %VD, %VA, %VB:Vector Compare Greater-Than Unsigned Half Word
int i;
unsigned16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a > b)
(*vS).h[i] = 0xffff;
else
(*vS).h[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
0.4,6.VS,11.VA,16.VB,21.RC,22.646:VXR:av:vcmpgtuwx %VD, %VA, %VB:Vector Compare Greater-Than Unsigned Word
int i;
unsigned32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a > b)
(*vS).w[i] = 0xffffffff;
else
(*vS).w[i] = 0;
}
if (RC)
ALTIVEC_SET_CR6(vS, 1);
PPC_INSN_VR_CR(VS_BITMASK, VA_BITMASK | VB_BITMASK, RC ? 0x000000f0 : 0);
#
# Vector Convert instructions, 6-65, 6-66.
#
0.4,6.VS,11.UIMM,16.VB,21.970:VX:av:vctsxs %VD, %VB, %UIMM:Vector Convert to Signed Fixed-Point Word Saturate
int i, sat, tempsat;
signed64 temp;
sim_fpu a, b, m;
sat = 0;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_u32to (&m, 2 << UIMM, sim_fpu_round_default);
sim_fpu_mul (&a, &b, &m);
sim_fpu_to64i (&temp, &a, sim_fpu_round_default);
(*vS).w[i] = altivec_signed_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.UIMM,16.VB,21.906:VX:av:vctuxs %VD, %VB, %UIMM:Vector Convert to Unsigned Fixed-Point Word Saturate
int i, sat, tempsat;
signed64 temp;
sim_fpu a, b, m;
sat = 0;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_u32to (&m, 2 << UIMM, sim_fpu_round_default);
sim_fpu_mul (&a, &b, &m);
sim_fpu_to64u (&temp, &a, sim_fpu_round_default);
(*vS).w[i] = altivec_unsigned_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VB_BITMASK);
#
# Vector Estimate instructions, 6-67 ... 6-70.
#
0.4,6.VS,11.0,16.VB,21.394:VX:av:vexptefp %VD, %VB:Vector 2 Raised to the Exponent Estimate Floating Point
int i;
unsigned32 f;
signed32 bi;
sim_fpu b, d;
for (i = 0; i < 4; i++) {
/*HACK!*/
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_to32i (&bi, &b, sim_fpu_round_default);
bi = 2 ^ bi;
sim_fpu_32to (&d, bi);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR_VSCR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.0,16.VB,21.458:VX:av:vlogefp %VD, %VB:Vector Log2 Estimate Floating Point
int i;
unsigned32 c, u, f;
sim_fpu b, cfpu, d;
for (i = 0; i < 4; i++) {
/*HACK!*/
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_to32u (&u, &b, sim_fpu_round_default);
for (c = 0; (u /= 2) > 1; c++)
;
sim_fpu_32to (&cfpu, c);
sim_fpu_add (&d, &b, &cfpu);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR_VSCR(VS_BITMASK, VB_BITMASK);
#
# Vector Multiply Add instruction, 6-71
#
0.4,6.VS,11.VA,16.VB,21.VC,26.46:VAX:av:vmaddfp %VD, %VA, %VB, %VC:Vector Multiply Add Floating Point
int i;
unsigned32 f;
sim_fpu a, b, c, d, e;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_32to (&c, (*vC).w[i]);
sim_fpu_mul (&e, &a, &c);
sim_fpu_add (&d, &e, &b);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Maximum instructions, 6-72 ... 6-78.
#
0.4,6.VS,11.VA,16.VB,21.1034:VX:av:vmaxfp %VD, %VA, %VB:Vector Maximum Floating Point
int i;
unsigned32 f;
sim_fpu a, b, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_max (&d, &a, &b);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.258:VX:av:vmaxsb %VD, %VA, %VB:Vector Maximum Signed Byte
int i;
signed8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a > b)
(*vS).b[i] = a;
else
(*vS).b[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.322:VX:av:vmaxsh %VD, %VA, %VB:Vector Maximum Signed Half Word
int i;
signed16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a > b)
(*vS).h[i] = a;
else
(*vS).h[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.386:VX:av:vmaxsw %VD, %VA, %VB:Vector Maximum Signed Word
int i;
signed32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a > b)
(*vS).w[i] = a;
else
(*vS).w[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.2:VX:av:vmaxub %VD, %VA, %VB:Vector Maximum Unsigned Byte
int i;
unsigned8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a > b)
(*vS).b[i] = a;
else
(*vS).b[i] = b;
};
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.66:VX:av:vmaxus %VD, %VA, %VB:Vector Maximum Unsigned Half Word
int i;
unsigned16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a > b)
(*vS).h[i] = a;
else
(*vS).h[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.130:VX:av:vmaxuw %VD, %VA, %VB:Vector Maximum Unsigned Word
int i;
unsigned32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a > b)
(*vS).w[i] = a;
else
(*vS).w[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Multiple High instructions, 6-79, 6-80.
#
0.4,6.VS,11.VA,16.VB,21.VC,26.32:VAX:av:vmhaddshs %VD, %VA, %VB, %VC:Vector Multiple High and Add Signed Half Word Saturate
int i, sat, tempsat;
signed16 a, b;
signed32 prod, temp, c;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
c = (signed32)(signed16)(*vC).h[i];
prod = (signed32)a * (signed32)b;
temp = (prod >> 15) + c;
(*vS).h[i] = altivec_signed_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.33:VAX:av:vmhraddshs %VD, %VA, %VB, %VC:Vector Multiple High Round and Add Signed Half Word Saturate
int i, sat, tempsat;
signed16 a, b;
signed32 prod, temp, c;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
c = (signed32)(signed16)(*vC).h[i];
prod = (signed32)a * (signed32)b;
prod += 0x4000;
temp = (prod >> 15) + c;
(*vS).h[i] = altivec_signed_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Minimum instructions, 6-81 ... 6-87
#
0.4,6.VS,11.VA,16.VB,21.1098:VX:av:vminfp %VD, %VA, %VB:Vector Minimum Floating Point
int i;
unsigned32 f;
sim_fpu a, b, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_min (&d, &a, &b);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.770:VX:av:vminsb %VD, %VA, %VB:Vector Minimum Signed Byte
int i;
signed8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a < b)
(*vS).b[i] = a;
else
(*vS).b[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.834:VX:av:vminsh %VD, %VA, %VB:Vector Minimum Signed Half Word
int i;
signed16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a < b)
(*vS).h[i] = a;
else
(*vS).h[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.898:VX:av:vminsw %VD, %VA, %VB:Vector Minimum Signed Word
int i;
signed32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a < b)
(*vS).w[i] = a;
else
(*vS).w[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.514:VX:av:vminub %VD, %VA, %VB:Vector Minimum Unsigned Byte
int i;
unsigned8 a, b;
for (i = 0; i < 16; i++) {
a = (*vA).b[i];
b = (*vB).b[i];
if (a < b)
(*vS).b[i] = a;
else
(*vS).b[i] = b;
};
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.578:VX:av:vminuh %VD, %VA, %VB:Vector Minimum Unsigned Half Word
int i;
unsigned16 a, b;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
if (a < b)
(*vS).h[i] = a;
else
(*vS).h[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.642:VX:av:vminuw %VD, %VA, %VB:Vector Minimum Unsigned Word
int i;
unsigned32 a, b;
for (i = 0; i < 4; i++) {
a = (*vA).w[i];
b = (*vB).w[i];
if (a < b)
(*vS).w[i] = a;
else
(*vS).w[i] = b;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Multiply Low instruction, 6-88
#
0.4,6.VS,11.VA,16.VB,21.VC,26.34:VAX:av:vmladduhm %VD, %VA, %VB, %VC:Vector Multiply Low and Add Unsigned Half Word Modulo
int i;
unsigned16 a, b, c;
unsigned32 prod;
for (i = 0; i < 8; i++) {
a = (*vA).h[i];
b = (*vB).h[i];
c = (*vC).h[i];
prod = (unsigned32)a * (unsigned32)b;
(*vS).h[i] = (prod + c) & 0xffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Merge instructions, 6-89 ... 6-94
#
0.4,6.VS,11.VA,16.VB,21.12:VX:av:vmrghb %VD, %VA, %VB:Vector Merge High Byte
int i;
for (i = 0; i < 16; i += 2) {
(*vS).b[AV_BINDEX(i)] = (*vA).b[AV_BINDEX(i/2)];
(*vS).b[AV_BINDEX(i+1)] = (*vB).b[AV_BINDEX(i/2)];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.76:VX:av:vmrghh %VD, %VA, %VB:Vector Merge High Half Word
int i;
for (i = 0; i < 8; i += 2) {
(*vS).h[AV_HINDEX(i)] = (*vA).h[AV_HINDEX(i/2)];
(*vS).h[AV_HINDEX(i+1)] = (*vB).h[AV_HINDEX(i/2)];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.140:VX:av:vmrghw %VD, %VA, %VB:Vector Merge High Word
int i;
for (i = 0; i < 4; i += 2) {
(*vS).w[i] = (*vA).w[i/2];
(*vS).w[i+1] = (*vB).w[i/2];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.268:VX:av:vmrglb %VD, %VA, %VB:Vector Merge Low Byte
int i;
for (i = 0; i < 16; i += 2) {
(*vS).b[AV_BINDEX(i)] = (*vA).b[AV_BINDEX((i/2) + 8)];
(*vS).b[AV_BINDEX(i+1)] = (*vB).b[AV_BINDEX((i/2) + 8)];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.332:VX:av:vmrglh %VD, %VA, %VB:Vector Merge Low Half Word
int i;
for (i = 0; i < 8; i += 2) {
(*vS).h[AV_HINDEX(i)] = (*vA).h[AV_HINDEX((i/2) + 4)];
(*vS).h[AV_HINDEX(i+1)] = (*vB).h[AV_HINDEX((i/2) + 4)];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.396:VX:av:vmrglw %VD, %VA, %VB:Vector Merge Low Word
int i;
for (i = 0; i < 4; i += 2) {
(*vS).w[i] = (*vA).w[(i/2) + 2];
(*vS).w[i+1] = (*vB).w[(i/2) + 2];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Multiply Sum instructions, 6-95 ... 6-100
#
0.4,6.VS,11.VA,16.VB,21.VC,26.37:VAX:av:vmsummbm %VD, %VA, %VB, %VC:Vector Multiply Sum Mixed-Sign Byte Modulo
int i, j;
signed32 temp;
signed16 prod, a;
unsigned16 b;
for (i = 0; i < 4; i++) {
temp = (*vC).w[i];
for (j = 0; j < 4; j++) {
a = (signed16)(signed8)(*vA).b[i*4+j];
b = (*vB).b[i*4+j];
prod = a * b;
temp += (signed32)prod;
}
(*vS).w[i] = temp;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.40:VAX:av:vmsumshm %VD, %VA, %VB, %VC:Vector Multiply Sum Signed Half Word Modulo
int i, j;
signed32 temp, prod, a, b;
for (i = 0; i < 4; i++) {
temp = (*vC).w[i];
for (j = 0; j < 2; j++) {
a = (signed32)(signed16)(*vA).h[i*2+j];
b = (signed32)(signed16)(*vB).h[i*2+j];
prod = a * b;
temp += prod;
}
(*vS).w[i] = temp;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.41:VAX:av:vmsumshs %VD, %VA, %VB, %VC:Vector Multiply Sum Signed Half Word Saturate
int i, j, sat, tempsat;
signed64 temp;
signed32 prod, a, b;
sat = 0;
for (i = 0; i < 4; i++) {
temp = (signed64)(signed32)(*vC).w[i];
for (j = 0; j < 2; j++) {
a = (signed32)(signed16)(*vA).h[i*2+j];
b = (signed32)(signed16)(*vB).h[i*2+j];
prod = a * b;
temp += (signed64)prod;
}
(*vS).w[i] = altivec_signed_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.36:VAX:av:vmsumubm %VD, %VA, %VB, %VC:Vector Multiply Sum Unsigned Byte Modulo
int i, j;
unsigned32 temp;
unsigned16 prod, a, b;
for (i = 0; i < 4; i++) {
temp = (*vC).w[i];
for (j = 0; j < 4; j++) {
a = (*vA).b[i*4+j];
b = (*vB).b[i*4+j];
prod = a * b;
temp += prod;
}
(*vS).w[i] = temp;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.38:VAX:av:vmsumuhm %VD, %VA, %VB, %VC:Vector Multiply Sum Unsigned Half Word Modulo
int i, j;
unsigned32 temp, prod, a, b;
for (i = 0; i < 4; i++) {
temp = (*vC).w[i];
for (j = 0; j < 2; j++) {
a = (*vA).h[i*2+j];
b = (*vB).h[i*2+j];
prod = a * b;
temp += prod;
}
(*vS).w[i] = temp;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
0.4,6.VS,11.VA,16.VB,21.VC,26.39:VAX:av:vmsumuhs %VD, %VA, %VB, %VC:Vector Multiply Sum Unsigned Half Word Saturate
int i, j, sat, tempsat;
unsigned32 temp, prod, a, b;
sat = 0;
for (i = 0; i < 4; i++) {
temp = (*vC).w[i];
for (j = 0; j < 2; j++) {
a = (*vA).h[i*2+j];
b = (*vB).h[i*2+j];
prod = a * b;
temp += prod;
}
(*vS).w[i] = altivec_unsigned_saturate_32(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Multiply Even/Odd instructions, 6-101 ... 6-108
#
0.4,6.VS,11.VA,16.VB,21.776:VX:av:vmulesb %VD, %VA, %VB:Vector Multiply Even Signed Byte
int i;
signed8 a, b;
signed16 prod;
for (i = 0; i < 8; i++) {
a = (*vA).b[AV_BINDEX(i*2)];
b = (*vB).b[AV_BINDEX(i*2)];
prod = a * b;
(*vS).h[AV_HINDEX(i)] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.840:VX:av:vmulesh %VD, %VA, %VB:Vector Multiply Even Signed Half Word
int i;
signed16 a, b;
signed32 prod;
for (i = 0; i < 4; i++) {
a = (*vA).h[AV_HINDEX(i*2)];
b = (*vB).h[AV_HINDEX(i*2)];
prod = a * b;
(*vS).w[i] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.520:VX:av:vmuleub %VD, %VA, %VB:Vector Multiply Even Unsigned Byte
int i;
unsigned8 a, b;
unsigned16 prod;
for (i = 0; i < 8; i++) {
a = (*vA).b[AV_BINDEX(i*2)];
b = (*vB).b[AV_BINDEX(i*2)];
prod = a * b;
(*vS).h[AV_HINDEX(i)] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.584:VX:av:vmuleuh %VD, %VA, %VB:Vector Multiply Even Unsigned Half Word
int i;
unsigned16 a, b;
unsigned32 prod;
for (i = 0; i < 4; i++) {
a = (*vA).h[AV_HINDEX(i*2)];
b = (*vB).h[AV_HINDEX(i*2)];
prod = a * b;
(*vS).w[i] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.264:VX:av:vmulosb %VD, %VA, %VB:Vector Multiply Odd Signed Byte
int i;
signed8 a, b;
signed16 prod;
for (i = 0; i < 8; i++) {
a = (*vA).b[AV_BINDEX((i*2)+1)];
b = (*vB).b[AV_BINDEX((i*2)+1)];
prod = a * b;
(*vS).h[AV_HINDEX(i)] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.328:VX:av:vmulosh %VD, %VA, %VB:Vector Multiply Odd Signed Half Word
int i;
signed16 a, b;
signed32 prod;
for (i = 0; i < 4; i++) {
a = (*vA).h[AV_HINDEX((i*2)+1)];
b = (*vB).h[AV_HINDEX((i*2)+1)];
prod = a * b;
(*vS).w[i] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.8:VX:av:vmuloub %VD, %VA, %VB:Vector Multiply Odd Unsigned Byte
int i;
unsigned8 a, b;
unsigned16 prod;
for (i = 0; i < 8; i++) {
a = (*vA).b[AV_BINDEX((i*2)+1)];
b = (*vB).b[AV_BINDEX((i*2)+1)];
prod = a * b;
(*vS).h[AV_HINDEX(i)] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.72:VX:av:vmulouh %VD, %VA, %VB:Vector Multiply Odd Unsigned Half Word
int i;
unsigned16 a, b;
unsigned32 prod;
for (i = 0; i < 4; i++) {
a = (*vA).h[AV_HINDEX((i*2)+1)];
b = (*vB).h[AV_HINDEX((i*2)+1)];
prod = a * b;
(*vS).w[i] = prod;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Negative Multiply-Subtract instruction, 6-109
#
0.4,6.VS,11.VA,16.VB,21.VC,26.47:VX:av:vnmsubfp %VD, %VA, %VB, %VC:Vector Negative Multiply-Subtract Floating Point
int i;
unsigned32 f;
sim_fpu a, b, c, d, i1, i2;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&a, (*vA).w[i]);
sim_fpu_32to (&b, (*vB).w[i]);
sim_fpu_32to (&c, (*vC).w[i]);
sim_fpu_mul (&i1, &a, &c);
sim_fpu_sub (&i2, &i1, &b);
sim_fpu_neg (&d, &i2);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Logical OR instructions, 6-110, 6-111, 6-177
#
0.4,6.VS,11.VA,16.VB,21.1284:VX:av:vnor %VD, %VA, %VB:Vector Logical NOR
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = ~((*vA).w[i] | (*vB).w[i]);
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1156:VX:av:vor %VD, %VA, %VB:Vector Logical OR
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = (*vA).w[i] | (*vB).w[i];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1220:VX:av:vxor %VD, %VA, %VB:Vector Logical XOR
int i;
for (i = 0; i < 4; i++)
(*vS).w[i] = (*vA).w[i] ^ (*vB).w[i];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Permute instruction, 6-112
#
0.4,6.VS,11.VA,16.VB,21.VC,26.43:VX:av:vperm %VD, %VA, %VB, %VC:Vector Permute
int i, who;
/* The permutation vector might have us read into the source vectors
back at positions before the iteration index, so we must latch the
sources to prevent early-clobbering in case the destination vector
is the same as one of them. */
vreg myvA = (*vA), myvB = (*vB);
for (i = 0; i < 16; i++) {
who = (*vC).b[AV_BINDEX(i)] & 0x1f;
if (who & 0x10)
(*vS).b[AV_BINDEX(i)] = myvB.b[AV_BINDEX(who & 0xf)];
else
(*vS).b[AV_BINDEX(i)] = myvA.b[AV_BINDEX(who & 0xf)];
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Pack instructions, 6-113 ... 6-121
#
0.4,6.VS,11.VA,16.VB,21.782:VX:av:vpkpx %VD, %VA, %VB:Vector Pack Pixel32
int i;
for (i = 0; i < 4; i++) {
(*vS).h[AV_HINDEX(i+4)] = ((((*vB).w[i]) >> 9) & 0xfc00)
| ((((*vB).w[i]) >> 6) & 0x03e0)
| ((((*vB).w[i]) >> 3) & 0x001f);
(*vS).h[AV_HINDEX(i)] = ((((*vA).w[i]) >> 9) & 0xfc00)
| ((((*vA).w[i]) >> 6) & 0x03e0)
| ((((*vA).w[i]) >> 3) & 0x001f);
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.398:VX:av:vpkshss %VD, %VA, %VB:Vector Pack Signed Half Word Signed Saturate
int i, sat, tempsat;
signed16 temp;
sat = 0;
for (i = 0; i < 16; i++) {
if (i < 8)
temp = (*vA).h[AV_HINDEX(i)];
else
temp = (*vB).h[AV_HINDEX(i-8)];
(*vS).b[AV_BINDEX(i)] = altivec_signed_saturate_8(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.270:VX:av:vpkshus %VD, %VA, %VB:Vector Pack Signed Half Word Unsigned Saturate
int i, sat, tempsat;
signed16 temp;
sat = 0;
for (i = 0; i < 16; i++) {
if (i < 8)
temp = (*vA).h[AV_HINDEX(i)];
else
temp = (*vB).h[AV_HINDEX(i-8)];
(*vS).b[AV_BINDEX(i)] = altivec_unsigned_saturate_8(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.462:VX:av:vpkswss %VD, %VA, %VB:Vector Pack Signed Word Signed Saturate
int i, sat, tempsat;
signed32 temp;
sat = 0;
for (i = 0; i < 8; i++) {
if (i < 4)
temp = (*vA).w[i];
else
temp = (*vB).w[i-4];
(*vS).h[AV_HINDEX(i)] = altivec_signed_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.334:VX:av:vpkswus %VD, %VA, %VB:Vector Pack Signed Word Unsigned Saturate
int i, sat, tempsat;
signed32 temp;
sat = 0;
for (i = 0; i < 8; i++) {
if (i < 4)
temp = (*vA).w[i];
else
temp = (*vB).w[i-4];
(*vS).h[AV_HINDEX(i)] = altivec_unsigned_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.14:VX:av:vpkuhum %VD, %VA, %VB:Vector Pack Unsigned Half Word Unsigned Modulo
int i;
for (i = 0; i < 16; i++)
if (i < 8)
(*vS).b[AV_BINDEX(i)] = (*vA).h[AV_HINDEX(i)];
else
(*vS).b[AV_BINDEX(i)] = (*vB).h[AV_HINDEX(i-8)];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.142:VX:av:vpkuhus %VD, %VA, %VB:Vector Pack Unsigned Half Word Unsigned Saturate
int i, sat, tempsat;
signed16 temp;
sat = 0;
for (i = 0; i < 16; i++) {
if (i < 8)
temp = (*vA).h[AV_HINDEX(i)];
else
temp = (*vB).h[AV_HINDEX(i-8)];
/* force positive in signed16, ok as we'll toss the bit away anyway */
temp &= ~0x8000;
(*vS).b[AV_BINDEX(i)] = altivec_unsigned_saturate_8(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.78:VX:av:vpkuwum %VD, %VA, %VB:Vector Pack Unsigned Word Unsigned Modulo
int i;
for (i = 0; i < 8; i++)
if (i < 8)
(*vS).h[AV_HINDEX(i)] = (*vA).w[i];
else
(*vS).h[AV_HINDEX(i)] = (*vB).w[i-8];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.206:VX:av:vpkuwus %VD, %VA, %VB:Vector Pack Unsigned Word Unsigned Saturate
int i, sat, tempsat;
signed32 temp;
sat = 0;
for (i = 0; i < 8; i++) {
if (i < 4)
temp = (*vA).w[i];
else
temp = (*vB).w[i-4];
/* force positive in signed32, ok as we'll toss the bit away anyway */
temp &= ~0x80000000;
(*vS).h[AV_HINDEX(i)] = altivec_unsigned_saturate_16(temp, &tempsat);
sat |= tempsat;
}
ALTIVEC_SET_SAT(sat);
PPC_INSN_VR_VSCR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Reciprocal instructions, 6-122, 6-123, 6-131
#
0.4,6.VS,11.0,16.VB,21.266:VX:av:vrefp %VD, %VB:Vector Reciprocal Estimate Floating Point
int i;
unsigned32 f;
sim_fpu op, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_div (&d, &sim_fpu_one, &op);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.0,16.VB,21.330:VX:av:vrsqrtefp %VD, %VB:Vector Reciprocal Square Root Estimate Floating Point
int i;
unsigned32 f;
sim_fpu op, i1, one, d;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_sqrt (&i1, &op);
sim_fpu_div (&d, &sim_fpu_one, &i1);
sim_fpu_to32 (&f, &d);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
#
# Vector Round instructions, 6-124 ... 6-127
#
0.4,6.VS,11.0,16.VB,21.714:VX:av:vrfim %VD, %VB:Vector Round to Floating-Point Integer towards Minus Infinity
int i;
unsigned32 f;
sim_fpu op;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_round_32(&op, sim_fpu_round_down, sim_fpu_denorm_default);
sim_fpu_to32 (&f, &op);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.0,16.VB,21.522:VX:av:vrfin %VD, %VB:Vector Round to Floating-Point Integer Nearest
int i;
unsigned32 f;
sim_fpu op;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_round_32(&op, sim_fpu_round_near, sim_fpu_denorm_default);
sim_fpu_to32 (&f, &op);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.0,16.VB,21.650:VX:av:vrfip %VD, %VB:Vector Round to Floating-Point Integer towards Plus Infinity
int i;
unsigned32 f;
sim_fpu op;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_round_32(&op, sim_fpu_round_up, sim_fpu_denorm_default);
sim_fpu_to32 (&f, &op);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.0,16.VB,21.586:VX:av:vrfiz %VD, %VB:Vector Round to Floating-Point Integer towards Zero
int i;
unsigned32 f;
sim_fpu op;
for (i = 0; i < 4; i++) {
sim_fpu_32to (&op, (*vB).w[i]);
sim_fpu_round_32(&op, sim_fpu_round_zero, sim_fpu_denorm_default);
sim_fpu_to32 (&f, &op);
(*vS).w[i] = f;
}
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
#
# Vector Rotate Left instructions, 6-128 ... 6-130
#
0.4,6.VS,11.VA,16.VB,21.4:VX:av:vrlb %VD, %VA, %VB:Vector Rotate Left Integer Byte
int i;
unsigned16 temp;
for (i = 0; i < 16; i++) {
temp = (unsigned16)(*vA).b[i] << (((*vB).b[i]) & 7);
(*vS).b[i] = (temp & 0xff) | ((temp >> 8) & 0xff);
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.68:VX:av:vrlh %VD, %VA, %VB:Vector Rotate Left Integer Half Word
int i;
unsigned32 temp;
for (i = 0; i < 8; i++) {
temp = (unsigned32)(*vA).h[i] << (((*vB).h[i]) & 0xf);
(*vS).h[i] = (temp & 0xffff) | ((temp >> 16) & 0xffff);
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.132:VX:av:vrlw %VD, %VA, %VB:Vector Rotate Left Integer Word
int i;
unsigned64 temp;
for (i = 0; i < 4; i++) {
temp = (unsigned64)(*vA).w[i] << (((*vB).w[i]) & 0x1f);
(*vS).w[i] = (temp & 0xffffffff) | ((temp >> 32) & 0xffffffff);
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Conditional Select instruction, 6-133
#
0.4,6.VS,11.VA,16.VB,21.VC,26.42:VAX:av:vsel %VD, %VA, %VB, %VC:Vector Conditional Select
int i;
unsigned32 c;
for (i = 0; i < 4; i++) {
c = (*vC).w[i];
(*vS).w[i] = ((*vB).w[i] & c) | ((*vA).w[i] & ~c);
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK | VC_BITMASK);
#
# Vector Shift Left instructions, 6-134 ... 6-139
#
0.4,6.VS,11.VA,16.VB,21.452:VX:av:vsl %VD, %VA, %VB:Vector Shift Left
int sh, i, j, carry, new_carry;
sh = (*vB).b[0] & 7; /* don't bother checking everything */
carry = 0;
for (j = 3; j >= 0; j--) {
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
i = j;
else
i = (j + 2) % 4;
new_carry = (*vA).w[i] >> (32 - sh);
(*vS).w[i] = ((*vA).w[i] << sh) | carry;
carry = new_carry;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.260:VX:av:vslb %VD, %VA, %VB:Vector Shift Left Integer Byte
int i, sh;
for (i = 0; i < 16; i++) {
sh = ((*vB).b[i]) & 7;
(*vS).b[i] = (*vA).b[i] << sh;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.0,22.SH,26.44:VX:av:vsldol %VD, %VA, %VB:Vector Shift Left Double by Octet Immediate
int i, j;
for (j = 0, i = SH; i < 16; i++)
(*vS).b[j++] = (*vA).b[i];
for (i = 0; i < SH; i++)
(*vS).b[j++] = (*vB).b[i];
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.324:VX:av:vslh %VD, %VA, %VB:Vector Shift Left Half Word
int i, sh;
for (i = 0; i < 8; i++) {
sh = ((*vB).h[i]) & 0xf;
(*vS).h[i] = (*vA).h[i] << sh;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1036:VX:av:vslo %VD, %VA, %VB:Vector Shift Left by Octet
int i, sh;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
sh = ((*vB).b[AV_BINDEX(15)] >> 3) & 0xf;
else
sh = ((*vB).b[AV_BINDEX(0)] >> 3) & 0xf;
for (i = 0; i < 16; i++) {
if (15 - i > sh)
(*vS).b[AV_BINDEX(i)] = (*vA).b[AV_BINDEX(i + sh)];
else
(*vS).b[AV_BINDEX(i)] = 0;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.388:VX:av:vslw %VD, %VA, %VB:Vector Shift Left Integer Word
int i, sh;
for (i = 0; i < 4; i++) {
sh = ((*vB).w[i]) & 0x1f;
(*vS).w[i] = (*vA).w[i] << sh;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
#
# Vector Splat instructions, 6-140 ... 6-145
#
0.4,6.VS,11.UIMM,16.VB,21.524:VX:av:vspltb %VD, %VB, %UIMM:Vector Splat Byte
int i;
unsigned8 b;
b = (*vB).b[AV_BINDEX(UIMM & 0xf)];
for (i = 0; i < 16; i++)
(*vS).b[i] = b;
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.UIMM,16.VB,21.588:VX:av:vsplth %VD, %VB, %UIMM:Vector Splat Half Word
int i;
unsigned16 h;
h = (*vB).h[AV_HINDEX(UIMM & 0x7)];
for (i = 0; i < 8; i++)
(*vS).h[i] = h;
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
0.4,6.VS,11.SIMM,16.0,21.780:VX:av:vspltisb %VD, %SIMM:Vector Splat Immediate Signed Byte
int i;
signed8 b = SIMM;
/* manual 5-bit signed extension */
if (b & 0x10)
b -= 0x20;
for (i = 0; i < 16; i++)
(*vS).b[i] = b;
PPC_INSN_VR(VS_BITMASK, 0);
0.4,6.VS,11.SIMM,16.0,21.844:VX:av:vspltish %VD, %SIMM:Vector Splat Immediate Signed Half Word
int i;
signed16 h = SIMM;
/* manual 5-bit signed extension */
if (h & 0x10)
h -= 0x20;
for (i = 0; i < 8; i++)
(*vS).h[i] = h;
PPC_INSN_VR(VS_BITMASK, 0);
0.4,6.VS,11.SIMM,16.0,21.908:VX:av:vspltisw %VD, %SIMM:Vector Splat Immediate Signed Word
int i;
signed32 w = SIMM;
/* manual 5-bit signed extension */
if (w & 0x10)
w -= 0x20;
for (i = 0; i < 4; i++)
(*vS).w[i] = w;
PPC_INSN_VR(VS_BITMASK, 0);
0.4,6.VS,11.UIMM,16.VB,21.652:VX:av:vspltw %VD, %VB, %UIMM:Vector Splat Word
int i;
unsigned32 w;
w = (*vB).w[UIMM & 0x3];
for (i = 0; i < 4; i++)
(*vS).w[i] = w;
PPC_INSN_VR(VS_BITMASK, VB_BITMASK);
#
# Vector Shift Right instructions, 6-146 ... 6-154
#
0.4,6.VS,11.VA,16.VB,21.708:VX:av:vsr %VD, %VA, %VB:Vector Shift Right
int sh, i, j, carry, new_carry;
sh = (*vB).b[0] & 7; /* don't bother checking everything */
carry = 0;
for (j = 0; j < 4; j++) {
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
i = j;
else
i = (j + 2) % 4;
new_carry = (*vA).w[i] << (32 - sh);
(*vS).w[i] = ((*vA).w[i] >> sh) | carry;
carry = new_carry;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.772:VX:av:vsrab %VD, %VA, %VB:Vector Shift Right Algebraic Byte
int i, sh;
signed16 a;
for (i = 0; i < 16; i++) {
sh = ((*vB).b[i]) & 7;
a = (signed16)(signed8)(*vA).b[i];
(*vS).b[i] = (a >> sh) & 0xff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.836:VX:av:vsrah %VD, %VA, %VB:Vector Shift Right Algebraic Half Word
int i, sh;
signed32 a;
for (i = 0; i < 8; i++) {
sh = ((*vB).h[i]) & 0xf;
a = (signed32)(signed16)(*vA).h[i];
(*vS).h[i] = (a >> sh) & 0xffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.900:VX:av:vsraw %VD, %VA, %VB:Vector Shift Right Algebraic Word
int i, sh;
signed64 a;
for (i = 0; i < 4; i++) {
sh = ((*vB).w[i]) & 0xf;
a = (signed64)(signed32)(*vA).w[i];
(*vS).w[i] = (a >> sh) & 0xffffffff;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.516:VX:av:vsrb %VD, %VA, %VB:Vector Shift Right Byte
int i, sh;
for (i = 0; i < 16; i++) {
sh = ((*vB).b[i]) & 7;
(*vS).b[i] = (*vA).b[i] >> sh;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.580:VX:av:vsrh %VD, %VA, %VB:Vector Shift Right Half Word
int i, sh;
for (i = 0; i < 8; i++) {
sh = ((*vB).h[i]) & 0xf;
(*vS).h[i] = (*vA).h[i] >> sh;
}
PPC_INSN_VR(VS_BITMASK, VA_BITMASK | VB_BITMASK);
0.4,6.VS,11.VA,16.VB,21.1100:VX:av:vsro %VD, %VA, %VB:Vector Shift Right Octet
int i, sh;
if (CURRENT_TARGET_BYTE_ORDER == BFD_ENDIAN_BIG)
sh = ((*vB).b[AV_BINDEX(15)] >> 3) & 0xf;
else
sh =